action research projects for high school students

21 Action Research Examples (In Education)

Dave Cornell (PhD)

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Action research is an example of qualitative research . It refers to a wide range of evaluative or investigative methods designed to analyze professional practices and take action for improvement.

Commonly used in education, those practices could be related to instructional methods, classroom practices, or school organizational matters.

The creation of action research is attributed to Kurt Lewin , a German-American psychologist also considered to be the father of social psychology.

Gillis and Jackson (2002) offer a very concise definition of action research: “systematic collection and analysis of data for the purpose of taking action and making change” (p.264).

The methods of action research in education include:

• conducting in-class observations
• taking field notes
• surveying or interviewing teachers, administrators, or parents
• using audio and video recordings.

The goal is to identify problematic issues, test possible solutions, or simply carry-out continuous improvement.

There are several steps in action research : identify a problem, design a plan to resolve, implement the plan, evaluate effectiveness, reflect on results, make necessary adjustment and repeat the process.

Action Research Examples

• Digital literacy assessment and training: The school’s IT department conducts a survey on students’ digital literacy skills. Based on the results, a tailored training program is designed for different age groups.
• Library resources utilization study: The school librarian tracks the frequency and type of books checked out by students. The data is then used to curate a more relevant collection and organize reading programs.
• Extracurricular activities and student well-being: A team of teachers and counselors assess the impact of extracurricular activities on student mental health through surveys and interviews. Adjustments are made based on findings.
• Parent-teacher communication channels: The school evaluates the effectiveness of current communication tools (e.g., newsletters, apps) between teachers and parents. Feedback is used to implement a more streamlined system.
• Homework load evaluation: Teachers across grade levels assess the amount and effectiveness of homework given. Adjustments are made to ensure a balance between academic rigor and student well-being.
• Classroom environment and learning: A group of teachers collaborates to study the impact of classroom layouts and decorations on student engagement and comprehension. Changes are made based on the findings.
• Student feedback on curriculum content: High school students are surveyed about the relevance and applicability of their current curriculum. The feedback is then used to make necessary curriculum adjustments.
• Teacher mentoring and support: New teachers are paired with experienced mentors. Both parties provide feedback on the effectiveness of the mentoring program, leading to continuous improvements.
• Assessment of school transportation: The school board evaluates the efficiency and safety of school buses through surveys with students and parents. Necessary changes are implemented based on the results.
• Cultural sensitivity training: After conducting a survey on students’ cultural backgrounds and experiences, the school organizes workshops for teachers to promote a more inclusive classroom environment.
• Environmental initiatives and student involvement: The school’s eco-club assesses the school’s carbon footprint and waste management. They then collaborate with the administration to implement greener practices and raise environmental awareness.
• Working with parents through research: A school’s admin staff conduct focus group sessions with parents to identify top concerns.Those concerns will then be addressed and another session conducted at the end of the school year.
• Peer teaching observations and improvements: Kindergarten teachers observe other teachers handling class transition techniques to share best practices.
• PTA surveys and resultant action: The PTA of a district conducts a survey of members regarding their satisfaction with remote learning classes.The results will be presented to the school board for further action.
• Recording and reflecting: A school administrator takes video recordings of playground behavior and then plays them for the teachers. The teachers work together to formulate a list of 10 playground safety guidelines.
• Pre/post testing of interventions: A school board conducts a district wide evaluation of a STEM program by conducting a pre/post-test of students’ skills in computer programming.
• Focus groups of practitioners : The professional development needs of teachers are determined from structured focus group sessions with teachers and admin.
• School lunch research and intervention: A nutrition expert is hired to evaluate and improve the quality of school lunches.
• School nurse systematic checklist and improvements: The school nurse implements a bathroom cleaning checklist to monitor cleanliness after the results of a recent teacher survey revealed several issues.
• Wearable technologies for pedagogical improvements; Students wear accelerometers attached to their hips to gain a baseline measure of physical activity.The results will identify if any issues exist.
• School counselor reflective practice : The school counselor conducts a student survey on antisocial behavior and then plans a series of workshops for both teachers and parents.

Detailed Examples

1. cooperation and leadership.

A science teacher has noticed that her 9 th grade students do not cooperate with each other when doing group projects. There is a lot of arguing and battles over whose ideas will be followed.

So, she decides to implement a simple action research project on the matter. First, she conducts a structured observation of the students’ behavior during meetings. She also has the students respond to a short questionnaire regarding their notions of leadership.

She then designs a two-week course on group dynamics and leadership styles. The course involves learning about leadership concepts and practices . In another element of the short course, students randomly select a leadership style and then engage in a role-play with other students.

At the end of the two weeks, she has the students work on a group project and conducts the same structured observation as before. She also gives the students a slightly different questionnaire on leadership as it relates to the group.

She plans to analyze the results and present the findings at a teachers’ meeting at the end of the term.

2. Professional Development Needs

Two high-school teachers have been selected to participate in a 1-year project in a third-world country. The project goal is to improve the classroom effectiveness of local teachers. 

The two teachers arrive in the country and begin to plan their action research. First, they decide to conduct a survey of teachers in the nearby communities of the school they are assigned to.

The survey will assess their professional development needs by directly asking the teachers and administrators. After collecting the surveys, they analyze the results by grouping the teachers based on subject matter.

They discover that history and social science teachers would like professional development on integrating smartboards into classroom instruction. Math teachers would like to attend workshops on project-based learning, while chemistry teachers feel that they need equipment more than training.

The two teachers then get started on finding the necessary training experts for the workshops and applying for equipment grants for the science teachers.

3. Playground Accidents

The school nurse has noticed a lot of students coming in after having mild accidents on the playground. She’s not sure if this is just her perception or if there really is an unusual increase this year.  So, she starts pulling data from the records over the last two years. She chooses the months carefully and only selects data from the first three months of each school year.

She creates a chart to make the data more easily understood. Sure enough, there seems to have been a dramatic increase in accidents this year compared to the same period of time from the previous two years.

She shows the data to the principal and teachers at the next meeting. They all agree that a field observation of the playground is needed.

Those observations reveal that the kids are not having accidents on the playground equipment as originally suspected. It turns out that the kids are tripping on the new sod that was installed over the summer.

They examine the sod and observe small gaps between the slabs. Each gap is approximately 1.5 inches wide and nearly two inches deep. The kids are tripping on this gap as they run.

They then discuss possible solutions.

4. Differentiated Learning

Trying to use the same content, methods, and processes for all students is a recipe for failure. This is why modifying each lesson to be flexible is highly recommended. Differentiated learning allows the teacher to adjust their teaching strategy based on all the different personalities and learning styles they see in their classroom.

Of course, differentiated learning should undergo the same rigorous assessment that all teaching techniques go through. So, a third-grade social science teacher asks his students to take a simple quiz on the industrial revolution. Then, he applies differentiated learning to the lesson.

By creating several different learning stations in his classroom, he gives his students a chance to learn about the industrial revolution in a way that captures their interests. The different stations contain: short videos, fact cards, PowerPoints, mini-chapters, and role-plays.

At the end of the lesson, students get to choose how they demonstrate their knowledge. They can take a test, construct a PPT, give an oral presentation, or conduct a simulated TV interview with different characters.

During this last phase of the lesson, the teacher is able to assess if they demonstrate the necessary knowledge and have achieved the defined learning outcomes. This analysis will allow him to make further adjustments to future lessons.

5. Healthy Habits Program

While looking at obesity rates of students, the school board of a large city is shocked by the dramatic increase in the weight of their students over the last five years. After consulting with three companies that specialize in student physical health, they offer the companies an opportunity to prove their value.

So, the board randomly assigns each company to a group of schools. Starting in the next academic year, each company will implement their healthy habits program in 5 middle schools.

Preliminary data is collected at each school at the beginning of the school year. Each and every student is weighed, their resting heart rate, blood pressure and cholesterol are also measured.

After analyzing the data, it is found that the schools assigned to each of the three companies are relatively similar on all of these measures.

At the end of the year, data for students at each school will be collected again. A simple comparison of pre- and post-program measurements will be conducted. The company with the best outcomes will be selected to implement their program city-wide.

Action research is a great way to collect data on a specific issue, implement a change, and then evaluate the effects of that change. It is perhaps the most practical of all types of primary research .

Most likely, the results will be mixed. Some aspects of the change were effective, while other elements were not. That’s okay. This just means that additional modifications to the change plan need to be made, which is usually quite easy to do.

There are many methods that can be utilized, such as surveys, field observations , and program evaluations.

The beauty of action research is based in its utility and flexibility. Just about anyone in a school setting is capable of conducting action research and the information can be incredibly useful.

Aronson, E., & Patnoe, S. (1997). The jigsaw classroom: Building cooperation in the classroom (2nd ed.). New York: Addison Wesley Longman.

Gillis, A., & Jackson, W. (2002). Research Methods for Nurses: Methods and Interpretation . Philadelphia: F.A. Davis Company.

Lewin, K. (1946). Action research and minority problems. Journal of SocialIssues, 2 (4), 34-46.

Macdonald, C. (2012). Understanding participatory action research: A qualitative research methodology option. Canadian Journal of Action Research, 13 , 34-50. https://doi.org/10.33524/cjar.v13i2.37 Mertler, C. A. (2008). Action Research: Teachers as Researchers in the Classroom . London: Sage.

Dr. Cornell has worked in education for more than 20 years. His work has involved designing teacher certification for Trinity College in London and in-service training for state governments in the United States. He has trained kindergarten teachers in 8 countries and helped businessmen and women open baby centers and kindergartens in 3 countries.

• Dave Cornell (PhD) https://helpfulprofessor.com/author/dave-cornell-phd/ 25 Defense Mechanisms Examples
• Dave Cornell (PhD) https://helpfulprofessor.com/author/dave-cornell-phd/ 15 Theory of Planned Behavior Examples
• Dave Cornell (PhD) https://helpfulprofessor.com/author/dave-cornell-phd/ 18 Adaptive Behavior Examples
• Dave Cornell (PhD) https://helpfulprofessor.com/author/dave-cornell-phd/ 15 Cooperative Play Examples

Chris Drew (PhD)

This article was peer-reviewed and edited by Chris Drew (PhD). The review process on Helpful Professor involves having a PhD level expert fact check, edit, and contribute to articles. Reviewers ensure all content reflects expert academic consensus and is backed up with reference to academic studies. Dr. Drew has published over 20 academic articles in scholarly journals. He is the former editor of the Journal of Learning Development in Higher Education and holds a PhD in Education from ACU.

• Chris Drew (PhD) https://helpfulprofessor.com/author/chris-drew-phd-2/ 25 Defense Mechanisms Examples
• Chris Drew (PhD) https://helpfulprofessor.com/author/chris-drew-phd-2/ 15 Theory of Planned Behavior Examples
• Chris Drew (PhD) https://helpfulprofessor.com/author/chris-drew-phd-2/ 18 Adaptive Behavior Examples
• Chris Drew (PhD) https://helpfulprofessor.com/author/chris-drew-phd-2/ 15 Cooperative Play Examples

2 thoughts on “21 Action Research Examples (In Education)”

Where can I capture this article in a better user-friendly format, since I would like to provide it to my students in a Qualitative Methods course at the University of Prince Edward Island? It is a good article, however, it is visually disjointed in its current format. Thanks, Dr. Frank T. Lavandier

Hi Dr. Lavandier,

I’ve emailed you a word doc copy that you can use and edit with your class.

Best, Chris.

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200+ List of Topics for Action Research in the Classroom

In the dynamic landscape of education, teachers are continually seeking innovative ways to enhance their teaching practices and improve student outcomes. Action research in the classroom is a powerful tool that allows educators to investigate and address specific challenges, leading to positive changes in teaching methods and learning experiences. 

Selecting the right topics from the list of topics for action research in the classroom is crucial for ensuring meaningful insights and improvements. In this blog post, we will explore the significance of action research in the classroom, the criteria for selecting impactful topics, and provide an extensive list of potential research areas.

Understanding: What is Action Research

Table of Contents

Action research is a reflective process that empowers teachers to systematically investigate and analyze their own teaching practices. Unlike traditional research, action research is conducted by educators within their own classrooms, emphasizing a collaborative and participatory approach. 

This method enables teachers to identify challenges, implement interventions, and assess the effectiveness of their actions.

How to Select Topics From List of Topics for Action Research in the Classroom

Choosing the right topic is the first step in the action research process. The selected topic should align with classroom goals, address students’ needs, be feasible to implement, and have the potential for positive impact. Teachers should consider the following criteria when selecting action research topics:

• Alignment with Classroom Goals and Objectives: The chosen topic should directly contribute to the overall goals and objectives of the classroom. Whether it’s improving student engagement, enhancing learning outcomes, or fostering a positive classroom environment, the topic should align with the broader educational context.
• Relevance to Students’ Needs and Challenges: Effective action research addresses the specific needs and challenges faced by students. Teachers should identify areas where students may be struggling or where improvement is needed, ensuring that the research directly impacts the learning experiences of the students.
• Feasibility and Practicality: The feasibility of the research is crucial. Teachers must choose topics that are practical to implement within the constraints of the classroom setting. This includes considering available resources, time constraints, and the level of support from school administrators.
• Potential for Positive Impact: The ultimate goal of action research is to bring about positive change. Teachers should carefully assess the potential impact of their research, aiming for improvements in teaching methods, student performance, or overall classroom dynamics.

List of Topics for Action Research in the Classroom

• Impact of Mindfulness Practices on Student Focus
• The Effectiveness of Peer Tutoring in Mathematics
• Strategies for Encouraging Critical Thinking in History Classes
• Using Gamification to Enhance Learning in Science
• Investigating the Impact of Flexible Seating Arrangements
• Assessing the Benefits of Project-Based Learning in Language Arts
• The Influence of Classroom Decor on Student Motivation
• Examining the Use of Learning Stations for Differentiation
• Implementing Reflective Journals to Enhance Writing Skills
• Exploring the Impact of Flipped Classroom Models
• Analyzing the Effects of Homework on Student Performance
• The Role of Positive Reinforcement in Classroom Behavior
• Investigating the Impact of Classroom Libraries on Reading Proficiency
• Strategies for Fostering a Growth Mindset in Students
• Assessing the Benefits of Cross-Curricular Integration
• Using Technology to Enhance Vocabulary Acquisition
• The Impact of Outdoor Learning on Student Engagement
• Investigating the Relationship Between Attendance and Academic Success
• The Role of Parental Involvement in Homework Completion
• Assessing the Impact of Classroom Rituals on Community Building
• Strategies for Increasing Student Participation in Discussions
• Exploring the Influence of Classroom Lighting on Student Alertness
• Investigating the Impact of Daily Agendas on Time Management
• The Effectiveness of Socratic Seminars in Social Studies
• Analyzing the Use of Graphic Organizers for Concept Mapping
• Implementing Student-Led Conferences for Goal Setting
• Examining the Effects of Mind Mapping on Information Retention
• The Influence of Classroom Temperature on Academic Performance
• Investigating the Benefits of Cooperative Learning Strategies
• Strategies for Addressing Test Anxiety in Students
• Assessing the Impact of Positive Affirmations on Student Confidence
• The Use of Literature Circles to Enhance Reading Comprehension
• Exploring the Effects of Classroom Noise Levels on Concentration
• Investigating the Benefits of Cross-Grade Collaborations
• Analyzing the Impact of Goal Setting on Student Achievement
• Implementing Interactive Notebooks for Conceptual Understanding
• The Effectiveness of Response to Intervention (RTI) Programs
• Strategies for Integrating Social-Emotional Learning (SEL)
• Investigating the Impact of Classroom Discussions on Critical Thinking
• The Role of Brain Breaks in Enhancing Student Focus
• Assessing the Benefits of Inquiry-Based Learning in Science
• Exploring the Effects of Music on Studying and Retention
• Investigating the Use of Learning Contracts for Individualized Learning
• The Influence of Classroom Colors on Mood and Learning
• Strategies for Promoting Collaborative Problem-Solving
• Analyzing the Impact of Flexible Scheduling on Student Productivity
• The Effectiveness of Mindful Breathing Exercises on Stress Reduction
• Investigating the Benefits of Service Learning Projects
• The Role of Peer Assessment in Improving Writing Skills
• Exploring the Impact of Field Trips on Cultural Competency
• Assessing the Benefits of Personalized Learning Plans
• Strategies for Differentiating Instruction in Large Classrooms
• Investigating the Influence of Teacher-Student Relationships on Learning
• The Effectiveness of Vocabulary Games in Foreign Language Classes
• Analyzing the Impact of Classroom Discussions on Civic Engagement
• Implementing Goal-Setting Strategies for Test Preparation
• The Role of Classroom Celebrations in Building a Positive Environment
• Strategies for Enhancing Student Reflection and Metacognition
• Investigating the Effects of Positive Behavior Supports (PBS)
• The Influence of Classroom Humor on Student Engagement
• Assessing the Benefits of Student-Led Research Projects
• Exploring the Impact of Timed vs. Untimed Tests on Anxiety
• Investigating the Use of Educational Podcasts for Learning
• The Effectiveness of Debate Activities in Developing Persuasive Skills
• Analyzing the Impact of Mindful Walking Breaks on Concentration
• Strategies for Promoting Digital Citizenship in the Classroom
• The Role of Visualization Techniques in Mathematics Learning
• Assessing the Benefits of Classroom Agreements for Behavior
• Exploring the Effects of Goal-Setting in Physical Education
• Investigating the Influence of Classroom Seating Charts on Behavior
• The Effectiveness of Peer Editing in Improving Writing Skills
• Strategies for Integrating Cultural Competency in History Lessons
• Analyzing the Impact of Classroom Pets on Student Well-Being
• The Role of Morning Meetings in Building Classroom Community
• Investigating the Benefits of Using Learning Centers in Elementary Schools
• Exploring the Effects of Virtual Reality in Geography Education
• Assessing the Impact of Homework Choice on Student Motivation
• Strategies for Promoting Growth Mindset in Mathematics
• The Influence of Classroom Layout on Group Collaboration
• Investigating the Benefits of Mindful Listening Practices
• The Effectiveness of Using Real-World Examples in Science Lessons
• Analyzing the Impact of Student-Led Assessments on Accountability
• Exploring the Use of Learning Contracts for Student Responsibility
• Investigating the Benefits of Teaching Digital Literacy Skills
• Strategies for Implementing Peer Mentoring Programs
• The Role of Graphic Novels in Promoting Literacy
• Assessing the Impact of Flexible Grouping in Mathematics Classes
• The Effectiveness of Using Storytelling for Conceptual Understanding
• Investigating the Influence of Classroom Rituals on Attendance
• Exploring the Benefits of Mindfulness Practices in Physical Education
• Strategies for Integrating Social Justice Education in the Curriculum
• Analyzing the Impact of Goal-Setting on Homework Completion
• The Role of Classroom Mindfulness Activities in Stress Reduction
• Investigating the Benefits of Using Educational Apps for Vocabulary
• The Effectiveness of Using Drama in History Lessons
• Assessing the Impact of Classroom Routines on Time Management
• Exploring the Influence of Teacher-Student Rapport on Academic Achievement
• Strategies for Promoting Active Listening Skills in the Classroom
• Investigating the Benefits of Using Concept Mapping in Science
• The Role of Classroom Socratic Seminars in Developing Critical Thinking
• Assessing the Impact of Mindful Eating Practices on Student Focus
• Exploring the Effects of Flipped Learning in Physical Education
• Investigating the Benefits of Using Educational Games for Math Fluency
• The Effectiveness of Peer Assessment in Art Classes
• Strategies for Fostering Creativity in Science Education
• Analyzing the Impact of Morning Stretches on Student Alertness
• The Role of Classroom Discussions in Enhancing Social Studies Learning
• Investigating the Benefits of Using Augmented Reality in History Lessons
• Assessing the Impact of Growth Mindset Interventions on Test Anxiety
• Strategies for Incorporating Environmental Education in the Curriculum
• The Effectiveness of Using Conceptual Maps in Literature Analysis
• Exploring the Influence of Classroom Lighting on Reading Comprehension
• Investigating the Benefits of Using Learning Apps for Language Acquisition
• The Role of Classroom Experiments in Science Education
• Analyzing the Impact of Mindful Breathing Exercises on Test Performance
• Strategies for Promoting Collaborative Problem-Solving in Mathematics
• Assessing the Benefits of Mindfulness Practices in Physical Education
• Exploring the Effects of Flexible Seating on Student Collaboration
• Investigating the Influence of Homework Choice on Student Motivation
• The Effectiveness of Using Educational Podcasts for History Learning
• Strategies for Integrating Sustainability Education Across Subjects
• Analyzing the Impact of Mindful Writing Practices on Language Arts Skills
• The Role of Peer Teaching in Enhancing Understanding of Complex Concepts
• Investigating the Benefits of Using Digital Storytelling in Literature Classes
• The Effectiveness of Inquiry-Based Learning in Social Studies
• Assessing the Impact of Student-Led Book Clubs on Reading Engagement
• Strategies for Incorporating Financial Literacy in Mathematics Education
• Exploring the Influence of Classroom Decor on Science Interest
• Investigating the Benefits of Mindful Movement Breaks in the Classroom
• The Role of Reflection Journals in Developing Critical Thinking Skills
• Analyzing the Impact of Virtual Field Trips on Geography Learning
• Strategies for Promoting Inclusive Physical Education Practices
• Assessing the Benefits of Using Educational Board Games for Learning
• The Effectiveness of Mindfulness Practices in Foreign Language Classes
• Investigating the Influence of Classroom Rituals on Academic Rigor
• Exploring the Impact of Student-Led Conferences on Goal Setting
• The Role of Mindful Listening Practices in Improving Communication Skills
• Investigating the Benefits of Using Educational Apps for Science Exploration
• Analyzing the Effectiveness of Socratic Seminars in Philosophy Classes
• Strategies for Promoting Gender Equity in STEM Education
• Assessing the Impact of Classroom Celebrations on Student Well-Being
• The Effectiveness of Using Debate Activities in Language Arts
• Exploring the Influence of Positive Affirmations on Classroom Climate
• Investigating the Benefits of Using Concept Mapping in History Essays
• Strategies for Incorporating Media Literacy in Social Studies
• Analyzing the Impact of Mindful Reflection Practices on Homework Completion
• The Role of Peer Collaboration in Enhancing Artistic Skills
• Investigating the Benefits of Using Educational Apps for Vocabulary Acquisition
• The Effectiveness of Mindful Breathing Exercises in Test Preparation
• Assessing the Impact of Flipped Learning in Science Laboratories
• Strategies for Promoting Civic Engagement in Social Studies Classes
• Exploring the Influence of Outdoor Learning on Scientific Inquiry
• Investigating the Benefits of Using Learning Stations for Literature Analysis
• The Role of Mindful Movement in Improving Physical Education Experiences
• Analyzing the Effectiveness of Virtual Reality in Language Learning
• Strategies for Incorporating Global Perspectives in Geography Education
• Assessing the Impact of Mindful Coloring Activities on Stress Reduction
• The Effectiveness of Using Educational Games for History Review
• Investigating the Benefits of Mindful Breathing Exercises in Mathematics
• Exploring the Influence of Classroom Rituals on Study Habits
• The Role of Mindful Listening Practices in Enhancing Oral Communication
• Analyzing the Impact of Student-Led Workshops on Study Skills
• Strategies for Promoting Critical Media Literacy in Language Arts
• Assessing the Benefits of Mindfulness Practices in Physical Fitness
• The Effectiveness of Using Educational Apps for Music Appreciation
• Investigating the Influence of Classroom Decor on Artistic Expression
• Exploring the Impact of Mindful Eating Practices on Nutrition Awareness
• The Role of Peer Assessment in Improving Science Fair Projects
• Analyzing the Benefits of Mindful Breathing Exercises in History Classes
• Strategies for Promoting Teamwork in Physical Education
• Assessing the Impact of Classroom Celebrations on Cultural Understanding
• The Effectiveness of Using Conceptual Maps in Geography Education
• Investigating the Benefits of Mindful Movement Breaks in Mathematics
• The Role of Mindful Listening Practices in Improving Musical Skills
• Analyzing the Impact of Student-Led Discussions in Philosophy Classes
• Strategies for Incorporating Environmental Stewardship in Science Education
• Assessing the Benefits of Using Educational Games for Physical Fitness
• Exploring the Influence of Classroom Decor on Mathematical Interest
• Investigating the Effectiveness of Virtual Reality in Art Appreciation
• The Role of Mindful Movement in Enhancing Physical Education Experiences
• Strategies for Promoting Cultural Competency in Language Arts
• Analyzing the Impact of Mindful Breathing Exercises on Test Anxiety
• The Effectiveness of Using Educational Apps for Science Exploration
• Investigating the Benefits of Peer Teaching in Mathematics Classes
• Exploring the Influence of Classroom Rituals on Language Arts Skills
• Assessing the Impact of Mindful Coloring Activities on Creative Expression
• The Role of Mindful Listening Practices in Improving Public Speaking
• Investigating the Benefits of Using Learning Stations for History Learning
• The Effectiveness of Peer Assessment in Improving Writing Skills
• Strategies for Promoting Digital Literacy in Geography Education
• Analyzing the Impact of Mindful Eating Practices on Healthy Habits
• Assessing the Benefits of Using Educational Games for Social Studies
• The Effectiveness of Mindful Movement Breaks in Science Education
• Exploring the Influence of Classroom Decor on Writing Motivation
• Investigating the Role of Mindfulness Practices in Mathematics Anxiety
• Strategies for Incorporating Financial Literacy in Social Studies
• Analyzing the Benefits of Using Concept Mapping in Science Labs
• The Role of Mindful Breathing Exercises in Improving Music Education
• Exploring the Impact of Virtual Reality on Foreign Language Acquisition
• Assessing the Benefits of Mindful Movement Breaks in History Classes

Tips for Conducting Action Research in the Classroom

• Setting Clear Research Goals and Objectives: Clearly define the goals and objectives of the research to ensure a focused and purposeful investigation.
• Involving Stakeholders in the Research Process: Engage students, parents, and colleagues in the research process to gather diverse perspectives and insights.
• Collecting and Analyzing Relevant Data: Use a variety of data collection methods, such as surveys, observations, and assessments, to gather comprehensive and meaningful data.
• Reflecting on Findings and Adjusting Teaching Practices: Regularly reflect on the research findings and be open to adjusting teaching practices based on the insights gained from the research.

Case Studies or Examples

Highlighting successful action research projects provides inspiration and practical insights for teachers. 

Sharing case studies or examples of impactful research can demonstrate the positive outcomes and improvements that can result from well-conducted action research.

In conclusion, action research is a valuable tool for educators seeking to enhance their teaching practices and improve student outcomes. 

Selecting the right topics from a list of topics for action research in the classroom is crucial for the success of action research projects, and teachers should consider alignment with goals, relevance to students, feasibility, and potential impact. 

By exploring a diverse range of topics, teachers can embark on meaningful action research journeys, contributing to the continuous improvement of education.

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The Complete Guide to Independent Research Projects for High School Students

Indigo Research Team

If you want to get into top universities, an independent research project will give your application the competitive edge it needs.

Writing and publishing independent research during high school lets you demonstrate to top colleges and universities that you can deeply inquire into a topic, think critically, and produce original analysis. In fact, MIT features "Research" and "Maker" portfolio sections in its application, highlighting the value it places on self-driven projects.

Moreover, successfully executing high-quality research shows potential employers that you can rise to challenges, manage your time, contribute new ideas, and work independently. 

This comprehensive guide will walk you through everything you need to know to take on independent study ideas and succeed. You’ll learn how to develop a compelling topic, conduct rigorous research, and ultimately publish your findings.

What is an Independent Research Project?

An independent research project is a self-directed investigation into an academic question or topic that interests you. Unlike projects assigned by teachers in class, independent research will allow you to explore your curiosity and passions.

These types of projects can vary widely between academic disciplines and scientific fields, but what connects them is a step-by-step approach to answering a research question. Specifically, you will have to collect and analyze data and draw conclusions from your analysis.

For a high school student, carrying out quality research may still require some mentorship from a teacher or other qualified scholar. But the project research ideas should come from you, the student. The end goal is producing original research and analysis around a topic you care about.

Some key features that define an independent study project include:

● Formulating your own research question

● Designing the methodology

● Conducting a literature review of existing research

● Gathering and analyzing data, and

● Communicating your findings.

The topic and scope may be smaller than a professional college academic project, but the process and skills learned have similar benefits.

Why Should High School Students Do Independent Research?

High school students who engage in independent study projects gain valuable skills and experiences that benefit and serve them well in their college and career pursuits. Here's a breakdown of what you will typically acquire:

Develop Critical Thinking and Problem-Solving Skills

Research and critical thinking are among the top 10 soft skills in demand in 2024 . They help you solve new challenges quickly and come up with alternative solutions

An independent project will give you firsthand experience with essential research skills like forming hypotheses, designing studies, collecting and analyzing data, and interpreting results. These skills will serve you well in college and when employed in any industry.

Stand Out for College Applications

With many applicants having similar GPAs and test scores, an Independent research study offer a chance to stand out from the crowd. Completing a research study in high school signals colleges that you are self-motivated and capable of high-level work. Showcasing your research process, findings, and contributions in your application essays or interviews can boost your application's strengths in top-level colleges and universities.

Earn Scholarship Opportunities

Completing an independent research project makes you a more preferred candidate for merit-based scholarships, especially in STEM fields. Many scholarships reward students who show initiative by pursuing projects outside of class requirements. Your research project ideas will demonstrate your skills and motivation to impress scholarship committees. For example, the Siemens Competition in Math, Science & Technology rewards students with original independent research projects in STEM fields. Others include the Garcia Summer Program and the BioGENEius challenge for life sciences.

Gain Subject Area Knowledge

Independent projects allow you to immerse yourself in a topic you genuinely care about beyond what is covered in the classroom. It's a chance to become an expert in something you're passionate about . You will build deep knowledge in the topic area you choose to research, which can complement what you're learning in related classes. This expertise can even help inform your career interests and goals.

Develop Time Management Skills

Time Management is the skill that lets you effectively plan and prioritize tasks and avoid procrastination. With no teacher guiding you step-by-step, independent study projects require strong time management, self-discipline, and personal responsibility – skills critical in college and adulthood.

Types of Independent Research Projects for High School Students

Understanding the different types and categories can spark inspiration if you need help finding an idea for an independent study. Topics for independent research generally fall into a few main buckets:

Science Experiments

For students interested in STEM fields, designing and carrying out science experiments is a great option. Test a hypothesis, collect data, and draw conclusions. Experiments in physics, chemistry, biology, engineering, and psychology are common choices. Science experiment is best for self-motivated students with access to lab equipment.

Social Science Surveys and Studies  

Use research methods from sociology, political science, anthropology, economics, and psychology to craft a survey study or field observation around a high school research project idea that interests you. Collect data from peers, your community, and online sources, and compile findings. Strong fit for students interested in social studies.

Literary Analysis Paper

This research category involves analyzing existing research papers, books, and articles on a specific topic. Imagine exploring the history of robots, examining the impact of social media on mental health, or comparing different interpretations of a classic novel. If you are an English enthusiast, this is an easy chance to showcase your analytical writing skills.

Programming or Engineering Project

For aspiring programmers or engineers, you can take on practical student projects that develop software programs, apps, websites, robots, electronic gadgets, or other hands-on engineering projects. This type of project will easily highlight your technical skills and interest in computer science or engineering fields in your college applications

Historical Research

History research projects will allow you to travel back and uncover the past to inform the future. This research involves analyzing historical documents, artifacts, and records to shed light on a specific event or period. For example, you can conduct independent research on the impact of a local historical figure or the evolution of fashion throughout the decades. Check to explore even more history project ideas for high school students .

Artistic and Creative Works

If you are artistic and love creating art,  you can explore ideas for independent study to produce an original film, musical composition, sculpture, painting series, fashion line, or other creative work. Alongside the tangible output, document your creative process and inspirations.

Bonus Tip: Feel free to mix different ideas for your project. For example, you could conduct a literature review on a specific historical event and follow it up with field research that interviewed people who experienced the event firsthand.

How To Conduct an Independent Research Project

Now that you have ideas for project topics that match your interests and strengths, here are the critical steps you must follow to move from mere concept to completed study.

1. Get Expert Guidance and Mentorship

As a high school student just starting out in research, it is advised to collaborate with more experienced mentors who will help you learn the ropes of research projects easily. Mentors are usually professors, post-doctoral researchers, or graduate students with significant experience in conducting independent project research and can guide you through the process. 

Specifically, your mentor will advise you on formulating research questions, designing methodologies, analyzing data, and communicating findings effectively. To quickly find mentors in your research project area of interest, enroll in an online academic research mentorship program that targets high school students. You’d be exposed to one-on-one sessions with professors and graduate students that will help you develop your research and publish your findings.

The right mentor can also help transform your independent project ideas into a study suitable for publication in relevant research journals. With their experience, mentors will guide you to follow the proper research methods and best practices. This ensures your work meets the standards required, avoiding rejection from journals. 

2. Develop a Compelling Research Question

Once you are familiar with the type of independent research best suited to your strengths and interests, as explained in the previous section, the next step is to develop a question you want to answer in that field. This is called a research question and will serve as the foundation for your entire project.

The research question will drive your entire project, so it needs to be complex enough to merit investigation but clear enough to study. Here are some ts for crafting your research question:

●  Align your research question(s) with topics you are passionate about and have some background knowledge. You will spend a significant amount of time on this question.

●  Consult with your mentor teacher or professor to get feedback and guidance on developing a feasible, meaningful question

●  Avoid overly broad questions better suited for doctoral dissertations. Narrow your focus to something manageable, but that still intrigues you.

●  Pose your research question as an actual question, like "How does social media usage affect teen mental health?" The question should lay out the key variables you'll be investigating.

●  Ensure your question and desired approach are ethically sound. You may need permission to study human subjects.

●  Conduct preliminary research to ensure your question hasn't already been answered. You want to contribute something new to your field.

With a compelling research question as your compass, you're ready to start your independent study project. Remember to stay flexible; you may need to refine the question further as your research develops.

3. Set a Timeline and Write a Proposal

After defining your research question, the next step is to map out a timeline for completing your research project. This will keep you organized and help you develop strong time management skills.

Start by creating a schedule that outlines all major milestones from start to finish. In your schedule, allow plenty of time for research, experimentation, data analysis, and compiling your report. Always remember to build in some cushion for unexpected delays.

Moreover, you can use tools like Gantt charts to design a timeline for an independent research project . Gantt charts help you visualize your research project timeline at a glance. See the video below for a tutorial on designing a Gantt chart to plan your project schedule:

[YouTube Video on How to Make a Gantt Chart: https://youtu.be/un8j6QqpYa0?si=C2_I0C_ZBXS73kZy ]

Research Proposal

To have a clear direction of the step-by-step process for your independent study, write a 1-2 page research proposal to outline your question, goals, methodology, timeline, resources, and desired outcomes. Get feedback from your mentor to improve the proposal before starting your research. 

Sticking to your timeline requires self-discipline. But strive to meet your goals and deadlines; it will build invaluable real-world skills in time and project management. With a plan in place, it's time to move forward with your research.

4. Do Your Research

This is the active phase where a student is conducting a research project. The specific method you will follow varies enormously based on your project type and field. You should have your methodology outlined in your approved research proposal already. However, most independent research has a similar basic process:

• Review existing studies : Perform a literature review to understand current knowledge on your topic and inform your own hypothesis/framework. Read relevant studies, articles, and papers.
• Create methodology materials : Design your independent research methodology for gathering data. This may involve experiments, surveys, interviews, field observations, or analysis of existing artifacts like texts or datasets.
• Permissions and Equipment :  Secure any necessary equipment and permissions. For example, if doing interviews, you'll need a recording device and consent from participants.
• Collect your data : For science projects, perform experiments and record results. For surveys, recruit respondents and compile responses. Gather enough data to draw valid conclusions.
• Analyze the data using appropriate techniques : Quantitative data may involve statistical analysis, while qualitative data requires coding for themes. Consult your mentor for direction.
• Interpret the findings : Take care not to overstate conclusions. Look for patterns and relationships that shed light on your research question. Always maintain rigorous objectivity.

While a student's project methodology and its execution are unique, ensure you follow the standard practices in your field of interest to ensure high-quality acceptable results. You can always refer to the plan in your research proposal as you diligently carry out the steps required to execute your study. Ensure you have detailed records that document all your processes.  

5. Write Your Final Paper and Presentation

Once you've completed your research, it's time to summarize and share your findings with the world by writing the final paper and designing its presentation. This involves synthesizing your work into clear, compelling reporting.

Drafting the paper will likely involve extensive writing and editing. Be prepared to go through multiple revisions to get the paper polished. Follow the standard format used in academic papers in your field;  your mentor can provide you with examples of independent study related to yours. The final product should include: 

• Abstract : A short summary of your project and conclusions.
• Introduction : Background on your topic, goals, and research questions.
• Literature Review : Summary of relevant existing research in your field.
• Methods : Detailed explanation of the methodology and process of your study.
• Results : Presentation of the data and main findings from your research. Using visual representations like charts was helpful.
• Discussion : Objective interpretation and analysis of the results and their significance.
• Conclusion : Summary of your research contributions, limitations, and suggestions for future work.
• References/Bibliography : Full citations for all sources referenced.

Adhere to clear academic writing principles to keep your writing objective and straightforward. Generally, stick to a 10-15 page length limit appropriate for student work. However, you may need to write more depending on your project type.

6. Research Presentation

After writing your research project report, you should prepare a presentation to share your research orally. Moreover, a research presentation is a tangible opportunity to practice public speaking and visual communication skills. Your presentation will include slides, handouts, demonstrations, or other aids to engage your audience and highlight key points in your independent study project.

Once you have written your final paper, you will likely want to publish it in relevant journals and publications. For detailed tips see our guide on how to publish your student research paper . Some options you have to formally publish your high school-level independent research include:

• Submitting your paper to academic journals and competitions
• Presenting at symposiums and science fairs
• Sharing on online research databases
• Adding your work to college applications

Publishing your independent project allows you to share your findings with broader scholarly and student audiences. It also helps amplify the impact of all your hard work.

Independent Research Project Examples

To spark creative ideas for independent research projects, it can be helpful to read through and examine examples of successful projects completed by other high school students in recent years. Here are some inspiring examples:

●  Using machine learning to diagnose cancer based on blood markers (bioinformatics)

●  Applying feature engineering and natural language processing to analyze Twitter data (data science)

●  Investigating connections between stress levels and HIV/AIDS progression (health science)

●  The Relationship between Color and Human Experience

These published i ndependent research project examples demonstrate the impressive research high schoolers take on using the Indigo research service with mentors from different fields. Let these case studies motivate your creative investigation and analysis of the best ideas for your project.

Need Mentorship for Your Independent Research Project?

As outlined in this guide, conducting a rigorous independent research study can be challenging without proper guidance from experts, especially for high school students. This is why partnering with an experienced research mentor is so crucial if your goal is to produce publishable research work.

With Indigo's structured research programs and ongoing expert feedback, you can elevate your high school independent study to a professional level. To get matched with the perfect research mentor aligned with your academic interests and passions, apply to Indigo Research now.

Indigo Research connects high school students with PhD-level researchers and professors who provide one-on-one mentorship through the entire research process - from refining your initial topic idea all the way through analyzing data, writing up results, and finalizing your findings.

Michael D. Eisner College of Education

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Get Inspired

The following Action Research Projects (ARPs) provide just that. These practical ideas and strategies are the result of classroom action research conducted by teachers in schools and classrooms.

To use this site, simply identify a grade level or topic of interest and click on it. This will take you to a list of ARPs for your review. Click on any ARP to learn more about the topic, what was done, and who did it.

Elementary (preK-5)

Digital portfolios.

• Evaluating the Effectiveness of Student-Created Digital Portfolios in Creating a Culture of Self-Efficacy in Kindergarten Classrooms

Improving Chronic Absenteeism

• Addressing Chronic Absenteeism through Peer-Mentoring

Literacy Academy

• Effectiveness of Early Language Literacy Plan Academy Model in Nonsense Word Fluency
• Critical Thinking Using an Online Discussion Forum with Fourth Graders

Math Computation

• Math Computation Proficiency in Elementary Classrooms

Parental Involvement

• Increasing Parental Involvement Through Technology Use

Reading Fluency

• Reading Fluency in the First Grade Classroom

Reading/Language Arts

• Phonemic Awareness Instruction as a Response to Intervention Strategy for Kindergarten Students without Preschool Experience
• Improving Reading Fluency and Comprehension With The Daily Café Program

Reflective Thinking Routines

• Reflective Thinking Routines and Their Impact on Teachers’ Rates of Positive to Directive/Corrective Interactions with Students

Speech Production Targets

• Non-Words Used as Speech Production Targets

Student Goal Setting

• Student Goal Setting to Increase Academic Achievement in Math

Middle School (6-8)

Chronic absenteeism.

• Impacts of “Internal” Mentoring Program on Chronic Absenteeism
• Student Recognition and Goals: The Effects of Student Recognition and Goal Setting on Motivation and Achievement among At-Risk Opportunity School Students

Student Behavior and Academics

• An Investigation into the Impact of Extra-Curricular Activities on Student Behavior and Academic Success

Restorative Justice

• Restorative Justice Prevailing Over Suspension

High School (9-12)

Ability grouping in mat.

• Maximizing the Benefits of Grouping by Ability in Math

Credit Recover Programs

• Effectiveness of Online Credit Recovery Versus Face-to-Face Credit Recovery Programs
• Increasing English Learner Assessment Scores with Software Intervention Programs

Full Inclusion

• Should Alternate Curriculum Integration Lead to Full Inclusion?

Instructional Approaches for Developing Spanish Fluency

• The Effects of Comprehensive Input Through Storytelling in High School Spanish Students

Mastery Grading

• Mastery Grading: An Action Research Plan for Student Engagement

STEM AP Enrollment

• Action Research Increasing STEM AP Enrollment

Student Self-Regulation

• Self-Regulation Strategies and Student Engagement
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How Teachers Can Learn Through Action Research

A look at one school’s action research project provides a blueprint for using this model of collaborative teacher learning.

When teachers redesign learning experiences to make school more relevant to students’ lives, they can’t ignore assessment. For many teachers, the most vexing question about real-world learning experiences such as project-based learning is: How will we know what students know and can do by the end of this project?

Teachers at the Siena School in Silver Spring, Maryland, decided to figure out the assessment question by investigating their classroom practices. As a result of their action research, they now have a much deeper understanding of authentic assessment and a renewed appreciation for the power of learning together.

Their research process offers a replicable model for other schools interested in designing their own immersive professional learning. The process began with a real-world challenge and an open-ended question, involved a deep dive into research, and ended with a public showcase of findings.

Start With an Authentic Need to Know

Siena School serves about 130 students in grades 4–12 who have mild to moderate language-based learning differences, including dyslexia. Most students are one to three grade levels behind in reading.

Teachers have introduced a variety of instructional strategies, including project-based learning, to better meet students’ learning needs and also help them develop skills like collaboration and creativity. Instead of taking tests and quizzes, students demonstrate what they know in a PBL unit by making products or generating solutions.

“We were already teaching this way,” explained Simon Kanter, Siena’s director of technology. “We needed a way to measure, was authentic assessment actually effective? Does it provide meaningful feedback? Can teachers grade it fairly?”

Focus the Research Question

Across grade levels and departments, teachers considered what they wanted to learn about authentic assessment, which the late Grant Wiggins described as engaging, multisensory, feedback-oriented, and grounded in real-world tasks. That’s a contrast to traditional tests and quizzes, which tend to focus on recall rather than application and have little in common with how experts go about their work in disciplines like math or history.

The teachers generated a big research question: Is using authentic assessment an effective and engaging way to provide meaningful feedback for teachers and students about growth and proficiency in a variety of learning objectives, including 21st-century skills?

Take Time to Plan

Next, teachers planned authentic assessments that would generate data for their study. For example, middle school science students created prototypes of genetically modified seeds and pitched their designs to a panel of potential investors. They had to not only understand the science of germination but also apply their knowledge and defend their thinking.

In other classes, teachers planned everything from mock trials to environmental stewardship projects to assess student learning and skill development. A shared rubric helped the teachers plan high-quality assessments.

Make Sense of Data

During the data-gathering phase, students were surveyed after each project about the value of authentic assessments versus more traditional tools like tests and quizzes. Teachers also reflected after each assessment.

“We collated the data, looked for trends, and presented them back to the faculty,” Kanter said.

Among the takeaways:

• Authentic assessment generates more meaningful feedback and more opportunities for students to apply it.
• Students consider authentic assessment more engaging, with increased opportunities to be creative, make choices, and collaborate.
• Teachers are thinking more critically about creating assessments that allow for differentiation and that are applicable to students’ everyday lives.

To make their learning public, Siena hosted a colloquium on authentic assessment for other schools in the region. The school also submitted its research as part of an accreditation process with the Middle States Association.

Strategies to Share

For other schools interested in conducting action research, Kanter highlighted three key strategies.

• Focus on areas of growth, not deficiency:  “This would have been less successful if we had said, ‘Our math scores are down. We need a new program to get scores up,’ Kanter said. “That puts the onus on teachers. Data collection could seem punitive. Instead, we focused on the way we already teach and thought about, how can we get more accurate feedback about how students are doing?”
• Foster a culture of inquiry:  Encourage teachers to ask questions, conduct individual research, and share what they learn with colleagues. “Sometimes, one person attends a summer workshop and then shares the highlights in a short presentation. That might just be a conversation, or it might be the start of a school-wide initiative,” Kanter explained. In fact, that’s exactly how the focus on authentic assessment began.
• Build structures for teacher collaboration:  Using staff meetings for shared planning and problem-solving fosters a collaborative culture. That was already in place when Siena embarked on its action research, along with informal brainstorming to support students.

For both students and staff, the deep dive into authentic assessment yielded “dramatic impact on the classroom,” Kanter added. “That’s the great part of this.”

In the past, he said, most teachers gave traditional final exams. To alleviate students’ test anxiety, teachers would support them with time for content review and strategies for study skills and test-taking.

“This year looks and feels different,” Kanter said. A week before the end of fall term, students were working hard on final products, but they weren’t cramming for exams. Teachers had time to give individual feedback to help students improve their work. “The whole climate feels way better.”

Action Research

← explore all resources.

Action research is a method used by teachers to solve everyday issues in the classroom. It is a reflective, democratic, and action-based approach to problem-solving or information-seeking in the classroom. Instead of waiting for a solution, action research empowers teachers to become critical and reflective thinkers and lifelong learners that are dedicated to helping improve student learning and teaching effectiveness.

Teachers or program leaders can take on an action research project by framing a question, carrying out an intervention or experiment, and reporting on the results. Below you’ll find resources, examples, and simple steps to help you get started.

Action Research in Early Childhood Education

Steps for action research.

1. Identify a Topic

Topics for action research can include the following:

• Changes in classroom practice
• Effects of program restructuring
• New understanding of students
• Teacher skills and competencies
• New professional relationships
• New content or curricula
• What problem do you want to solve? What information are you seeking?
• What data will need to be collected to help find a solution or answer?
• How will it be collected, by whom and from whom?
• How can you assure that your data will be reliable?

3. Collect Data

A mixed-method approach is a great way to ensure that your data is valid and reliable since you are gathering data from more than one source. This is called triangulation.

Mixed-methods research is when you integrate quantitative and qualitative research and analysis in a single study. Quantitative data is data that can be measured and written down with numbers. Some examples include attendance records, developmental screening tests, and attitude surveys. Qualitative data is data that cannot be measured in a numerical format. Some examples include observations, open-ended survey responses, audio recordings, focus groups, pictures, and in-depth interviews.

Ethically, even if your research will be contained in the classroom, it is important to get permission from the director or principal and parents. If your data collection involves videotaping or photographing students, you should review and follow school procedures. Always make sure that you have a secure place to store data and that you respect the confidentiality of your students.

4. Analyze and Interpret the Data

It’s important to consider when data will be able to answer your question. Were you looking for effects right away or effects that last until the end of the school year? When you’re done, review all of the data and look for themes. You can then separate the data into categories and analyze each group. Remember the goal of the analysis is not only to help answer the research question, but to gain understanding as a teacher.

5. Carry out an Action Plan to Improve Your Practice 

After the analysis, summarize what you learned from the study.

• How can you share your findings?
• What new research questions did the study prompt you to research next?
• What actionable steps can you make as a result of the findings?

Pine, G. J. (2008). Teacher action research: building knowledge democracies. Sage Publications.

Related Content

Data design initiative, webinar: child assessments: telling stories with data, data basics, data literacy credential, data essentials.

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1 What is Action Research for Classroom Teachers?

ESSENTIAL QUESTIONS

• What is the nature of action research?
• How does action research develop in the classroom?
• What models of action research work best for your classroom?
• What are the epistemological, ontological, theoretical underpinnings of action research?

Educational research provides a vast landscape of knowledge on topics related to teaching and learning, curriculum and assessment, students’ cognitive and affective needs, cultural and socio-economic factors of schools, and many other factors considered viable to improving schools. Educational stakeholders rely on research to make informed decisions that ultimately affect the quality of schooling for their students. Accordingly, the purpose of educational research is to engage in disciplined inquiry to generate knowledge on topics significant to the students, teachers, administrators, schools, and other educational stakeholders. Just as the topics of educational research vary, so do the approaches to conducting educational research in the classroom. Your approach to research will be shaped by your context, your professional identity, and paradigm (set of beliefs and assumptions that guide your inquiry). These will all be key factors in how you generate knowledge related to your work as an educator.

Action research is an approach to educational research that is commonly used by educational practitioners and professionals to examine, and ultimately improve, their pedagogy and practice. In this way, action research represents an extension of the reflection and critical self-reflection that an educator employs on a daily basis in their classroom. When students are actively engaged in learning, the classroom can be dynamic and uncertain, demanding the constant attention of the educator. Considering these demands, educators are often only able to engage in reflection that is fleeting, and for the purpose of accommodation, modification, or formative assessment. Action research offers one path to more deliberate, substantial, and critical reflection that can be documented and analyzed to improve an educator’s practice.

Purpose of Action Research

As one of many approaches to educational research, it is important to distinguish the potential purposes of action research in the classroom. This book focuses on action research as a method to enable and support educators in pursuing effective pedagogical practices by transforming the quality of teaching decisions and actions, to subsequently enhance student engagement and learning. Being mindful of this purpose, the following aspects of action research are important to consider as you contemplate and engage with action research methodology in your classroom:

• Action research is a process for improving educational practice. Its methods involve action, evaluation, and reflection. It is a process to gather evidence to implement change in practices.
• Action research is participative and collaborative. It is undertaken by individuals with a common purpose.
• Action research is situation and context-based.
• Action research develops reflection practices based on the interpretations made by participants.
• Knowledge is created through action and application.
• Action research can be based in problem-solving, if the solution to the problem results in the improvement of practice.
• Action research is iterative; plans are created, implemented, revised, then implemented, lending itself to an ongoing process of reflection and revision.
• In action research, findings emerge as action develops and takes place; however, they are not conclusive or absolute, but ongoing (Koshy, 2010, pgs. 1-2).

In thinking about the purpose of action research, it is helpful to situate action research as a distinct paradigm of educational research. I like to think about action research as part of the larger concept of living knowledge. Living knowledge has been characterized as “a quest for life, to understand life and to create… knowledge which is valid for the people with whom I work and for myself” (Swantz, in Reason & Bradbury, 2001, pg. 1). Why should educators care about living knowledge as part of educational research? As mentioned above, action research is meant “to produce practical knowledge that is useful to people in the everyday conduct of their lives and to see that action research is about working towards practical outcomes” (Koshy, 2010, pg. 2). However, it is also about:

creating new forms of understanding, since action without reflection and understanding is blind, just as theory without action is meaningless. The participatory nature of action research makes it only possible with, for and by persons and communities, ideally involving all stakeholders both in the questioning and sense making that informs the research, and in the action, which is its focus. (Reason & Bradbury, 2001, pg. 2)

In an effort to further situate action research as living knowledge, Jean McNiff reminds us that “there is no such ‘thing’ as ‘action research’” (2013, pg. 24). In other words, action research is not static or finished, it defines itself as it proceeds. McNiff’s reminder characterizes action research as action-oriented, and a process that individuals go through to make their learning public to explain how it informs their practice. Action research does not derive its meaning from an abstract idea, or a self-contained discovery – action research’s meaning stems from the way educators negotiate the problems and successes of living and working in the classroom, school, and community.

While we can debate the idea of action research, there are people who are action researchers, and they use the idea of action research to develop principles and theories to guide their practice. Action research, then, refers to an organization of principles that guide action researchers as they act on shared beliefs, commitments, and expectations in their inquiry.

Reflection and the Process of Action Research

When an individual engages in reflection on their actions or experiences, it is typically for the purpose of better understanding those experiences, or the consequences of those actions to improve related action and experiences in the future. Reflection in this way develops knowledge around these actions and experiences to help us better regulate those actions in the future. The reflective process generates new knowledge regularly for classroom teachers and informs their classroom actions.

Unfortunately, the knowledge generated by educators through the reflective process is not always prioritized among the other sources of knowledge educators are expected to utilize in the classroom. Educators are expected to draw upon formal types of knowledge, such as textbooks, content standards, teaching standards, district curriculum and behavioral programs, etc., to gain new knowledge and make decisions in the classroom. While these forms of knowledge are important, the reflective knowledge that educators generate through their pedagogy is the amalgamation of these types of knowledge enacted in the classroom. Therefore, reflective knowledge is uniquely developed based on the action and implementation of an educator’s pedagogy in the classroom. Action research offers a way to formalize the knowledge generated by educators so that it can be utilized and disseminated throughout the teaching profession.

Research is concerned with the generation of knowledge, and typically creating knowledge related to a concept, idea, phenomenon, or topic. Action research generates knowledge around inquiry in practical educational contexts. Action research allows educators to learn through their actions with the purpose of developing personally or professionally. Due to its participatory nature, the process of action research is also distinct in educational research. There are many models for how the action research process takes shape. I will share a few of those here. Each model utilizes the following processes to some extent:

• Plan a change;
• Take action to enact the change;
• Observe the process and consequences of the change;
• Reflect on the process and consequences;
• Act, observe, & reflect again and so on.

Figure 1.1 Basic action research cycle

There are many other models that supplement the basic process of action research with other aspects of the research process to consider. For example, figure 1.2 illustrates a spiral model of action research proposed by Kemmis and McTaggart (2004). The spiral model emphasizes the cyclical process that moves beyond the initial plan for change. The spiral model also emphasizes revisiting the initial plan and revising based on the initial cycle of research:

Figure 1.2 Interpretation of action research spiral, Kemmis and McTaggart (2004, p. 595)

Other models of action research reorganize the process to emphasize the distinct ways knowledge takes shape in the reflection process. O’Leary’s (2004, p. 141) model, for example, recognizes that the research may take shape in the classroom as knowledge emerges from the teacher’s observations. O’Leary highlights the need for action research to be focused on situational understanding and implementation of action, initiated organically from real-time issues:

Figure 1.3 Interpretation of O’Leary’s cycles of research, O’Leary (2000, p. 141)

Lastly, Macintyre’s (2000, p. 1) model, offers a different characterization of the action research process. Macintyre emphasizes a messier process of research with the initial reflections and conclusions as the benchmarks for guiding the research process. Macintyre emphasizes the flexibility in planning, acting, and observing stages to allow the process to be naturalistic. Our interpretation of Macintyre process is below:

Figure 1.4 Interpretation of the action research cycle, Macintyre (2000, p. 1)

We believe it is important to prioritize the flexibility of the process, and encourage you to only use these models as basic guides for your process. Your process may look similar, or you may diverge from these models as you better understand your students, context, and data.

Definitions of Action Research and Examples

At this point, it may be helpful for readers to have a working definition of action research and some examples to illustrate the methodology in the classroom. Bassey (1998, p. 93) offers a very practical definition and describes “action research as an inquiry which is carried out in order to understand, to evaluate and then to change, in order to improve educational practice.” Cohen and Manion (1994, p. 192) situate action research differently, and describe action research as emergent, writing:

essentially an on-the-spot procedure designed to deal with a concrete problem located in an immediate situation. This means that ideally, the step-by-step process is constantly monitored over varying periods of time and by a variety of mechanisms (questionnaires, diaries, interviews and case studies, for example) so that the ensuing feedback may be translated into modifications, adjustment, directional changes, redefinitions, as necessary, so as to bring about lasting benefit to the ongoing process itself rather than to some future occasion.

Lastly, Koshy (2010, p. 9) describes action research as:

a constructive inquiry, during which the researcher constructs his or her knowledge of specific issues through planning, acting, evaluating, refining and learning from the experience. It is a continuous learning process in which the researcher learns and also shares the newly generated knowledge with those who may benefit from it.

These definitions highlight the distinct features of action research and emphasize the purposeful intent of action researchers to improve, refine, reform, and problem-solve issues in their educational context. To better understand the distinctness of action research, these are some examples of action research topics:

Examples of Action Research Topics

• Flexible seating in 4th grade classroom to increase effective collaborative learning.
• Structured homework protocols for increasing student achievement.
• Developing a system of formative feedback for 8th grade writing.
• Using music to stimulate creative writing.
• Weekly brown bag lunch sessions to improve responses to PD from staff.
• Using exercise balls as chairs for better classroom management.

Action Research in Theory

Action research-based inquiry in educational contexts and classrooms involves distinct participants – students, teachers, and other educational stakeholders within the system. All of these participants are engaged in activities to benefit the students, and subsequently society as a whole. Action research contributes to these activities and potentially enhances the participants’ roles in the education system. Participants’ roles are enhanced based on two underlying principles:

• communities, schools, and classrooms are sites of socially mediated actions, and action research provides a greater understanding of self and new knowledge of how to negotiate these socially mediated environments;
• communities, schools, and classrooms are part of social systems in which humans interact with many cultural tools, and action research provides a basis to construct and analyze these interactions.

In our quest for knowledge and understanding, we have consistently analyzed human experience over time and have distinguished between types of reality. Humans have constantly sought “facts” and “truth” about reality that can be empirically demonstrated or observed.

Social systems are based on beliefs, and generally, beliefs about what will benefit the greatest amount of people in that society. Beliefs, and more specifically the rationale or support for beliefs, are not always easy to demonstrate or observe as part of our reality. Take the example of an English Language Arts teacher who prioritizes argumentative writing in her class. She believes that argumentative writing demonstrates the mechanics of writing best among types of writing, while also providing students a skill they will need as citizens and professionals. While we can observe the students writing, and we can assess their ability to develop a written argument, it is difficult to observe the students’ understanding of argumentative writing and its purpose in their future. This relates to the teacher’s beliefs about argumentative writing; we cannot observe the real value of the teaching of argumentative writing. The teacher’s rationale and beliefs about teaching argumentative writing are bound to the social system and the skills their students will need to be active parts of that system. Therefore, our goal through action research is to demonstrate the best ways to teach argumentative writing to help all participants understand its value as part of a social system.

The knowledge that is conveyed in a classroom is bound to, and justified by, a social system. A postmodernist approach to understanding our world seeks knowledge within a social system, which is directly opposed to the empirical or positivist approach which demands evidence based on logic or science as rationale for beliefs. Action research does not rely on a positivist viewpoint to develop evidence and conclusions as part of the research process. Action research offers a postmodernist stance to epistemology (theory of knowledge) and supports developing questions and new inquiries during the research process. In this way action research is an emergent process that allows beliefs and decisions to be negotiated as reality and meaning are being constructed in the socially mediated space of the classroom.

Theorizing Action Research for the Classroom

All research, at its core, is for the purpose of generating new knowledge and contributing to the knowledge base of educational research. Action researchers in the classroom want to explore methods of improving their pedagogy and practice. The starting place of their inquiry stems from their pedagogy and practice, so by nature the knowledge created from their inquiry is often contextually specific to their classroom, school, or community. Therefore, we should examine the theoretical underpinnings of action research for the classroom. It is important to connect action research conceptually to experience; for example, Levin and Greenwood (2001, p. 105) make these connections:

• Action research is context bound and addresses real life problems.
• Action research is inquiry where participants and researchers cogenerate knowledge through collaborative communicative processes in which all participants’ contributions are taken seriously.
• The meanings constructed in the inquiry process lead to social action or these reflections and action lead to the construction of new meanings.
• The credibility/validity of action research knowledge is measured according to whether the actions that arise from it solve problems (workability) and increase participants’ control over their own situation.

Educators who engage in action research will generate new knowledge and beliefs based on their experiences in the classroom. Let us emphasize that these are all important to you and your work, as both an educator and researcher. It is these experiences, beliefs, and theories that are often discounted when more official forms of knowledge (e.g., textbooks, curriculum standards, districts standards) are prioritized. These beliefs and theories based on experiences should be valued and explored further, and this is one of the primary purposes of action research in the classroom. These beliefs and theories should be valued because they were meaningful aspects of knowledge constructed from teachers’ experiences. Developing meaning and knowledge in this way forms the basis of constructivist ideology, just as teachers often try to get their students to construct their own meanings and understandings when experiencing new ideas.  

Classroom Teachers Constructing their Own Knowledge

Most of you are probably at least minimally familiar with constructivism, or the process of constructing knowledge. However, what is constructivism precisely, for the purposes of action research? Many scholars have theorized constructivism and have identified two key attributes (Koshy, 2010; von Glasersfeld, 1987):

• Knowledge is not passively received, but actively developed through an individual’s cognition;
• Human cognition is adaptive and finds purpose in organizing the new experiences of the world, instead of settling for absolute or objective truth.

Considering these two attributes, constructivism is distinct from conventional knowledge formation because people can develop a theory of knowledge that orders and organizes the world based on their experiences, instead of an objective or neutral reality. When individuals construct knowledge, there are interactions between an individual and their environment where communication, negotiation and meaning-making are collectively developing knowledge. For most educators, constructivism may be a natural inclination of their pedagogy. Action researchers have a similar relationship to constructivism because they are actively engaged in a process of constructing knowledge. However, their constructions may be more formal and based on the data they collect in the research process. Action researchers also are engaged in the meaning making process, making interpretations from their data. These aspects of the action research process situate them in the constructivist ideology. Just like constructivist educators, action researchers’ constructions of knowledge will be affected by their individual and professional ideas and values, as well as the ecological context in which they work (Biesta & Tedder, 2006). The relations between constructivist inquiry and action research is important, as Lincoln (2001, p. 130) states:

much of the epistemological, ontological, and axiological belief systems are the same or similar, and methodologically, constructivists and action researchers work in similar ways, relying on qualitative methods in face-to-face work, while buttressing information, data and background with quantitative method work when necessary or useful.

While there are many links between action research and educators in the classroom, constructivism offers the most familiar and practical threads to bind the beliefs of educators and action researchers.  

Epistemology, Ontology, and Action Research

It is also important for educators to consider the philosophical stances related to action research to better situate it with their beliefs and reality. When researchers make decisions about the methodology they intend to use, they will consider their ontological and epistemological stances. It is vital that researchers clearly distinguish their philosophical stances and understand the implications of their stance in the research process, especially when collecting and analyzing their data. In what follows, we will discuss ontological and epistemological stances in relation to action research methodology.

Ontology, or the theory of being, is concerned with the claims or assumptions we make about ourselves within our social reality – what do we think exists, what does it look like, what entities are involved and how do these entities interact with each other (Blaikie, 2007). In relation to the discussion of constructivism, generally action researchers would consider their educational reality as socially constructed. Social construction of reality happens when individuals interact in a social system. Meaningful construction of concepts and representations of reality develop through an individual’s interpretations of others’ actions. These interpretations become agreed upon by members of a social system and become part of social fabric, reproduced as knowledge and beliefs to develop assumptions about reality. Researchers develop meaningful constructions based on their experiences and through communication. Educators as action researchers will be examining the socially constructed reality of schools. In the United States, many of our concepts, knowledge, and beliefs about schooling have been socially constructed over the last hundred years. For example, a group of teachers may look at why fewer female students enroll in upper-level science courses at their school. This question deals directly with the social construction of gender and specifically what careers females have been conditioned to pursue. We know this is a social construction in some school social systems because in other parts of the world, or even the United States, there are schools that have more females enrolled in upper level science courses than male students. Therefore, the educators conducting the research have to recognize the socially constructed reality of their school and consider this reality throughout the research process. Action researchers will use methods of data collection that support their ontological stance and clarify their theoretical stance throughout the research process.

Koshy (2010, p. 23-24) offers another example of addressing the ontological challenges in the classroom:

A teacher who was concerned with increasing her pupils’ motivation and enthusiasm for learning decided to introduce learning diaries which the children could take home. They were invited to record their reactions to the day’s lessons and what they had learnt. The teacher reported in her field diary that the learning diaries stimulated the children’s interest in her lessons, increased their capacity to learn, and generally improved their level of participation in lessons. The challenge for the teacher here is in the analysis and interpretation of the multiplicity of factors accompanying the use of diaries. The diaries were taken home so the entries may have been influenced by discussions with parents. Another possibility is that children felt the need to please their teacher. Another possible influence was that their increased motivation was as a result of the difference in style of teaching which included more discussions in the classroom based on the entries in the dairies.

Here you can see the challenge for the action researcher is working in a social context with multiple factors, values, and experiences that were outside of the teacher’s control. The teacher was only responsible for introducing the diaries as a new style of learning. The students’ engagement and interactions with this new style of learning were all based upon their socially constructed notions of learning inside and outside of the classroom. A researcher with a positivist ontological stance would not consider these factors, and instead might simply conclude that the dairies increased motivation and interest in the topic, as a result of introducing the diaries as a learning strategy.

Epistemology, or the theory of knowledge, signifies a philosophical view of what counts as knowledge – it justifies what is possible to be known and what criteria distinguishes knowledge from beliefs (Blaikie, 1993). Positivist researchers, for example, consider knowledge to be certain and discovered through scientific processes. Action researchers collect data that is more subjective and examine personal experience, insights, and beliefs.

Action researchers utilize interpretation as a means for knowledge creation. Action researchers have many epistemologies to choose from as means of situating the types of knowledge they will generate by interpreting the data from their research. For example, Koro-Ljungberg et al., (2009) identified several common epistemologies in their article that examined epistemological awareness in qualitative educational research, such as: objectivism, subjectivism, constructionism, contextualism, social epistemology, feminist epistemology, idealism, naturalized epistemology, externalism, relativism, skepticism, and pluralism. All of these epistemological stances have implications for the research process, especially data collection and analysis. Please see the table on pages 689-90, linked below for a sketch of these potential implications:

Again, Koshy (2010, p. 24) provides an excellent example to illustrate the epistemological challenges within action research:

A teacher of 11-year-old children decided to carry out an action research project which involved a change in style in teaching mathematics. Instead of giving children mathematical tasks displaying the subject as abstract principles, she made links with other subjects which she believed would encourage children to see mathematics as a discipline that could improve their understanding of the environment and historic events. At the conclusion of the project, the teacher reported that applicable mathematics generated greater enthusiasm and understanding of the subject.

The educator/researcher engaged in action research-based inquiry to improve an aspect of her pedagogy. She generated knowledge that indicated she had improved her students’ understanding of mathematics by integrating it with other subjects – specifically in the social and ecological context of her classroom, school, and community. She valued constructivism and students generating their own understanding of mathematics based on related topics in other subjects. Action researchers working in a social context do not generate certain knowledge, but knowledge that emerges and can be observed and researched again, building upon their knowledge each time.

Researcher Positionality in Action Research

In this first chapter, we have discussed a lot about the role of experiences in sparking the research process in the classroom. Your experiences as an educator will shape how you approach action research in your classroom. Your experiences as a person in general will also shape how you create knowledge from your research process. In particular, your experiences will shape how you make meaning from your findings. It is important to be clear about your experiences when developing your methodology too. This is referred to as researcher positionality. Maher and Tetreault (1993, p. 118) define positionality as:

Gender, race, class, and other aspects of our identities are markers of relational positions rather than essential qualities. Knowledge is valid when it includes an acknowledgment of the knower’s specific position in any context, because changing contextual and relational factors are crucial for defining identities and our knowledge in any given situation.

By presenting your positionality in the research process, you are signifying the type of socially constructed, and other types of, knowledge you will be using to make sense of the data. As Maher and Tetreault explain, this increases the trustworthiness of your conclusions about the data. This would not be possible with a positivist ontology. We will discuss positionality more in chapter 6, but we wanted to connect it to the overall theoretical underpinnings of action research.

Advantages of Engaging in Action Research in the Classroom

In the following chapters, we will discuss how action research takes shape in your classroom, and we wanted to briefly summarize the key advantages to action research methodology over other types of research methodology. As Koshy (2010, p. 25) notes, action research provides useful methodology for school and classroom research because:

Advantages of Action Research for the Classroom

• research can be set within a specific context or situation;
• researchers can be participants – they don’t have to be distant and detached from the situation;
• it involves continuous evaluation and modifications can be made easily as the project progresses;
• there are opportunities for theory to emerge from the research rather than always follow a previously formulated theory;
• the study can lead to open-ended outcomes;
• through action research, a researcher can bring a story to life.

Action Research Copyright © by J. Spencer Clark; Suzanne Porath; Julie Thiele; and Morgan Jobe is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License , except where otherwise noted.

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• Published: 02 December 2020

Enhancing senior high school student engagement and academic performance using an inclusive and scalable inquiry-based program

• Locke Davenport Huyer   ORCID: orcid.org/0000-0003-1526-7122 1 , 2   na1 ,
• Neal I. Callaghan   ORCID: orcid.org/0000-0001-8214-3395 1 , 3   na1 ,
• Sara Dicks 4 ,
• Edward Scherer 4 ,
• Andrey I. Shukalyuk 1 ,
• Margaret Jou 4 &
• Dawn M. Kilkenny   ORCID: orcid.org/0000-0002-3899-9767 1 , 5  

npj Science of Learning volume  5 , Article number:  17 ( 2020 ) Cite this article

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The multi-disciplinary nature of science, technology, engineering, and math (STEM) careers often renders difficulty for high school students navigating from classroom knowledge to post-secondary pursuits. Discrepancies between the knowledge-based high school learning approach and the experiential approach of future studies leaves some students disillusioned by STEM. We present Discovery , a term-long inquiry-focused learning model delivered by STEM graduate students in collaboration with high school teachers, in the context of biomedical engineering. Entire classes of high school STEM students representing diverse cultural and socioeconomic backgrounds engaged in iterative, problem-based learning designed to emphasize critical thinking concomitantly within the secondary school and university environments. Assessment of grades and survey data suggested positive impact of this learning model on students’ STEM interests and engagement, notably in under-performing cohorts, as well as repeating cohorts that engage in the program on more than one occasion. Discovery presents a scalable platform that stimulates persistence in STEM learning, providing valuable learning opportunities and capturing cohorts of students that might otherwise be under-engaged in STEM.

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Introduction.

High school students with diverse STEM interests often struggle to understand the STEM experience outside the classroom 1 . The multi-disciplinary nature of many career fields can foster a challenge for students in their decision to enroll in appropriate high school courses while maintaining persistence in study, particularly when these courses are not mandatory 2 . Furthermore, this challenge is amplified by the known discrepancy between the knowledge-based learning approach common in high schools and the experiential, mastery-based approaches afforded by the subsequent undergraduate model 3 . In the latter, focused classes, interdisciplinary concepts, and laboratory experiences allow for the application of accumulated knowledge, practice in problem solving, and development of both general and technical skills 4 . Such immersive cooperative learning environments are difficult to establish in the secondary school setting and high school teachers often struggle to implement within their classroom 5 . As such, high school students may become disillusioned before graduation and never experience an enriched learning environment, despite their inherent interests in STEM 6 .

It cannot be argued that early introduction to varied math and science disciplines throughout high school is vital if students are to pursue STEM fields, especially within engineering 7 . However, the majority of literature focused on student interest and retention in STEM highlights outcomes in US high school learning environments, where the sciences are often subject-specific from the onset of enrollment 8 . In contrast, students in the Ontario (Canada) high school system are required to complete Level 1 and 2 core courses in science and math during Grades 9 and 10; these courses are offered as ‘applied’ or ‘academic’ versions and present broad topics of content 9 . It is not until Levels 3 and 4 (generally Grades 11 and 12, respectively) that STEM classes become subject-specific (i.e., Biology, Chemistry, and/or Physics) and are offered as “university”, “college”, or “mixed” versions, designed to best prepare students for their desired post-secondary pursuits 9 . Given that Levels 3 and 4 science courses are not mandatory for graduation, enrollment identifies an innate student interest in continued learning. Furthermore, engagement in these post-secondary preparatory courses is also dependent upon achieving successful grades in preceding courses, but as curriculum becomes more subject-specific, students often yield lower degrees of success in achieving course credit 2 . Therefore, it is imperative that learning supports are best focused on ensuring that those students with an innate interest are able to achieve success in learning.

When given opportunity and focused support, high school students are capable of successfully completing rigorous programs at STEM-focused schools 10 . Specialized STEM schools have existed in the US for over 100 years; generally, students are admitted after their sophomore year of high school experience (equivalent to Grade 10) based on standardized test scores, essays, portfolios, references, and/or interviews 11 . Common elements to this learning framework include a diverse array of advanced STEM courses, paired with opportunities to engage in and disseminate cutting-edge research 12 . Therein, said research experience is inherently based in the processes of critical thinking, problem solving, and collaboration. This learning framework supports translation of core curricular concepts to practice and is fundamental in allowing students to develop better understanding and appreciation of STEM career fields.

Despite the described positive attributes, many students do not have the ability or resources to engage within STEM-focused schools, particularly given that they are not prevalent across Canada, and other countries across the world. Consequently, many public institutions support the idea that post-secondary led engineering education programs are effective ways to expose high school students to engineering education and relevant career options, and also increase engineering awareness 13 . Although singular class field trips are used extensively to accomplish such programs, these may not allow immersive experiences for application of knowledge and practice of skills that are proven to impact long-term learning and influence career choices 14 , 15 . Longer-term immersive research experiences, such as after-school programs or summer camps, have shown successful at recruiting students into STEM degree programs and careers, where longevity of experience helps foster self-determination and interest-led, inquiry-based projects 4 , 16 , 17 , 18 , 19 .

Such activities convey the elements that are suggested to make a post-secondary led high school education programs successful: hands-on experience, self-motivated learning, real-life application, immediate feedback, and problem-based projects 20 , 21 . In combination with immersion in university teaching facilities, learning is authentic and relevant, similar to the STEM school-focused framework, and consequently representative of an experience found in actual STEM practice 22 . These outcomes may further be a consequence of student engagement and attitude: Brown et al. studied the relationships between STEM curriculum and student attitudes, and found the latter played a more important role in intention to persist in STEM when compared to self-efficacy 23 . This is interesting given that student self-efficacy has been identified to influence ‘motivation, persistence, and determination’ in overcoming challenges in a career pathway 24 . Taken together, this suggests that creation and delivery of modern, exciting curriculum that supports positive student attitudes is fundamental to engage and retain students in STEM programs.

Supported by the outcomes of identified effective learning strategies, University of Toronto (U of T) graduate trainees created a novel high school education program Discovery , to develop a comfortable yet stimulating environment of inquiry-focused iterative learning for senior high school students (Grades 11 & 12; Levels 3 & 4) at non-specialized schools. Built in strong collaboration with science teachers from George Harvey Collegiate Institute (Toronto District School Board), Discovery stimulates application of STEM concepts within a unique term-long applied curriculum delivered iteratively within both U of T undergraduate teaching facilities and collaborating high school classrooms 25 . Based on the volume of medically-themed news and entertainment that is communicated to the population at large, the rapidly-growing and diverse field of biomedical engineering (BME) were considered an ideal program context 26 . In its definition, BME necessitates cross-disciplinary STEM knowledge focused on the betterment of human health, wherein Discovery facilitates broadening student perspective through engaging inquiry-based projects. Importantly, Discovery allows all students within a class cohort to work together with their classroom teacher, stimulating continued development of a relevant learning community that is deemed essential for meaningful context and important for transforming student perspectives and understandings 27 , 28 . Multiple studies support the concept that relevant learning communities improve student attitudes towards learning, significantly increasing student motivation in STEM courses, and consequently improving the overall learning experience 29 . Learning communities, such as that provided by Discovery , also promote the formation of self-supporting groups, greater active involvement in class, and higher persistence rates for participating students 30 .

The objective of Discovery , through structure and dissemination, is to engage senior high school science students in challenging, inquiry-based practical BME activities as a mechanism to stimulate comprehension of STEM curriculum application to real-world concepts. Consequent focus is placed on critical thinking skill development through an atmosphere of perseverance in ambiguity, something not common in a secondary school knowledge-focused delivery but highly relevant in post-secondary STEM education strategies. Herein, we describe the observed impact of the differential project-based learning environment of Discovery on student performance and engagement. We identify the value of an inquiry-focused learning model that is tangible for students who struggle in a knowledge-focused delivery structure, where engagement in conceptual critical thinking in the relevant subject area stimulates student interest, attitudes, and resulting academic performance. Assessment of study outcomes suggests that when provided with a differential learning opportunity, student performance and interest in STEM increased. Consequently, Discovery provides an effective teaching and learning framework within a non-specialized school that motivates students, provides opportunity for critical thinking and problem-solving practice, and better prepares them for persistence in future STEM programs.

Program delivery

The outcomes of the current study result from execution of Discovery over five independent academic terms as a collaboration between Institute of Biomedical Engineering (graduate students, faculty, and support staff) and George Harvey Collegiate Institute (science teachers and administration) stakeholders. Each term, the program allowed senior secondary STEM students (Grades 11 and 12) opportunity to engage in a novel project-based learning environment. The program structure uses the problem-based engineering capstone framework as a tool of inquiry-focused learning objectives, motivated by a central BME global research topic, with research questions that are inter-related but specific to the curriculum of each STEM course subject (Fig. 1 ). Over each 12-week term, students worked in teams (3–4 students) within their class cohorts to execute projects with the guidance of U of T trainees ( Discovery instructors) and their own high school teacher(s). Student experimental work was conducted in U of T teaching facilities relevant to the research study of interest (i.e., Biology and Chemistry-based projects executed within Undergraduate Teaching Laboratories; Physics projects executed within Undergraduate Design Studios). Students were introduced to relevant techniques and safety procedures in advance of iterative experimentation. Importantly, this experience served as a course term project for students, who were assessed at several points throughout the program for performance in an inquiry-focused environment as well as within the regular classroom (Fig. 1 ). To instill the atmosphere of STEM, student teams delivered their outcomes in research poster format at a final symposium, sharing their results and recommendations with other post-secondary students, faculty, and community in an open environment.

The general program concept (blue background; top left ) highlights a global research topic examined through student dissemination of subject-specific research questions, yielding multifaceted student outcomes (orange background; top right ). Each program term (term workflow, yellow background; bottom panel ), students work on program deliverables in class (blue), iterate experimental outcomes within university facilities (orange), and are assessed accordingly at numerous deliverables in an inquiry-focused learning model.

Over the course of five terms there were 268 instances of tracked student participation, representing 170 individual students. Specifically, 94 students participated during only one term of programming, 57 students participated in two terms, 16 students participated in three terms, and 3 students participated in four terms. Multiple instances of participation represent students that enrol in more than one STEM class during their senior years of high school, or who participated in Grade 11 and subsequently Grade 12. Students were surveyed before and after each term to assess program effects on STEM interest and engagement. All grade-based assessments were performed by high school teachers for their respective STEM class cohorts using consistent grading rubrics and assignment structure. Here, we discuss the outcomes of student involvement in this experiential curriculum model.

Student performance and engagement

Student grades were assigned, collected, and anonymized by teachers for each Discovery deliverable (background essay, client meeting, proposal, progress report, poster, and final presentation). Teachers anonymized collective Discovery grades, the component deliverable grades thereof, final course grades, attendance in class and during programming, as well as incomplete classroom assignments, for comparative study purposes. Students performed significantly higher in their cumulative Discovery grade than in their cumulative classroom grade (final course grade less the Discovery contribution; p  < 0.0001). Nevertheless, there was a highly significant correlation ( p  < 0.0001) observed between the grade representing combined Discovery deliverables and the final course grade (Fig. 2a ). Further examination of the full dataset revealed two student cohorts of interest: the “Exceeds Expectations” (EE) subset (defined as those students who achieved ≥1 SD [18.0%] grade differential in Discovery over their final course grade; N  = 99 instances), and the “Multiple Term” (MT) subset (defined as those students who participated in Discovery more than once; 76 individual students that collectively accounted for 174 single terms of assessment out of the 268 total student-terms delivered) (Fig. 2b, c ). These subsets were not unrelated; 46 individual students who had multiple experiences (60.5% of total MTs) exhibited at least one occasion in achieving a ≥18.0% grade differential. As students participated in group work, there was concern that lower-performing students might negatively influence the Discovery grade of higher-performing students (or vice versa). However, students were observed to self-organize into groups where all individuals received similar final overall course grades (Fig. 2d ), thereby alleviating these concerns.

a Linear regression of student grades reveals a significant correlation ( p  = 0.0009) between Discovery performance and final course grade less the Discovery contribution to grade, as assessed by teachers. The dashed red line and intervals represent the theoretical 1:1 correlation between Discovery and course grades and standard deviation of the Discovery -course grade differential, respectively. b , c Identification of subgroups of interest, Exceeds Expectations (EE; N  = 99, orange ) who were ≥+1 SD in Discovery -course grade differential and Multi-Term (MT; N  = 174, teal ), of which N  = 65 students were present in both subgroups. d Students tended to self-assemble in working groups according to their final course performance; data presented as mean ± SEM. e For MT students participating at least 3 terms in Discovery , there was no significant correlation between course grade and time, while ( f ) there was a significant correlation between Discovery grade and cumulative terms in the program. Histograms of total absences per student in ( g ) Discovery and ( h ) class (binned by 4 days to be equivalent in time to a single Discovery absence).

The benefits experienced by MT students seemed progressive; MT students that participated in 3 or 4 terms ( N  = 16 and 3, respectively ) showed no significant increase by linear regression in their course grade over time ( p  = 0.15, Fig. 2e ), but did show a significant increase in their Discovery grades ( p  = 0.0011, Fig. 2f ). Finally, students demonstrated excellent Discovery attendance; at least 91% of participants attended all Discovery sessions in a given term (Fig. 2g ). In contrast, class attendance rates reveal a much wider distribution where 60.8% (163 out of 268 students) missed more than 4 classes (equivalent in learning time to one Discovery session) and 14.6% (39 out of 268 students) missed 16 or more classes (equivalent in learning time to an entire program of Discovery ) in a term (Fig. 2h ).

Discovery EE students (Fig. 3 ), roughly by definition, obtained lower course grades ( p  < 0.0001, Fig. 3a ) and higher final Discovery grades ( p  = 0.0004, Fig. 3b ) than non-EE students. This cohort of students exhibited program grades higher than classmates (Fig. 3c–h ); these differences were significant in every category with the exception of essays, where they outperformed to a significantly lesser degree ( p  = 0.097; Fig. 3c ). There was no statistically significant difference in EE vs. non-EE student classroom attendance ( p  = 0.85; Fig. 3i, j ). There were only four single day absences in Discovery within the EE subset; however, this difference was not statistically significant ( p  = 0.074).

The “Exceeds Expectations” (EE) subset of students (defined as those who received a combined Discovery grade ≥1 SD (18.0%) higher than their final course grade) performed ( a ) lower on their final course grade and ( b ) higher in the Discovery program as a whole when compared to their classmates. d – h EE students received significantly higher grades on each Discovery deliverable than their classmates, except for their ( c ) introductory essays and ( h ) final presentations. The EE subset also tended ( i ) to have a higher relative rate of attendance during Discovery sessions but no difference in ( j ) classroom attendance. N  = 99 EE students and 169 non-EE students (268 total). Grade data expressed as mean ± SEM.

Discovery MT students (Fig. 4 ), although not receiving significantly higher grades in class than students participating in the program only one time ( p  = 0.29, Fig. 4a ), were observed to obtain higher final Discovery grades than single-term students ( p  = 0.0067, Fig. 4b ). Although trends were less pronounced for individual MT student deliverables (Fig. 4c–h ), this student group performed significantly better on the progress report ( p  = 0.0021; Fig. 4f ). Trends of higher performance were observed for initial proposals and final presentations ( p  = 0.081 and 0.056, respectively; Fig. 4e, h ); all other deliverables were not significantly different between MT and non-MT students (Fig. 4c, d, g ). Attendance in Discovery ( p  = 0.22) was also not significantly different between MT and non-MT students, although MT students did miss significantly less class time ( p  = 0.010) (Fig. 4i, j ). Longitudinal assessment of individual deliverables for MT students that participated in three or more Discovery terms (Fig. 5 ) further highlights trend in improvement (Fig. 2f ). Greater performance over terms of participation was observed for essay ( p  = 0.0295, Fig. 5a ), client meeting ( p  = 0.0003, Fig. 5b ), proposal ( p  = 0.0004, Fig. 5c ), progress report ( p  = 0.16, Fig. 5d ), poster ( p  = 0.0005, Fig. 5e ), and presentation ( p  = 0.0295, Fig. 5f ) deliverable grades; these trends were all significant with the exception of the progress report ( p  = 0.16, Fig. 5d ) owing to strong performance in this deliverable in all terms.

The “multi-term” (MT) subset of students (defined as having attended more than one term of Discovery ) demonstrated favorable performance in Discovery , ( a ) showing no difference in course grade compared to single-term students, but ( b outperforming them in final Discovery grade. Independent of the number of times participating in Discovery , MT students did not score significantly differently on their ( c ) essay, ( d ) client meeting, or ( g ) poster. They tended to outperform their single-term classmates on the ( e ) proposal and ( h ) final presentation and scored significantly higher on their ( f ) progress report. MT students showed no statistical difference in ( i ) Discovery attendance but did show ( j ) higher rates of classroom attendance than single-term students. N  = 174 MT instances of student participation (76 individual students) and 94 single-term students. Grade data expressed as mean ± SEM.

Longitudinal assessment of a subset of MT student participants that participated in three ( N  = 16) or four ( N  = 3) terms presents a significant trend of improvement in their ( a ) essay, ( b ) client meeting, ( c ) proposal, ( e ) poster, and ( f ) presentation grade. d Progress report grades present a trend in improvement but demonstrate strong performance in all terms, limiting potential for student improvement. Grade data are presented as individual student performance; each student is represented by one color; data is fitted with a linear trendline (black).

Finally, the expansion of Discovery to a second school of lower LOI (i.e., nominally higher aggregate SES) allowed for the assessment of program impact in a new population over 2 terms of programming. A significant ( p  = 0.040) divergence in Discovery vs. course grade distribution from the theoretical 1:1 relationship was found in the new cohort (S 1 Appendix , Fig. S 1 ), in keeping with the pattern established in this study.

Teacher perceptions

Qualitative observation in the classroom by high school teachers emphasized the value students independently placed on program participation and deliverables. Throughout the term, students often prioritized Discovery group assignments over other tasks for their STEM courses, regardless of academic weight and/or due date. Comparing within this student population, teachers spoke of difficulties with late and incomplete assignments in the regular curriculum but found very few such instances with respect to Discovery -associated deliverables. Further, teachers speculated on the good behavior and focus of students in Discovery programming in contrast to attentiveness and behavior issues in their school classrooms. Multiple anecdotal examples were shared of renewed perception of student potential; students that exhibited poor academic performance in the classroom often engaged with high performance in this inquiry-focused atmosphere. Students appeared to take a sense of ownership, excitement, and pride in the setting of group projects oriented around scientific inquiry, discovery, and dissemination.

Student perceptions

Students were asked to consider and rank the academic difficulty (scale of 1–5, with 1 = not challenging and 5 = highly challenging) of the work they conducted within the Discovery learning model. Considering individual Discovery terms, at least 91% of students felt the curriculum to be sufficiently challenging with a 3/5 or higher ranking (Term 1: 87.5%, Term 2: 93.4%, Term 3: 85%, Term 4: 93.3%, Term 5: 100%), and a minimum of 58% of students indicating a 4/5 or higher ranking (Term 1: 58.3%, Term 2: 70.5%, Term 3: 67.5%, Term 4: 69.1%, Term 5: 86.4%) (Fig. 6a ).

a Histogram of relative frequency of perceived Discovery programming academic difficulty ranked from not challenging (1) to highly challenging (5) for each session demonstrated the consistently perceived high degree of difficulty for Discovery programming (total responses: 223). b Program participation increased student comfort (94.6%) with navigating lab work in a university or college setting (total responses: 220). c Considering participation in Discovery programming, students indicated their increased (72.4%) or decreased (10.1%) likelihood to pursue future experiences in STEM as a measure of program impact (total responses: 217). d Large majority of participating students (84.9%) indicated their interest for future participation in Discovery (total responses: 212). Students were given the opportunity to opt out of individual survey questions, partially completed surveys were included in totals.

The majority of students (94.6%) indicated they felt more comfortable with the idea of performing future work in a university STEM laboratory environment given exposure to university teaching facilities throughout the program (Fig. 6b ). Students were also queried whether they were (i) more likely, (ii) less likely, or (iii) not impacted by their experience in the pursuit of STEM in the future. The majority of participants (>82%) perceived impact on STEM interests, with 72.4% indicating they were more likely to pursue these interests in the future (Fig. 6c ). When surveyed at the end of term, 84.9% of students indicated they would participate in the program again (Fig. 6d ).

We have described an inquiry-based framework for implementing experiential STEM education in a BME setting. Using this model, we engaged 268 instances of student participation (170 individual students who participated 1–4 times) over five terms in project-based learning wherein students worked in peer-based teams under the mentorship of U of T trainees to design and execute the scientific method in answering a relevant research question. Collaboration between high school teachers and Discovery instructors allowed for high school student exposure to cutting-edge BME research topics, participation in facilitated inquiry, and acquisition of knowledge through scientific discovery. All assessments were conducted by high school teachers and constituted a fraction (10–15%) of the overall course grade, instilling academic value for participating students. As such, students exhibited excitement to learn as well as commitment to their studies in the program.

Through our observations and analysis, we suggest there is value in differential learning environments for students that struggle in a knowledge acquisition-focused classroom setting. In general, we observed a high level of academic performance in Discovery programming (Fig. 2a ), which was highlighted exceptionally in EE students who exhibited greater academic performance in Discovery deliverables compared to normal coursework (>18% grade improvement in relevant deliverables). We initially considered whether this was the result of strong students influencing weaker students; however, group organization within each course suggests this is not the case (Fig. 2d ). With the exception of one class in one term (24 participants assigned by their teacher), students were allowed to self-organize into working groups and they chose to work with other students of relatively similar academic performance (as indicated by course grade), a trend observed in other studies 31 , 32 . Remarkably, EE students not only excelled during Discovery when compared to their own performance in class, but this cohort also achieved significantly higher average grades in each of the deliverables throughout the program when compared to the remaining Discovery cohort (Fig. 3 ). This data demonstrates the value of an inquiry-based learning environment compared to knowledge-focused delivery in the classroom in allowing students to excel. We expect that part of this engagement was resultant of student excitement with a novel learning opportunity. It is however a well-supported concept that students who struggle in traditional settings tend to demonstrate improved interest and motivation in STEM when given opportunity to interact in a hands-on fashion, which supports our outcomes 4 , 33 . Furthermore, these outcomes clearly represent variable student learning styles, where some students benefit from a greater exchange of information, knowledge and skills in a cooperative learning environment 34 . The performance of the EE group may not be by itself surprising, as the identification of the subset by definition required high performers in Discovery who did not have exceptionally high course grades; in addition, the final Discovery grade is dependent on the component assignment grades. However, the discrepancies between EE and non-EE groups attendance suggests that students were engaged by Discovery in a way that they were not by regular classroom curriculum.

In addition to quantified engagement in Discovery observed in academic performance, we believe remarkable attendance rates are indicative of the value students place in the differential learning structure. Given the differences in number of Discovery days and implications of missing one day of regular class compared to this immersive program, we acknowledge it is challenging to directly compare attendance data and therefore approximate this comparison with consideration of learning time equivalence. When combined with other subjective data including student focus, requests to work on Discovery during class time, and lack of discipline/behavior issues, the attendance data importantly suggests that students were especially engaged by the Discovery model. Further, we believe the increased commute time to the university campus (students are responsible for independent transit to campus, a much longer endeavour than the normal school commute), early program start time, and students’ lack of familiarity with the location are non-trivial considerations when determining the propensity of students to participate enthusiastically in Discovery . We feel this suggests the students place value on this team-focused learning and find it to be more applicable and meaningful to their interests.

Given post-secondary admission requirements for STEM programs, it would be prudent to think that students participating in multiple STEM classes across terms are the ones with the most inherent interest in post-secondary STEM programs. The MT subset, representing students who participated in Discovery for more than one term, averaged significantly higher final Discovery grades. The increase in the final Discovery grade was observed to result from a general confluence of improved performance over multiple deliverables and a continuous effort to improve in a STEM curriculum. This was reflected in longitudinal tracking of Discovery performance, where we observed a significant trend of improved performance. Interestingly, the high number of MT students who were included in the EE group suggests that students who had a keen interest in science enrolled in more than one course and in general responded well to the inquiry-based teaching method of Discovery , where scientific method was put into action. It stands to reason that students interested in science will continue to take STEM courses and will respond favorably to opportunities to put classroom theory to practical application.

The true value of an inquiry-based program such as Discovery may not be based in inspiring students to perform at a higher standard in STEM within the high school setting, as skills in critical thinking do not necessarily translate to knowledge-based assessment. Notably, students found the programming equally challenging throughout each of the sequential sessions, perhaps somewhat surprising considering the increasing number of repeat attendees in successive sessions (Fig. 6a ). Regardless of sub-discipline, there was an emphasis of perceived value demonstrated through student surveys where we observed indicated interest in STEM and comfort with laboratory work environments, and desire to engage in future iterations given the opportunity. Although non-quantitative, we perceive this as an indicator of significant student engagement, even though some participants did not yield academic success in the program and found it highly challenging given its ambiguity.

Although we observed that students become more certain of their direction in STEM, further longitudinal study is warranted to make claim of this outcome. Additionally, at this point in our assessment we cannot effectively assess the practical outcomes of participation, understanding that the immediate effects observed are subject to a number of factors associated with performance in the high school learning environment. Future studies that track graduates from this program will be prudent, in conjunction with an ever-growing dataset of assessment as well as surveys designed to better elucidate underlying perceptions and attitudes, to continue to understand the expected benefits of this inquiry-focused and partnered approach. Altogether, a multifaceted assessment of our early outcomes suggests significant value of an immersive and iterative interaction with STEM as part of the high school experience. A well-defined divergence from knowledge-based learning, focused on engagement in critical thinking development framed in the cutting-edge of STEM, may be an important step to broadening student perspectives.

In this study, we describe the short-term effects of an inquiry-based STEM educational experience on a cohort of secondary students attending a non-specialized school, and suggest that the framework can be widely applied across virtually all subjects where inquiry-driven and mentored projects can be undertaken. Although we have demonstrated replication in a second cohort of nominally higher SES (S 1 Appendix , Supplementary Fig. 1 ), a larger collection period with more students will be necessary to conclusively determine impact independent of both SES and specific cohort effects. Teachers may also find this framework difficult to implement depending on resources and/or institutional investment and support, particularly if post-secondary collaboration is inaccessible. Offerings to a specific subject (e.g., physics) where experiments yielding empirical data are logistically or financially simpler to perform may be valid routes of adoption as opposed to the current study where all subject cohorts were included.

As we consider Discovery in a bigger picture context, expansion and implementation of this model is translatable. Execution of the scientific method is an important aspect of citizen science, as the concepts of critical thing become ever-more important in a landscape of changing technological landscapes. Giving students critical thinking and problem-solving skills in their primary and secondary education provides value in the context of any career path. Further, we feel that this model is scalable across disciplines, STEM or otherwise, as a means of building the tools of inquiry. We have observed here the value of differential inclusive student engagement and critical thinking through an inquiry-focused model for a subset of students, but further to this an engagement, interest, and excitement across the body of student participants. As we educate the leaders of tomorrow, we suggest that use of an inquiry-focused model such as Discovery could facilitate growth of a data-driven critical thinking framework.

In conclusion, we have presented a model of inquiry-based STEM education for secondary students that emphasizes inclusion, quantitative analysis, and critical thinking. Student grades suggest significant performance benefits, and engagement data suggests positive student attitude despite the perceived challenges of the program. We also note a particular performance benefit to students who repeatedly engage in the program. This framework may carry benefits in a wide variety of settings and disciplines for enhancing student engagement and performance, particularly in non-specialized school environments.

Study design and implementation

Participants in Discovery include all students enrolled in university-stream Grade 11 or 12 biology, chemistry, or physics at the participating school over five consecutive terms (cohort summary shown in Table 1 ). Although student participation in educational content was mandatory, student grades and survey responses (administered by high school teachers) were collected from only those students with parent or guardian consent. Teachers replaced each student name with a unique coded identifier to preserve anonymity but enable individual student tracking over multiple terms. All data collected were analyzed without any exclusions save for missing survey responses; no power analysis was performed prior to data collection.

Ethics statement

This study was approved by the University of Toronto Health Sciences Research Ethics Board (Protocol # 34825) and the Toronto District School Board External Research Review Committee (Protocol # 2017-2018-20). Written informed consent was collected from parents or guardians of participating students prior to the acquisition of student data (both post-hoc academic data and survey administration). Data were anonymized by high school teachers for maintenance of academic confidentiality of individual students prior to release to U of T researchers.

Educational program overview

Students enrolled in university-preparatory STEM classes at the participating school completed a term-long project under the guidance of graduate student instructors and undergraduate student mentors as a mandatory component of their respective course. Project curriculum developed collaboratively between graduate students and participating high school teachers was delivered within U of T Faculty of Applied Science & Engineering (FASE) teaching facilities. Participation allows high school students to garner a better understanding as to how undergraduate learning and career workflows in STEM vary from traditional high school classroom learning, meanwhile reinforcing the benefits of problem solving, perseverance, teamwork, and creative thinking competencies. Given that Discovery was a mandatory component of course curriculum, students participated as class cohorts and addressed questions specific to their course subject knowledge base but related to the defined global health research topic (Fig. 1 ). Assessment of program deliverables was collectively assigned to represent 10–15% of the final course grade for each subject at the discretion of the respective STEM teacher.

The Discovery program framework was developed, prior to initiation of student assessment, in collaboration with one high school selected from the local public school board over a 1.5 year period of time. This partner school consistently scores highly (top decile) in the school board’s Learning Opportunities Index (LOI). The LOI ranks each school based on measures of external challenges affecting its student population therefore schools with the greatest level of external challenge receive a higher ranking 35 . A high LOI ranking is inversely correlated with socioeconomic status (SES); therefore, participating students are identified as having a significant number of external challenges that may affect their academic success. The mandatory nature of program participation was established to reach highly capable students who may be reluctant to engage on their own initiative, as a means of enhancing the inclusivity and impact of the program. The selected school partner is located within a reasonable geographical radius of our campus (i.e., ~40 min transit time from school to campus). This is relevant as participating students are required to independently commute to campus for Discovery hands-on experiences.

Each program term of Discovery corresponds with a five-month high school term. Lead university trainee instructors (3–6 each term) engaged with high school teachers 1–2 months in advance of high school student engagement to discern a relevant overarching global healthcare theme. Each theme was selected with consideration of (a) topics that university faculty identify as cutting-edge biomedical research, (b) expertise that Discovery instructors provide, and (c) capacity to showcase the diversity of BME. Each theme was sub-divided into STEM subject-specific research questions aligning with provincial Ministry of Education curriculum concepts for university-preparatory Biology, Chemistry, and Physics 9 that students worked to address, both on-campus and in-class, during a term-long project. The Discovery framework therefore provides students a problem-based learning experience reflective of an engineering capstone design project, including a motivating scientific problem (i.e., global topic), subject-specific research question, and systematic determination of a professional recommendation addressing the needs of the presented problem.

Discovery instructors were volunteers recruited primarily from graduate and undergraduate BME programs in the FASE. Instructors were organized into subject-specific instructional teams based on laboratory skills, teaching experience, and research expertise. The lead instructors of each subject (the identified 1–2 trainees that built curriculum with high school teachers) were responsible to organize the remaining team members as mentors for specific student groups over the course of the program term (~1:8 mentor to student ratio).

All Discovery instructors were familiarized with program expectations and trained in relevant workspace safety, in addition to engagement at a teaching workshop delivered by the Faculty Advisor (a Teaching Stream faculty member) at the onset of term. This workshop was designed to provide practical information on teaching and was co-developed with high school teachers based on their extensive training and experience in fundamental teaching methods. In addition, group mentors received hands-on training and guidance from lead instructors regarding the specific activities outlined for their respective subject programming (an exemplary term of student programming is available in S 2 Appendix) .

Discovery instructors were responsible for introducing relevant STEM skills and mentoring high school students for the duration of their projects, with support and mentorship from the Faculty Mentor. Each instructor worked exclusively throughout the term with the student groups to which they had been assigned, ensuring consistent mentorship across all disciplinary components of the project. In addition to further supporting university trainees in on-campus mentorship, high school teachers were responsible for academic assessment of all student program deliverables (Fig. 1 ; the standardized grade distribution available in S 3 Appendix ). Importantly, trainees never engaged in deliverable assessment; for continuity of overall course assessment, this remained the responsibility of the relevant teacher for each student cohort.

Throughout each term, students engaged within the university facilities four times. The first three sessions included hands-on lab sessions while the fourth visit included a culminating symposium for students to present their scientific findings (Fig. 1 ). On average, there were 4–5 groups of students per subject (3–4 students per group; ~20 students/class). Discovery instructors worked exclusively with 1–2 groups each term in the capacity of mentor to monitor and guide student progress in all project deliverables.

After introducing the selected global research topic in class, teachers led students in completion of background research essays. Students subsequently engaged in a subject-relevant skill-building protocol during their first visit to university teaching laboratory facilities, allowing opportunity to understand analysis techniques and equipment relevant for their assessment projects. At completion of this session, student groups were presented with a subject-specific research question as well as the relevant laboratory inventory available for use during their projects. Armed with this information, student groups continued to work in their classroom setting to develop group-specific experimental plans. Teachers and Discovery instructors provided written and oral feedback, respectively , allowing students an opportunity to revise their plans in class prior to on-campus experimental execution.

Once at the relevant laboratory environment, student groups executed their protocols in an effort to collect experimental data. Data analysis was performed in the classroom and students learned by trial & error to optimize their protocols before returning to the university lab for a second opportunity of data collection. All methods and data were re-analyzed in class in order for students to create a scientific poster for the purpose of study/experience dissemination. During a final visit to campus, all groups presented their findings at a research symposium, allowing students to verbally defend their process, analyses, interpretations, and design recommendations to a diverse audience including peers, STEM teachers, undergraduate and graduate university students, postdoctoral fellows and U of T faculty.

Data collection

Teachers evaluated their students on the following associated deliverables: (i) global theme background research essay; (ii) experimental plan; (iii) progress report; (iv) final poster content and presentation; and (v) attendance. For research purposes, these grades were examined individually and also as a collective Discovery program grade for each student. For students consenting to participation in the research study, all Discovery grades were anonymized by the classroom teacher before being shared with study authors. Each student was assigned a code by the teacher for direct comparison of deliverable outcomes and survey responses. All instances of “Final course grade” represent the prorated course grade without the Discovery component, to prevent confounding of quantitative analyses.

Survey instruments were used to gain insight into student attitudes and perceptions of STEM and post-secondary study, as well as Discovery program experience and impact (S 4 Appendix ). High school teachers administered surveys in the classroom only to students supported by parental permission. Pre-program surveys were completed at minimum 1 week prior to program initiation each term and exit surveys were completed at maximum 2 weeks post- Discovery term completion. Surveys results were validated using a principal component analysis (S 1 Appendix , Supplementary Fig. 2 ).

Identification and comparison of population subsets

From initial analysis, we identified two student subpopulations of particular interest: students who performed ≥1 SD [18.0%] or greater in the collective Discovery components of the course compared to their final course grade (“EE”), and students who participated in Discovery more than once (“MT”). These groups were compared individually against the rest of the respective Discovery population (“non-EE” and “non-MT”, respectively ). Additionally, MT students who participated in three or four (the maximum observed) terms of Discovery were assessed for longitudinal changes to performance in their course and Discovery grades. Comparisons were made for all Discovery deliverables (introductory essay, client meeting, proposal, progress report, poster, and presentation), final Discovery grade, final course grade, Discovery attendance, and overall attendance.

Statistical analysis

Student course grades were analyzed in all instances without the Discovery contribution (calculated from all deliverable component grades and ranging from 10 to 15% of final course grade depending on class and year) to prevent correlation. Aggregate course grades and Discovery grades were first compared by paired t-test, matching each student’s course grade to their Discovery grade for the term. Student performance in Discovery ( N  = 268 instances of student participation, comprising 170 individual students that participated 1–4 times) was initially assessed in a linear regression of Discovery grade vs. final course grade. Trends in course and Discovery performance over time for students participating 3 or 4 terms ( N  = 16 and 3 individuals, respectively ) were also assessed by linear regression. For subpopulation analysis (EE and MT, N  = 99 instances from 81 individuals and 174 instances from 76 individuals, respectively ), each dataset was tested for normality using the D’Agostino and Pearson omnibus normality test. All subgroup comparisons vs. the remaining population were performed by Mann–Whitney U -test. Data are plotted as individual points with mean ± SEM overlaid (grades), or in histogram bins of 1 and 4 days, respectively , for Discovery and class attendance. Significance was set at α ≤ 0.05.

Reporting summary

Further information on research design is available in the Nature Research Reporting Summary linked to this article.

Data availability

The data that support the findings of this study are available upon reasonable request from the corresponding author DMK. These data are not publicly available due to privacy concerns of personal data according to the ethical research agreements supporting this study.

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Acknowledgements

This study has been possible due to the support of many University of Toronto trainee volunteers, including Genevieve Conant, Sherif Ramadan, Daniel Smieja, Rami Saab, Andrew Effat, Serena Mandla, Cindy Bui, Janice Wong, Dawn Bannerman, Allison Clement, Shouka Parvin Nejad, Nicolas Ivanov, Jose Cardenas, Huntley Chang, Romario Regeenes, Dr. Henrik Persson, Ali Mojdeh, Nhien Tran-Nguyen, Ileana Co, and Jonathan Rubianto. We further acknowledge the staff and administration of George Harvey Collegiate Institute and the Institute of Biomedical Engineering (IBME), as well as Benjamin Rocheleau and Madeleine Rocheleau for contributions to data collation. Discovery has grown with continued support of Dean Christopher Yip (Faculty of Applied Science and Engineering, U of T), and the financial support of the IBME and the National Science and Engineering Research Council (NSERC) PromoScience program (PROSC 515876-2017; IBME “Igniting Youth Curiosity in STEM” initiative co-directed by DMK and Dr. Penney Gilbert). LDH and NIC were supported by Vanier Canada graduate scholarships from the Canadian Institutes of Health Research and NSERC, respectively . DMK holds a Dean’s Emerging Innovation in Teaching Professorship in the Faculty of Engineering & Applied Science, U of T.

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These authors contributed equally: Locke Davenport Huyer, Neal I. Callaghan.

Authors and Affiliations

Institute of Biomedical Engineering, University of Toronto, Toronto, ON, Canada

Locke Davenport Huyer, Neal I. Callaghan, Andrey I. Shukalyuk & Dawn M. Kilkenny

Chemical Engineering and Applied Chemistry, University of Toronto, Toronto, ON, Canada

Locke Davenport Huyer

Translational Biology and Engineering Program, Ted Rogers Centre for Heart Research, University of Toronto, Toronto, ON, Canada

Neal I. Callaghan

George Harvey Collegiate Institute, Toronto District School Board, Toronto, ON, Canada

Sara Dicks, Edward Scherer & Margaret Jou

Institute for Studies in Transdisciplinary Engineering Education & Practice, University of Toronto, Toronto, ON, Canada

Dawn M. Kilkenny

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Contributions

LDH, NIC and DMK conceived the program structure, designed the study, and interpreted the data. LDH and NIC ideated programming, coordinated execution, and performed all data analysis. SD, ES, and MJ designed and assessed student deliverables, collected data, and anonymized data for assessment. SD assisted in data interpretation. AIS assisted in programming ideation and design. All authors provided feedback and approved the manuscript that was written by LDH, NIC and DMK.

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Correspondence to Dawn M. Kilkenny .

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Davenport Huyer, L., Callaghan, N.I., Dicks, S. et al. Enhancing senior high school student engagement and academic performance using an inclusive and scalable inquiry-based program. npj Sci. Learn. 5 , 17 (2020). https://doi.org/10.1038/s41539-020-00076-2

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Action Research

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• Introduction
• About the Authors
• What is Action Research for Classroom Teachers?
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About the book.

Action research is a common journey for graduate students in education and other human science fields. This book attempts to meet the needs of graduate students, in-service teachers, and any other educators interested in action research and/or self-study. The chapters of this book draw on our collective experiences as educators in a variety of educational contexts, and our roles guiding educator/researchers in various settings. All of our experiences have enabled us to question and refine our own understanding of action research as a process and means for pedagogical improvement. The primary purpose of this book is to offer clear steps and practical guidance to those who intend to carry out action research for the first time. As educators begin their action research journey, we feel it is vital to pose four questions: 1) What is action research, and how is it distinct from other educational research?; 2) When is it appropriate for an educator to conduct an action research project in their context?; 3) How does an educator conduct an action research project?; 4) What does an educator do with the data once the action research project has been conducted? We have attempted to address all four questions in the chapters of this book.

About the Contributors

J. Spencer Clark is an Associate Professor of Curriculum Studies at Kansas State University. He has used action research methodology for the past 17 years, in K-12 schools and higher education. More recently, for the past 10 years he has taught action research methods to teachers in graduate and licensure degree programs. He also has led secondary student action research projects in Indiana, Utah, and Kansas. Clark also utilizes action research methodology in his own research. Much of his research has focused on understanding and developing teacher agency through clinical and professional learning experiences that utilize aspects of digital communication, inquiry, collaboration, and personalized learning. He has published in a variety of journals and edited books on teacher education, technology, inquiry-based learning, and curriculum development.

Suzanne Porath has been an English Language Arts, history, and humanities classroom teacher and reading teacher for 13 years before becoming a teacher educator. She has taught in Wisconsin and American international schools in Brazil, Lithuania, and Aruba when she conducted her own action research projects. Before accepting her current position as an assistant professor at Kansas State University in Curriculum and Instruction, she taught at Concordia University and Edgewood College in Wisconsin. She has taught action research methods at the graduate level and facilitated professional development through action research in school districts. She is the lead editor of Networks: An Online Journal for Teacher Research  https://newprairiepress.org/networks/ .

Julie Thiele , PhD. is an Assistant Professor at Kansas State University.  She teaches math education courses, math and science education courses and graduate research courses. Prior to teaching at KSU, she taught elementary and middle school, and led her district level professional learning community, focusing on implementing effective, research-based teaching practices.

Morgan M. Jobe is a program coordinator in the College of Education at Kansas State University, where she also earned a bachelor’s degree in secondary education and a master’s degree in curriculum and instruction. Morgan taught high school English-Language Arts for ten years in two different Kansas school districts before returning to Kansas State University as a staff member. Her research interests include diversity and equity issues in public education, as well as action research in teacher education programs.

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Examples of Critical Participatory Action Research

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• Stephen Kemmis 4 ,
• Robin McTaggart 5 &
• Rhonda Nixon 6  

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This chapter presents five examples of critical participatory action research from different kinds of settings. The first, from ‘Braxton’ High School in Canada, describes a project in which senior students initiated waste recycling. This example has been referred to extensively in preceding chapters. The second example is from a Canadian elementary school (‘Grace’ Elementary) and describes a project in which teachers and students introduced periods of self-directed learning in the school week. The third example, from ‘Joseph’ Junior High in Canada, describes a project introducing highly visual texts—including graphic novels—in the school. The fourth example, ‘Teacher Talk,’ is from an Australian University, and discusses how a group of university academics explore the conditions under which they work. The fifth is from an Indigenous community in Australia: it describes how the Yirrkala community followed the principles of critical participatory action research to change a local school.

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A former member of the group now at the University of Queensland.

The findings of the research Stephen is referring to—the analyses of transcripts of interviews and classroom lessons—can be found in Kemmis, Wilkinson, Edwards-Groves, Hardy, Grootenboer and Bristol (2014).

Name used by the Indigenous people of North Eastern Arnhem Land to describe themselves as a people.

This man has been our colleague and friend for many years, but since his recent death, out of respect and at the specific request of his relatives, we do not use his first name. This is an established practice regarding the names and images of deceased Indigenous persons in Australia. We use the formal title ‘Doctor’ also out of respect: in 1998, our friend was awarded an honorary doctorate by Queensland University of Technology in Brisbane “in recognition of his significant contribution to the education of Aboriginal children, and to greater understanding between Aboriginal and non-Aboriginal Australians.” He was named 1992 Australian of the Year for his role in “building bridges of understanding between Aboriginal and non-Aboriginal people.”

The community movement that led to the formation of the Ganma education project produced other significant developments for the Yolngu people of North East Arnhem Land. The related word ‘Garma’ became internationally prominent as the name of the Garma Festival, the festival of Traditional Culture held each year at Gulkula in North East Arnhem Land. Dr Yunupingu’s Yothu Yindi Foundation initiated the Garma Festival.

Carr, W. (2006). Philosophy, methodology and action research. Journal of Philosophy of Education , 40 , 421–435.

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Dunlop, I. (1981). Narritjin at Djarrakpi—parts one & two: my country, Djarrakpi . Canberra: National Film and Sound Archive, Yirrkala Film Project DVD Collection.

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Hardy, I. (2010a). Academic architectures: Academic perceptions of teaching conditions in an Australian university. Studies in Higher Education , 35 (4), 391–404.

Hardy, I. (2010b). Teacher talk: Flexible delivery and academics’ praxis in an Australian university. International Journal for Academic Development , 15 (2), 131–142.

Kemmis, S. (2012). Researching educational praxis: Spectator and participant perspectives. British Educational Research Journal , 38 (6), 885–905.

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Morphy, H. (1984). Journey to the crocodile’s nest . Canberra: Australian Institute of Aboriginal Studies.

Ngurruwutthun, D. (1991). The Garma project. In R. Bunbury, W. Hastings, J. Henry, & R. McTaggart (Eds.), Towards Aboriginal pedagogy: Aboriginal teachers speak out. Blekbala Wei, Deme Nayin, Yolngu Rom, and Ngini Nginingawula Ngawurranungurumagi (pp. 107–122). Geelong: Deakin University Press.

Watson, H., & Chambers, W. (1989) Singing the land, signing the land . Geelong: Deakin University Press.

Yunupingu, M. (1991). Ganma education. In R. Bunbury, W. Hastings, J. Henry, & R. McTaggart (Eds.), Towards Aboriginal pedagogy: Aboriginal teachers speak out, Blekbala Wei, Deme Nayin, Yolngu Rom, and Ngini Nginingawula Ngawurranungurumag i (pp. 98–106). Geelong: Deakin University Press.

Yunupingu, Y. (2013). ‘Today we celebrate a true Yolngu Maralitja Gumatj man, Dr Djarrtjuntjun Yunupingu’, posted by Bob Gosford, Crikey . Available at: http://blogs.crikey.com.au/northern/2013/07/02/yalmay-yunupingu-today-we-celebrate-a-true-yolngu-maralitja-gumatj-man-dr-djarrtjuntjun-yunupingu/?wpmp_switcher = mobile & wpmp_tp = 0 .

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Kemmis, S., McTaggart, R., Nixon, R. (2014). Examples of Critical Participatory Action Research. In: The Action Research Planner. Springer, Singapore. https://doi.org/10.1007/978-981-4560-67-2_6

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Extracurriculars.

A Guide to Pursuing Research Projects in High School

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Most common high school pursuits and interests can be fit fairly neatly into the academic or extracurricular categories. There are of course required courses that you take, and then there are the activities that you pursue outside of school hours, usually for your own enjoyment. You may play on a sports team, participate in a service project, or pursue visual arts. In most cases, even if your interests are somewhat untraditional, you can somehow package them in a way that neatly qualifies them as an extracurricular activity.

But what if your interests outside of school are more academic in nature? What if you’ve long been fascinated by the potential that carbon sequestration holds to limit the effects of climate change? What if you’re interested in the history of civil disobedience, or the ability of exams to measure actual comprehension? Whatever the case may be, there are some topics of interest that just don’t fit neatly into any extracurricular club or activity.

If you find yourself longing to pursue an interest such as this, you might consider conducting your own research project. While the concept may seem daunting at first, if you break it down into smaller, manageable tasks, you’ll quickly find that you probably already have the skills necessary to get started.

In this post, we will outline the process for conducting a long-term research project independently, including several avenues for pursuing recognition of your work and a step-by-step guide to completing your project. If you’re interested in pursuing an independent research project during high school, keep reading.

Why Pursue an Independent Research Project?

An independent research project is a great way to explore an area of interest that you otherwise would not get to learn about outside of school. By undertaking a research project on your own, not only will you explore a personal area of interest in more depth, but also you will demonstrate your dedication to pursuing knowledge for the sake of learning and your ability to work independently over a prolonged period.

Independent research projects, when conducted well and presented appropriately on a college application, can be a great advantage to you on your college admissions.

How to Choose a Topic for a Research Project

If you’re interested in pursuing a research project, you probably already have a topic in mind. In fact, the desire to conduct a research project usually stems from an existing interest, not just from the idea to conduct research on a vague or undetermined subject matter.

You should aim to narrow your research project to something that has some academic relevance. Perhaps it is related to your existing coursework. Maybe it reflects work you hope to pursue in the future, either academically or professionally. Try to fine-tune your project enough that you can easily explain the driving force behind it and its relevance to your future career path.

While you don’t need to decide on your exact topic or thesis quite yet, you should have a general idea of what your project will entail before moving forward.

Are There Existing Avenues for Undertaking a Research Project At Your School?

While you could certainly conduct your research project completely independently from your school, it is usually easier and more productive to conduct it in a way that is somehow connected to the rest of your schooling.

If the project is STEM-oriented, think about whether it would fit into a science fair or other STEM competition in which your school already competes. Also consider the AP Capstone Program if your school offers it. The second course in this sequence is AP Research , and it requires an in-depth research project as its culminating assessment.

If neither of these formal avenues are available, or neither provides a good fit, look into the possibility of pursuing your project as an independent study. If your school offers independent studies for credit, you can usually get information about them from your adviser. These types of projects usually require an extended application process that must be followed closely if you want to gain approval.

Finally, even if you can’t take advantage of one of the options above, if you have achieved advanced standing or enough credits, your school might still allow you to undertake an extended individual research project through some type of formal arrangement. Talk with a teacher, mentor, or adviser to learn what your options are. Clearly communicate your innate desire to learn more about this specific topic and be prepared to give some background on the issue that you want to research.

Steps for Undertaking the Research Project

1. find a mentor or adviser.

You will need someone to help guide and advise your work, so finding a willing and able mentor should be one of your first steps. This should ideally be a person with existing expertise in the subject area you wish to pursue. In the least, this person should share your interest and passion for the topic.

A teacher at your school who can also serve as an adviser is ideal, and may even be a requirement if you are formally pursuing the project as an independent study for credit. If that is not possible, you can certainly find a mentor somewhere else, even remotely if necessary.

Find out if your subject matter pertains to any local industries or companies, or if there are any scientists or professionals nearby who specialize in it. Consider checking the instructors of local summer programs or judges from past science fairs at your school.   Also consider a professional who has written an article that interested you in the field.

Before you approach a mentor to request their help, familiarize yourself with his or her work. Be able to speak articulately about what has drawn you to him or her specifically. Put some thought into informed questions you might ask him or her. Be upfront about your needs if you are going to require any specific guidance or extended time or energy from your mentor. It might be difficult to find someone at first, but keep trying. Finding a mentor for your project is an important step.

2. Set a Timeline and Stick to It

Once you’ve found a mentor, you can get started laying out the timeline for your project. When you do this, list each step of your project as specifically as possible. These will include at a minimum: background research, writing a thesis statement, in depth research phase, outlining your final paper, drafting your paper, editing your paper, and publishing your paper.

You will probably have a completion date in mind, whether it’s required by the school or simply the end of the semester or school year. Work backwards from your completion date to set a realistic timeframe for each of these steps.

It helps to have a calendar displayed prominently with your deadlines listed clearly on it to keep you on track. Also be sure to put your deadlines into your school assignment book or Google calendar so that you can see how they overlap and affect your other commitments.

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3. Conducting Research

After you’ve completed your deadline calendar, you’re ready to get started with the fun stuff:   the actual research. There are many sources for finding high quality research materials. You can use your school library, your local library, and sometimes even the library at local colleges or universities. Sometimes the libraries at colleges are open only to registered students and faculty, but if you contact a library official or a member of the department related to your research project, you might be able to gain access for research purposes.

You may also take advantage of online research tools. Google Scholar is a good place to find peer-reviewed, high quality publications. You may also find out if your school has a subscription to any online research databases like Ebsco , or JSTOR . These databases provide digital compilations of hundreds of research journals, both current and archived.    

Be careful what you choose to use as sources, though. You need to ensure that every source you rely on is high-quality and fact-based. Many internet resources now are not as accurate as they might appear. Some are outdated and some are just wrong. Remember that just about anyone can publish something online these days, so you can’t rely on information that you find on just any old website. Be particularly wary of pages like Wikipedia that look like fact-based resources but are actually drawn from unfiltered user submissions.

As you research your topic, take careful notes to track your work. Choose a system to organize your notes, such as writing on notecards that can be easily organized, or using different colored pens to color code different subtopics of your research. By carefully organizing your notes, you’ll be better set up to organize your paper.

4. Organize Your Paper

Once you’ve completed the research phase of your project, you’re ready to organize your paper. Go through your notes carefully to see how they support your thesis. If they don’t, be prepared and open to changing your thesis. Always allow the research to guide the direction of your paper, and not vice versa.

Organize your notes into the order that makes most sense in your paper. Use them to guide an outline of your paper. Once they are in order, write out a rough outline of your paper.

Prewriting is an important step to writing your paper. It allows you to go into the drafting phase with as much preparation as possible so that your writing will have a clear direction when you begin.

5. Write Your Paper 

After your organization and prewriting, you’re ready to draft your paper. Try to break this phase up into smaller pieces so that you don’t burn out. Your final product will probably be one of the longest papers you’ve ever written, usually ranging from 15-30 pages depending on your subject, so you’ll want to pace yourself.

Break up your writing deadlines into more specific sub-deadlines to help guide your work. Set goals for completing the introduction, various sections of the body, and your conclusion.

6. Edit Your Paper 

There will be multiple stages of editing that need to happen. First, you will self-edit your first draft. Then, you will likely turn a draft of your paper in to your mentor for another round of editing. Some students even choose to have a peer or family member edit a draft at some point. After several rounds of editing, you will be prepared to publish your work.

7. Publish Your Work

Publication sounds like a very official completion of your project, but in reality publishing can take many different forms. It’s really just the final draft of your project, however you decide to produce it.

For some students, publication means submitting a draft of your project to an actual journal or formal publication. For others, it means creating a polished draft and a display board that you will present at a school or public event. For still others it might just be a polished, final draft bound and turned into your mentor.

However you decide to publish your work, be mindful that this should be a reflection of an entire semester or year of work, and it should reflect the very height of your learning and abilities. You should be proud of your final product.

If you’re a high school student with in-depth interests in a subject area that doesn’t fit neatly into any of your existing extracurriculars or academic courses, you should consider pursuing a research project to reflect your interest and dedication. Not only will your pursuit allow you to further explore a subject that’s interesting to you, but also it will be a clear example of your independence and commitment on your college applications.

Looking for help navigating the road to college as a high school student? Download our  free guide for 9th graders  and our  free guide for 10th graders . Our guides go in-depth about subjects ranging from  academics ,  choosing courses ,  standardized tests ,  extracurricular activities ,  and much more !

For more information about research and independent projects in high school, check out these posts:

• Ultimate Guide to the AP Research Course and Assessment
• How to Choose a Project for Your AP Research Course
• How to Get a Research Assistant Position in High School
• An Introduction to the AP Capstone Diploma
• How to Choose a Winning Science Fair Project Idea
• How to Plan and Implement an Independent Study in High School

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100 Research Topics for High School Students

By Eric Eng

High school is such an exciting time for stretching your intellectual muscles. One awesome way to do that is through research projects. But picking the right topic can make all the difference. It should be something you’re passionate about and also practical to tackle. So, we’ve put together a list of engaging research topics for high school students across ten different subjects: physics, math, chemistry, biology, engineering, literature, psychology, political science, economics, and history. Each topic is crafted to spark your curiosity and help you grow those research skills.

Physics Research Topics

Research topics for high school students in physics are an exciting way to enhance your understanding of the universe.

1. Gravitational Waves and Space-Time

How do gravitational waves distort space-time, and what can these distortions tell us about the origins of the universe?

2. Quantum Entanglement Applications

What are the potential technological applications of quantum entanglement, and how can it be harnessed for secure communication?

3. Dark Matter and Galaxy Formation

How does dark matter affect the formation and behavior of galaxies, and what evidence supports its existence?

4. Physics of Renewable Energy

What are the fundamental physical principles behind renewable energy sources, and how do they compare in terms of efficiency?

5. Superconductors in Technology

How are superconductors utilized in modern technology, and what advantages do they offer over traditional materials?

6. Particle Physics at the Large Hadron Collider

What significant discoveries have been made at the Large Hadron Collider, and how do they advance our understanding of particle physics?

7. Microgravity Effects on Organisms

How does microgravity affect the physiological and biological functions of organisms during space travel?

8. Thermodynamics and Engine Efficiency

How do the principles of thermodynamics improve the efficiency and performance of internal combustion engines?

9. Electromagnetism in Wireless Communication

How do principles of electromagnetism enable the functioning of wireless communication systems?

10. Cosmic Radiation and Human Space Travel

What are the effects of cosmic radiation on astronauts, and what measures can be taken to protect them during long-term space missions?

These research topics for high school students are designed to deepen your knowledge and prepare you for advanced studies and innovations in the field of physics.

Math Research Topics

Math research topics for high school students are a fantastic way to explore real-world problems through the lens of mathematical principles .

11. Graph Theory and Social Networks

How can graph theory be applied to identify influential nodes and optimize information flow in social networks?

12. Cryptography and Data Security

What cryptographic techniques are most effective in securing online communications and protecting sensitive data?

13. Mathematical Models in Disease Spread

How do SIR models predict the spread of infectious diseases, and what factors affect their accuracy?

14. Game Theory and Economic Decisions

How does game theory explain the strategic behavior of firms in competitive markets?

15. Calculus in Engineering Design

How is calculus used to optimize the structural integrity and efficiency of engineering designs?

16. Linear Algebra in Computer Graphics

How do matrices and vectors facilitate the creation and manipulation of digital images in computer graphics?

17. Statistical Methods in Public Health

What statistical methods are most effective in analyzing public health data to track disease outbreaks?

18. Differential Equations and Population Dynamics

How do differential equations model the population dynamics of endangered species in varying environments?

19. Probability Theory in Risk Management

How is probability theory applied to assess and mitigate financial risks in investment portfolios?

20. Mathematical Modeling in Climate Change Predictions

How do mathematical models simulate climate change scenarios, and what variables are most critical to their predictions?

These research topics for high school students are designed to spark your curiosity and help you build critical thinking skills and practical knowledge.

Chemistry Research Topics

Chemistry research topics for high school students open up a world of molecular wonders and practical applications.

21. Photosynthesis Chemical Processes

How do the chemical reactions involved in photosynthesis convert light energy into chemical energy in plants?

22. Catalysts and Reaction Rates

How do different catalysts influence the rate of chemical reactions, and what factors affect their efficiency?

23. Environmental Pollutants and Atmospheric Chemistry

How do specific environmental pollutants alter chemical reactions in the atmosphere, and what are the consequences for air quality?

24. Green Chemistry Principles

How can green chemistry practices be applied to reduce chemical waste and promote sustainable industrial processes?

25. Nanotechnology in Drug Delivery

How does nanotechnology improve the targeted delivery and effectiveness of drugs within the human body?

26. Plastic Composition and Environmental Impact

How does the chemical composition of various plastics affect their environmental impact and degradation process?

27. Enzymes in Biochemical Reactions

How do enzymes catalyze biochemical reactions, and what factors influence their activity and specificity?

28. Electrochemistry in Battery Technology

How are electrochemical principles applied to improve the performance and sustainability of modern batteries?

29. Chemical Fertilizers and Soil Health

How do chemical fertilizers impact soil health and agricultural productivity, and what alternatives exist to minimize negative effects?

30. Spectroscopy in Compound Identification

How is spectroscopy used to identify and analyze the composition of chemical compounds in various fields?

These research topics for high school students are designed to enhance your understanding of chemical principles and their real-world applications.

Biology Research Topics

Research topics for high school students in biology open up a fascinating window into the complexities of the living world.

31. Genetic Basis of Inherited Diseases

How do specific genetic mutations cause inherited diseases, and what are the mechanisms behind their transmission?

32. Climate Change and Biodiversity

How does climate change affect biodiversity in different ecosystems, and what species are most at risk?

33. Microbiomes and Human Health

How do microbiomes influence human health, and what roles do they play in disease prevention and treatment?

34. Habitat Destruction and Wildlife

How does habitat destruction impact wildlife populations and their behaviors, and what are the long-term ecological consequences?

35. Genetic Engineering in Agriculture

How can genetic engineering techniques improve crop yields and resistance to pests and diseases?

36. Pollution and Aquatic Ecosystems

How do various pollutants affect aquatic ecosystems, and what are the implications for water quality and marine life?

37. Stem Cells in Regenerative Medicine

How are stem cells used in regenerative medicine to repair and replace damaged tissues and organs?

38. Evolutionary Biology and Species Adaptation

How do evolutionary principles explain the adaptation of species to changing environmental conditions?

39. Diet and Human Health

How do different dietary choices impact human health, and what are the underlying mechanisms?

40. Bioinformatics in Genetic Research

How is bioinformatics used to analyze genetic data, and what insights can it provide into genetic disorders and evolution?

These research topics for high school students are designed to deepen your understanding of life sciences and prepare you for advanced studies and research in the field.

Engineering Research Topics

Engineering research topics give high school students practical insights into designing and creating innovative solutions.

41. 3D Printing in Manufacturing

How does 3D printing technology revolutionize manufacturing processes, and what are its key advantages over traditional methods?

42. Robotics in Modern Industry

How do robotics improve efficiency and productivity in modern industries, and what are some specific applications?

43. Sustainable Building Design

What principles of sustainable building design can be applied to reduce environmental impact and enhance energy efficiency?

44. Artificial Intelligence in Engineering

How is artificial intelligence integrated into engineering solutions to optimize processes and solve complex problems?

45. Renewable Energy Technologies

How do renewable energy technologies, such as solar and wind power, contribute to reducing carbon footprints?

46. Aerodynamics in Vehicle Design

How do aerodynamic principles enhance the performance and fuel efficiency of vehicles?

47. Material Science in Engineering Innovations

How do advancements in material science lead to innovative engineering solutions and improved product performance?

48. Civil Engineering in Urban Development

How does civil engineering contribute to urban development and infrastructure planning in growing cities?

49. Electrical Engineering in Modern Electronics

How are electrical engineering principles applied in the design and development of modern electronic devices?

50. Biomedical Engineering and Medical Devices

How does biomedical engineering contribute to the development of innovative medical devices and healthcare solutions?

These research topics for high school students are designed to broaden your understanding of engineering principles and their real-world applications, preparing you for future innovations and problem-solving in the field.

Literature Research Topics

Literature research topics give high school students the chance to delve into the rich and varied world of written works and their broader implications.

51. Identity in Contemporary Young Adult Fiction

How do contemporary young adult fiction novels explore themes of identity and self-discovery among teenagers?

52. Historical Events and Literary Movements

How have significant historical events influenced and shaped various literary movements, such as Romanticism or Modernism?

53. Symbolism in Classic Literature

How do authors use symbolism in classic literature to convey deeper meanings and themes?

54. Narrative Structure in Modern Storytelling

How do modern authors utilize narrative structures to enhance the storytelling experience and engage readers?

55. Literary Devices in Poetry

How do poets employ literary devices like metaphor, simile, and alliteration to enrich the meaning and emotional impact of their work?

56. Dystopian Themes in Science Fiction

How do science fiction authors use dystopian themes to comment on contemporary social and political issues?

57. Cultural Diversity and Literary Expression

How does cultural diversity influence literary expression and contribute to the richness of global literature?

58. Feminist Theory in Literary Analysis

How is feminist theory applied to analyze and interpret the representation of women and gender roles in literature?

59. Postcolonial Literature Principles

How does postcolonial literature address themes of colonization, identity, and resistance, and what are its key characteristics?

60. Intertextuality in Modern Novels

How do modern novelists use intertextuality to create layers of meaning and connect their works with other literary texts?

These research topics for high school students are designed to deepen your understanding of literary techniques and themes. They prepare you for advanced literary analysis and appreciation.

Psychology Research Topics

Psychology research topics offer high school students a fascinating journey into the complexities of human behavior and mental processes.

61. Social Media and Adolescent Mental Health

How does social media usage affect the mental health and well-being of adolescents, particularly in terms of anxiety and depression?

62. Stress and Cognitive Function

How does chronic stress impact cognitive functions such as memory, attention, and decision-making?

63. Cognitive-Behavioral Therapy and Anxiety Disorders

How effective is cognitive-behavioral therapy (CBT) in treating various anxiety disorders, and what mechanisms underlie its success?

64. Early Childhood Experiences and Personality Development

How do early childhood experiences shape personality traits and influence long-term behavioral patterns?

65. Sleep and Memory Retention

How does the quality and quantity of sleep affect the retention and recall of memories?

66. Neuroplasticity in Brain Recovery

How does neuroplasticity facilitate brain recovery and adaptation following injury or neurological illness?

67. Mindfulness Practices and Emotional Regulation

How do mindfulness practices help individuals regulate their emotions and reduce symptoms of stress and anxiety?

68. Genetic Factors in Mental Health Disorders

How do genetic predispositions contribute to the development of mental health disorders, such as schizophrenia and bipolar disorder?

69. Group Dynamics and Decision-Making

How do group dynamics influence individual decision-making processes and outcomes in collaborative settings?

70. Psychological Assessments in Educational Settings

How are psychological assessments used to support student learning and development in educational environments?

These research topics for high school students are designed to enhance your understanding of mental processes and behavior. They prepare you for advanced studies and practical applications in the field.

Political Science Research Topics

Political science research topics offer high school students an exciting opportunity to dive into the complexities of political systems and their impact on society.

71. Social Media and Political Campaigns

How does social media influence the strategies and outcomes of political campaigns, particularly in terms of voter engagement and misinformation?

72. International Organizations and Global Governance

How do international organizations, such as the United Nations, contribute to global governance and conflict resolution?

73. Political Corruption and Economic Development

How does political corruption affect economic development and stability in different countries?

74. Democracy in Political Systems

How do the principles of democracy vary across different political systems, and what impact do these differences have on governance?

75. Public Opinion and Policy-Making

How does public opinion shape government policy-making processes and legislative decisions?

76. Political Ideology and Government Policies

How do different political ideologies influence the formulation and implementation of government policies?

77. Electoral Systems and Political Representation

How do various electoral systems impact political representation and voter behavior?

78. Political Communication in Media

How do media and communication strategies shape public perception of political issues and candidates?

79. Globalization and National Sovereignty

How does globalization affect national sovereignty and the ability of states to maintain independent policies?

80. Political Theory and Social Movements

How can political theory be used to understand the origins, development, and impact of social movements?

These research topics for high school students are designed to enhance your understanding of political processes and theories. They prepare you for advanced studies and informed civic participation.

Economics Research Topics

Economics research topics give high school students valuable insights into how economic systems and policies shape our world.

81. Minimum Wage Laws and Employment Rates

How do changes in minimum wage laws impact employment rates across different sectors and demographics?

82. Fiscal Policy in Economic Recessions

How do government fiscal policies, such as stimulus packages, help manage and mitigate the effects of economic recessions?

83. Globalization and Local Economies

How does globalization influence local economies, particularly in terms of job creation and market competition?

84. Behavioral Economics and Consumer Decisions

How do psychological factors and cognitive biases affect consumer decision-making and market trends?

85. Trade Policies and International Relations

How do specific trade policies impact international relations and global trade dynamics?

86. Technology in Economic Growth

How do technological advancements drive economic growth and productivity in various industries?

87. Taxation and Income Distribution

How do different taxation policies affect income distribution and economic inequality within a society?

88. Economic Modeling and Market Predictions

How are economic models used to predict market trends, and what are the limitations of these models?

89. Inflation and Purchasing Power

How does inflation impact purchasing power and the cost of living for consumers?

90. Econometrics in Economic Data Analysis

How is econometrics used to analyze and interpret complex economic data, and what insights can it provide?

These research topics for high school students are designed to deepen your understanding of economic principles and their real-world applications, preparing you for further studies and informed decision-making in the field.

History Research Topics

History research topics for high school students offer a deep dive into the past. They help you understand how it shapes our present and future.

91. Industrial Revolution: Causes and Consequences

What were the key factors that led to the Industrial Revolution, and how did it impact society and the economy?

92. Colonialism and Indigenous Populations

How did colonial rule affect the cultural, social, and economic lives of indigenous populations?

93. Women in Historical Social Movements

What roles did women play in various social movements throughout history, and what were their contributions?

94. Historical Revisionism in Modern Historiography

What are the principles and controversies surrounding historical revisionism in contemporary historiography?

95. Technological Advancements and Historical Events

How have technological innovations influenced significant historical events and driven societal changes?

96. Major Wars: Causes and Effects

What were the primary causes, key events, and consequences of major wars in history?

97. Religion in Shaping Historical Narratives

How has religion influenced the crafting and interpretation of historical narratives across different cultures?

98. Historiography and Documenting Events

What methods and principles are used in historiography to accurately record and analyze historical events?

99. Economic Changes and Historical Societies

How have economic shifts impacted social structures and historical developments in various societies?

100. Primary Sources in Historical Research

Why are primary sources important in historical research, and how are they used to ensure accuracy and depth in historical analysis?

These research topics for high school students are designed to deepen your understanding of past events and their significance, preparing you for advanced studies and critical historical inquiry.

How do I pick the right high school research topic?

Choosing the right research topic involves considering your interests, the availability of resources, and the relevance of the topic to current issues. Start by identifying subjects you are passionate about. Then, look for specific questions within those subjects that spark your curiosity. It’s also important to consider the feasibility of the research, including access to necessary materials and data.

What high school research topics are in demand today?

High-demand research topics for high school students today often align with current global challenges and advancements. In science and technology, areas such as renewable energy, artificial intelligence , and genetic engineering are popular. In social sciences, topics like the impact of social media, political polarization, and mental health are highly relevant. Keeping up with current events and scientific journals can help you identify trending topics.

What resources should I use for my high school research?

Effective research requires a mix of resources. Start with your school library and online databases like JSTOR or Google Scholar for academic papers. Utilize books, reputable websites, and expert interviews to gather diverse perspectives. Don’t overlook primary sources, such as historical documents or scientific data, which provide firsthand information. Additionally, consider using software tools for data analysis and project management.

How can I publish or present my high school research?

Publishing and presenting your research can enhance its impact and your academic profile. Consider submitting your work to high school research journals , science fairs , and local or national competitions. You can also present at school or community events, or create a blog or website to share your findings. Networking with teachers and professors can provide guidance and additional opportunities for publication and presentation.

How does high school research enhance my college applications?

High school research demonstrates your ability to undertake independent projects, critical thinking, and problem-solving skills. Colleges value these attributes as they indicate readiness for college-level work. Including research experience in your application can set you apart from other applicants. It shows your commitment to learning and your ability to contribute to academic and extracurricular activities at the college level.

Want to assess your chances of admission? Take our FREE chances calculator today!

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Home > CSMCE > Math in the Middle > MATHMIDACTIONRESEARCH

Math in the Middle Institute Partnership

Action research projects.

Using Cooperative Learning In A Sixth Grade Math Classroom , Teena Andersen

Algebra in the Fifth Grade Mathematics Program , Kathy Bohac

Real Life Problem Solving in Eighth Grade Mathematics , Michael Bomar

Holding Students Accountable , Jeremy Fries

Writing In Math Class? Written Communication in the Mathematics Classroom , Stephanie Fuehrer

The Role of Manipulatives in the Eighth Grade Mathematics Classroom , Michaela Ann Goracke

Reasonable or Not? A Study of the Use of Teacher Questioning to Promote Reasonable Mathematical Answers from Sixth Grade Students , Marlene Grayer

Improving Achievement and Attitude Through Cooperative Learning in Math Class , Scott Johnsen

Oral Communication and Presentations in Mathematics , Brian Johnson

Meaningful Independent Practice in Mathematics , Michelle Looky

Making Better Problem Solvers through Oral and Written Communication , Sheila McCartney

Student Understanding and Achievement When Focusing on Peer-led Reviews , Ryon Nilson

Students Writing Original Word Problems , Marcia Ostmeyer

Cooperative Grouping Working on Mathematics Homework , Maggie Pickering

Making Sense of Word Problems , Edie Ronhovde

Oral and Written Communication in Classroom Mathematics , Lindsey Sample

Written Communication in a Sixth-Grade Mathematics Classroom , Mary Schneider

The Use of Vocabulary in an Eighth Grade Mathematics Classroom: Improving Usage of Mathematics Vocabulary in Oral and Written Communication , Amy Solomon

Enhancing Problem Solving Through Math Clubs , Jessica Haley Thompson

Communication: A Vital Skill of Mathematics , Lexi Wichelt

Mathematical Communication through Written and Oral Expression , Brandee Wilson

Oral Presentation: Exploring Oral Presentations of Homework Problems as a Means of Assessing Homework

Building Confidence in Low Achievers through Building Mathematics Vocabulary , Val Adams

An Uphill Battle: Incorporating cooperative learning using a largely individualized curriculum , Anna Anderson

Using Descriptive Feedback In a Sixth Grade Mathematics Classroom , Vicki J. Barry

Does Decoding Increase Word Problem Solving Skills? , JaLena J. Clement

Using Non-Traditional Activities to Enhance Mathematical Connections , Sandy Dean

Producing More Problem Solving by Emphasizing Vocabulary , Jill Edgren

Reading as a Learning Strategy for Mathematics , Monte Else

Perceptions of Math Homework: Exploring the Connections between Written Explanations and Oral Presentations and the Influence on Students’ Understanding of Math Homework , Kyla Hall

Homework Presentations: Are They Worth the Time? , Kacy Heiser

Reduce Late Assignments through Classroom Presentations , Cole Hilker

Mathematical Communication, Conceptual Understanding, and Students' Attitudes Toward Mathematics , Kimberly Hirschfeld-Cotton

Enhancing Thinking Skills: Will Daily Problem Solving Activities Help? , Julie Hoaglund

Can homework become more meaningful with the inclusion of oral presentations? , Emy Jones

Confidence in Communication: Can My Whole Class Achieve This? , Emily Lashley

Exploring the Influence of Vocabulary Instruction on Students’ Understanding of Mathematical Concepts , Micki McConnell

Using Relearning Groups to Help All Students Understand Learning Objectives Before Tests , Katie Pease

Cooperative Learning in Relation to Problem Solving in the Mathematics Classroom , Shelley Poore

How Student Self-Assessment Influences Mastery Of Objectives , Jeremy John Renfro

RAP (Reasoning and Proof) Journals: I Am Here , Bryce Schwanke

Homework: Is There More To It Than Answers? , Shelly Sehnert

Written Solutions of Mathematical Word Problems , Marcia J. Smith

Rubric Assessment of Mathematical Processes in Homework , Aubrey Weitzenkamp

Calculators in a Middle School Mathematics Classroom: Helpful or Harmful? , Leah Wilcox

Pre-Reading Mathematics Empowers Students , Stacey Aldag

The Importance of Teaching Students How to Read to Comprehend Mathematical Language , Tricia Buchanan

Cooperative Learning as an Effective Way to Interact , Gary Eisenhauer

Generating Interest in Mathematics Using Discussion in the Middle School Classroom , Jessica Fricke

“Let’s Review.” A Look at the Effects of Re-teaching Basic Mathematic Skills , Thomas J. Harrington

The Importance of Vocabulary Instruction in Everyday Mathematics , Chad Larson

Understanding the Mathematical Language , Carmen Melliger

Writing for Understanding in Math Class , Linda Moore

Improving Student Engagement and Verbal Behavior Through Cooperative Learning , Daniel Schaben

Improving Students’ Story Problem Solving Abilities , Josh Severin

Calculators in the Classroom: Help or Hindrance? , Christina L. Sheets

Do Students Progress if They Self-Assess? A Study in Small-Group Work , Cindy Steinkruger

Why Are We Writing? This is Math Class! , Shana Streeks

Effects of Self-Assessment on Math Homework , Diane Swartzlander

The Effects Improving Student Discourse Has on Learning Mathematics , Lindsey Thompson

Increasing Teacher Involvement with Other Teachers Through Reflective Interaction , Tina Thompson

Increasing Conceptual Learning through Student Participation , Janet Timoney

Improving the Effectiveness of Independent Practice with Corrective Feedback , Greg Vanderbeek

Using Math Vocabulary Building to Increase Problem Solving Abilities in a 5th Grade Classroom , Julane Amen

Departmentalization in the 5th Grade Classroom: Re-thinking the Elementary School Model , Delise Andrews

Cooperative Learning Groups in the Eighth Grade Math Classroom , Dean J. Davis

Daily Problem-Solving Warm-Ups: Harboring Mathematical Thinking In The Middle School Classroom , Diana French

Student Transition to College , Doug Glasshoff

The Effects of Teaching Problem Solving Strategies to Low Achieving Students , Kristin Johnson and Anne Schmidt

The Effects of Self-Assessment on Student Learning , Darla Rae Kelberlau-Berks

Writing in a Mathematics Classroom: A Form of Communication and Reflection , Stacie Lefler

Math in the George Middle School , Tiffany D. Lothrop

Bad Medicine: Homework or Headache? Responsibility and Accountability for Middle Level Mathematics Students , Shawn Mousel

Self-Directed Learning in the Middle School Classroom , Jim Pfeiffer

How to Better Prepare for Assessment and Create a More Technologically Advanced Classroom , Kyle Lannin Poore

Cooperative Learning Groups in the Middle School Mathematics Classroom , Sandra S. Snyder

Motivating Middle School Mathematics Students , Vicki Sorensen

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100 Last-Day-of-School Activities Your Students Will Love!

65+ Real-World Project-Based Learning Ideas for All Ages and Interests

Find and implement solutions to real-world problems.

Project-based learning is a hot topic in many schools these days, as educators work to make learning more meaningful for students. As students conduct hands-on projects addressing real-world issues, they dig deeper and make personal connections to the knowledge and skills they’re gaining. But not just any project fits into this concept. Learn more about strong project-based learning ideas, and find examples for any age or passion.

What is project-based learning?

Project-based learning (PBL) uses real-world projects and student-directed activities to build knowledge and skills. Kids choose a real-world topic that’s meaningful to them (some people call these “passion projects”), so they’re engaged in the process from the beginning. These projects are long-term, taking weeks, months, or even a full semester or school year. Students may complete them independently or working in small groups. Learn much more about project-based learning here.

What makes a good PBL project?

In many ways, PBL is more like the work adults do in their daily jobs, especially because student efforts have potential real-world effects. A strong PBL project:

• Addresses a real-world issue or problem
• Requires sustained and independent inquiry, in and out of the classroom
• Allows students voice and choice throughout the project
• Combines elements of many disciplines
• Includes collaboration with public partners, such as universities, community organizations, or businesses
• Produces a public product that is seen by those outside the school community
• Covers a complete process, including activities like research, design, production, marketing or public awareness, and enlisting supporters or investors

Outdoor Project-Based Learning Ideas

• Create a new local park, or improve an existing one by adding new features or providing needed maintenance.
• Plant a community garden to provide food for a soup kitchen, food pantry, or other organization.
• Design and create a butterfly, pollinator, or other wildlife garden to support the local ecosystem.
• Build a new walking or biking trail that’s safe for people of all ages to use.
• Devise and implement a way to reduce litter in your community.
• Set up and manage a school or community compost pile, and distribute the resulting soil to those who need it most.
• Find and help the public use a new way to grow food that requires less soil, water, or fertilizers, which are in short supply in some parts of the world.
• Design, build, and install a completely unique piece of playground equipment that serves a specific purpose or need.

School Community Project-Based Learning Ideas

• Start a comprehensive recycling program at school, or substantially improve participation in an existing one.
• Add collaborative artwork like murals or other displays to school hallways, bathrooms, or grounds.
• Determine a location or program at your school that needs improvement, then make a plan, raise the funds, and implement your ideas.
• Come up with ways to celebrate your school’s diversity and improve relationships between all students.
• Start and run a school store , including inventory, financial plans, and marketing.
• Write a school handbook for new students, with tips and tricks for helping them feel at home.
• Figure out how to offer healthier, better-tasting meals and snacks in the school cafeteria.
• Implement a mentoring program for older students to help younger students, with planned activities and appropriate training for older students.
• Design and propose a new style of grading system that ensures equity.
• Find ways to improve the indoor recess experience at your school.
• Set up and run a new school newspaper, magazine, podcast, video channel, etc.

Greater Community Project-Based Learning Ideas

• Coordinate a community art project in a central location to celebrate local culture or artists.
• Set up a program for schoolkids to socialize with senior citizens in nursing homes, hospitals, or retirement communities.
• Create a program to offer free translation services for ESL families in the community.
• Help a local animal shelter improve its facilities, or find new ways to match homeless pets with their forever families.
• Build and maintain Little Free Libraries around your community, especially in underserved areas.
• Help local businesses become more environmentally conscious, increasing sustainability and decreasing waste.
• Create and lead a walking tour of your community, highlighting its culture, history, landmarks, and more.
• Find a way to record and celebrate local voices in your community’s history.
• Come up with ideas for welcoming immigrants and other newcomers to your community.
• Set up a series of events that will encourage the community to mix and experience each others’ foods, cultures, and more.
• Create and implement a new program to inspire a love of books and reading in preschool students.
• Set up and help run a new charitable organization your community needs.

Social Issues Project-Based Learning Ideas

• Start an awareness campaign on a topic that’s important to you, like anti-bullying, healthy living, protecting the environment, civil rights, equality and equity, etc.
• Come up with and implement ways to increase voter turnout in your community, especially among younger voters.
• Write, record, and share with a wider audience your own TED Talk–style video on an issue that hasn’t been covered yet or on which you have a unique perspective.
• Devise and implement ways for unheard voices to be amplified in your school or community.
• Write and publicly perform a play that highlights a social issue that’s important to you.
• Look for areas in your community that present challenges to those with disabilities, and help to improve them to overcome those challenges.
• Research, write, and publicly present and defend a position paper on an issue that’s important to your community.
• Choose a real court case, then research the law and work with legal experts to prepare and present your own case as you would in a courtroom.
• Write, edit, seek, and incorporate real-world feedback, and publish or publicly present your own book, poem, or song on an issue that’s important to you.
• Start a program to teach a specific group (e.g., preschoolers, senior citizens, business owners) to care for and protect the environment.
• Plan and hold a fundraiser to support an issue you care about.
• Choose a law you feel is unjust, and write, research, and publicly present and defend a position paper about your desired change.

STEM Project-Based Learning Ideas

• Create an app that meets a specific purpose for a specific audience.
• Invent something new that the world needs, and then fund, create, and sell your product in the community.
• Design a game to help students learn important STEM concepts.
• Find a simple way to improve an existing product, especially if it cuts costs or improves environmental sustainability.
• Explore ways to reduce the amount of waste we produce, especially plastic and other landfill-bound items.
• Write a book or graphic novel that’s entertaining but also teaches kids about science or math.
• Devise new ways to provide clean drinking water to communities where water is scarce.
• Build an effective solar oven people can use to cook during extended power outages, or in areas where electricity isn’t available.
• Work with a university or STEM organization to gather, analyze, and present real-world scientific data.
• Design a building to fit a specific purpose or need, including researching the requirements and zoning laws, accurately drafting a plan, determining the costs, and presenting the plan to the proposed client.
• Create an interactive hands-on exhibit to teach people about STEM concepts.
• Determine a type of website you believe is missing, then research, build, and publish the site you envision.

Creative Arts Project-Based Learning Ideas

• Organize an art show for the community, seeking out those who ordinarily might not have a chance to display their work.
• Create and teach an art class in your area of expertise to children, the elderly, or another segment of the population.
• Design a mural for an area in your community that needs beautification, and seek funding or other assistance from community members to install it.
• Write a play about a topic that’s meaningful to you or your community. Work with the community to stage a performance for all to attend.
• Invite local dancers to perform at a school or community Festival of Dance, highlighting a variety of cultures and dance styles.
• Start a regular writer’s workshop where community writers can come together to share and seek feedback. Invite local authors or publishing experts to speak as guests.
• Collect stories, poems, and essays from local authors, and put them together into a book. Sell the book to raise money for a cause that’s important to local writers.
• Gather singers or instrumentalists from your community into a choir or band. Put on a concert to raise money for a special cause, or take your choir on tour to local retirement homes, hospitals, etc.
• Write a song about a person or cause that’s important to you. Produce and record the song, then find a way to share it with others.
• Make a short film about a local hero, community event, or local place. Invite others to do the same, and organize a local film festival.

What are some your favorite project-based learning ideas? Come share your thoughts in the We Are Teachers HELPLINE group on Facebook !

Plus, meaningful service learning projects for kids and teens ..

You Might Also Like

What Is Project-Based Learning and How Can I Use It With My Students?

There's a difference between regular projects and true-project based learning. Continue Reading

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Enjoy 24/7 services, access to vast digital and print resources and modern lab spaces to support your coursework and creative projects.

A crossroads of knowledge

The Lemieux Library is at the center of teaching, learning and research, offering a wide range of resources, services, expertise, spaces and technology. Most importantly, the library supports our students’ academic and personal journeys.

Space for Everyone

You’ll enjoy spending time in this dynamic and inspiring campus library full of light and art. Located near the center of campus, it’s connected to the Student Center by a walkway and inside you'll find a café.

The library is a popular space for studying, group work, creative projects and meeting up with friends. With a well-staffed and enjoyable environment, Lemieux Library is also a top student employer on campus.

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Resources to Advance Your Studies

Support your studies with incredible staff and immediate access to roughly 1 million digital and physical titles. The library’s membership in the Orbis Cascade Alliance provides access to more than 21 million titles from academic libraries in the Pacific Northwest. Still looking for more? Interlibrary Loan lets you borrow from even more collections.

If you need it, we’ll get it for you!

24/7 Support from Professional Librarians

Chat 24/7, schedule an appointment or find us in-person. Whether you need help getting started on your research project, locating great sources or accessing materials in another location, you have a team of librarians eager to assist.

Technology Access: High-End Labs & More

Academic excellence requires more than books. We’re home to the largest computer lab on campus, including computers equipped with software for VR/AR/3D modeling and data science. You can use what’s available on-site or borrow technology to use beyond the library walls. 

Creativity in Action: the Library Makerspaces

The library makerspaces empower the Seattle University community by providing the resources to explore digital and physical making in spaces that are grounded in inclusivity and open-mindedness.

The Billodue Makerspace is open to all students, all majors and driven by the belief that making is a community inclusive practice for all. There are many program activities such as learning fiber arts, jewelry making, repair sessions and using digital fabrication techniques like laser cutting and 3D printing.

The Media Production Center is available to all students with many program offerings such as how to use the studio and editing room equipment for video, photographic and audio production. Students can also create graphic stickers or learn about animation and generative AI. The center even has a screening room to watch movies on a big screen!

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Undergraduate Admission

Application requirements & enhancements.

Our admission counselors review each application carefully, taking into consideration your academic background, life experiences and interests. We don’t have a minimum test score or GPA range to gauge your potential for admission, but there are some things that can make you a stronger candidate.

Required for admission consideration

We look for students who have been successful in a variety of challenging courses, especially those that are above and beyond what’s required for graduation. And we understand every school is different, so we evaluate your transcript specifically against your high school's curriculum.

Prior to high school graduation, we require you to complete a minimum of:

• English: 4 years
• Math: 3 years
• Science: 3 years (2 must be laboratory science)
• Social studies: 3 years
• Foreign language: 2 years

If you're interested in engineering or the sciences, we recommend an additional year of math and laboratory science. Leaning more toward the liberal arts? We’d suggest another year of social studies and foreign language.

Application essay

All first-year students must complete an essay via the Common App or Coalition with Scoir. What you share in your essay is completely up to you—it should be about conveying who you are to the admission staff. No matter the topic, personalize it. Add a part of you into the piece, and make it genuine.

Arts Supplement Required for music majors and those who are pursing a Arts Achievement Scholarship in either music or art studio

Applicants who are required to submit an Arts Supplement will see this required checklist item on their applicant status portal. Students must upload their portfolio materials using the portfolio updater prior to completing the Arts Supplement. You can access the portfolio uploader by logging into your applicant portal using your CWRU Network ID and clicking Edit Portfolio.

The Arts Supplement is optional for all other applicants. (More on that below.)

Opportunities to enhance your application

We understand there may be more you want to share with us than can fit neatly on the Common App or Coalition with Scoir. Though not required as part of their application, some students choose to share additional information that may possibly strengthen their application and help us get to know them better. We welcome you to share such information with us.

Optional ways to enhance your application include the following:

Test-optional policy

Case Western Reserve University is test-optional.  Read about our test-optional policy .

We “superscore” our students’ test results, which means we take your best scores on each section of the SAT and ACT. If you took a test more than once, you will be evaluated on the highest score you received in each individual section of the exam.

Here’s a look at admitted student statistics for the Class of 2025:

Middle 50% 

• SAT Total: 1420-1510
• ACT Composite: 32-35
• Unweighted GPA: 3.6–4.0
• Test optional: 42%

Ordinarily, scores for standardized tests taken in November of your senior year arrive in time for Early Action or Early Decision I deadlines, and scores for tests taken in January arrive in time for Early Decision II or Regular Decision consideration.

To ensure your application can be fully reviewed in time for your chosen decision plan, you should take tests by the following dates:

• Nov. 30 : Early Action, Early Decision I and Pre-Professional Scholars Program applicants
• Dec. 31 : Early Decision II and Regular Decision applicants

Share your talents

Arts Supplements are required for music and music education majors and available to all applicants. If you intend to submit an arts supplement, be sure to indicate this on your application.

The arts supplement is due 15 days after the application deadline and can be completed via your applicant portal .  For detailed information:

Scholarship Audition and Portfolio Requirements

• Prepare two contrasting monologues, one Shakespeare and one contemporary, not to exceed a total time of four minutes. You may also prepare 16 bars of any song, but this is not required. If possible, please present a headshot and resume at the audition.

A portfolio presentation is needed for the directing concentration. Your portfolio should consist of the following:

• A one-page resume documenting your theater experience (directing, acting, playwriting, design, stage management, etc.).
• A one- to two- page director’s concept for a published play or musical that you would be interested in directing, detailing your vision for the show (characters, moods and tones, visual aspects) in addition to what you would want the audience to take away from the production in terms of its central themes and ideas.
• Production photos from previous projects you have directed (if applicable, not required).
• You should be prepared to speak about your interest and passion for directing as well as your previous directing and/or theater experience.

Dramatic Writing/Playwriting

• Submit a 20-page sample of your work in either playwriting or screenwriting (or both) at least one week before the interview date. This can include either an excerpt from a full-length work or a combination of shorter pieces, such as 10-minute plays or short-film scripts. While dramatic writing is preferred, you may also submit other examples of your creative writing, such as short stories, poetry, essays, etc.

Stage Management

• Bring your stage management binders, copies of scripts you have worked on (with cues written in), paperwork related to the show, and any other evidence of skills related to stage management such as organization, managing/coordinating large groups of people, multitasking and communication.
• A one-page resume of experience in theater is required. You may also include experience in a related field, such as art, architecture, graphics or photography. Additionally, a statement of intent—even if that statement is exploratory—should be provided. Other materials may include a portfolio demonstrating skills in theater (renderings, sketches, paperwork, scale drawings, production photos, etc.) and related areas (artwork, photography, drawing, drafting, computer graphics, etc.). The portfolio may be in scrapbook format. Art projects or model-making could substitute or be included with the other requirements. The material should be organized into some kind of cohesive presentation, with identifying labels for references. The interviewer will retain a copy of your resume but will not keep your portfolio. Portfolio is for presentation purposes only.
• Submit a video and complete an online questionnaire for pre-screening by dance department faculty. The video submission should be 90 seconds to three minutes in length, and you should be clearly visible. Do not submit ensemble footage. Video may be from technique class or performance.
• Submit a portfolio PowerPoint consisting of 24 pieces of your work. Each image credit line should include the name of the piece, the dimensions, the material, media and the date completed. (For example: Self-Portrait, 18” x 24”, media soft pastel on paper, fall 2021.) If you are showing three-dimensional work, i.e. sculpture or pottery, you may want to show two different views, front and side, etc. You may also want to choose to photograph a specific detail.
• Autobiography : A short (250-word) essay, citing your course of study in the visual arts. Include any special out-of-school activities, i.e., art camp, working as a teaching assistant doing creative activities, or private art lessons. Describe both your junior high and high school art experiences, courses that you took, and subjects that you studied.
• Program of study : A separate, short (250-word) essay of what you hope to gain participating in our program in Art History and Art. You may want to consult the Art History and Art website for courses that are available for you to take.

Tell us more about yourself

Additional materials can be shared through a form on your applicant portal. You can use this opportunity to share videos, web links, PDFs, documents, photos and more.

Some students use this as an opportunity to add additional context to their application with materials like:

• Additional letters of recommendation
• Research abstracts
• ACT writing tests
• Schoolhouse.world tutor transcripts
• Predicted IB results
• Though not all may be eligible for college credit at CWRU, these test scores can still enhance your application. You can send scores directly to us or self-report them via your portal.

Anything you have that can help us know you better and understand the contributions you can make to our campus are welcome and appreciated.