What is critical thinking (a definition).
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Critical thinking is a widely accepted educational goal. Its definition is contested, but the competing definitions can be understood as differing conceptions of the same basic concept: careful thinking directed to a goal. Conceptions differ with respect to the scope of such thinking, the type of goal, the criteria and norms for thinking carefully, and the thinking components on which they focus. Its adoption as an educational goal has been recommended on the basis of respect for students’ autonomy and preparing students for success in life and for democratic citizenship. “Critical thinkers” have the dispositions and abilities that lead them to think critically when appropriate. The abilities can be identified directly; the dispositions indirectly, by considering what factors contribute to or impede exercise of the abilities. Standardized tests have been developed to assess the degree to which a person possesses such dispositions and abilities. Educational intervention has been shown experimentally to improve them, particularly when it includes dialogue, anchored instruction, and mentoring. Controversies have arisen over the generalizability of critical thinking across domains, over alleged bias in critical thinking theories and instruction, and over the relationship of critical thinking to other types of thinking.
2.2 dewey’s other examples, 2.3 further examples, 2.4 non-examples, 3. the definition of critical thinking, 4. its value, 5. the process of thinking critically, 6. components of the process, 7. contributory dispositions and abilities, 8.1 initiating dispositions, 8.2 internal dispositions, 9. critical thinking abilities, 10. required knowledge, 11. educational methods, 12.1 the generalizability of critical thinking, 12.2 bias in critical thinking theory and pedagogy, 12.3 relationship of critical thinking to other types of thinking, other internet resources, related entries.
Use of the term ‘critical thinking’ to describe an educational goal goes back to the American philosopher John Dewey (1910), who more commonly called it ‘reflective thinking’. He defined it as
active, persistent and careful consideration of any belief or supposed form of knowledge in the light of the grounds that support it, and the further conclusions to which it tends. (Dewey 1910: 6; 1933: 9)
and identified a habit of such consideration with a scientific attitude of mind. His lengthy quotations of Francis Bacon, John Locke, and John Stuart Mill indicate that he was not the first person to propose development of a scientific attitude of mind as an educational goal.
In the 1930s, many of the schools that participated in the Eight-Year Study of the Progressive Education Association (Aikin 1942) adopted critical thinking as an educational goal, for whose achievement the study’s Evaluation Staff developed tests (Smith, Tyler, & Evaluation Staff 1942). Glaser (1941) showed experimentally that it was possible to improve the critical thinking of high school students. Bloom’s influential taxonomy of cognitive educational objectives (Bloom et al. 1956) incorporated critical thinking abilities. Ennis (1962) proposed 12 aspects of critical thinking as a basis for research on the teaching and evaluation of critical thinking ability.
Since 1980, an annual international conference in California on critical thinking and educational reform has attracted tens of thousands of educators from all levels of education and from many parts of the world. Also since 1980, the state university system in California has required all undergraduate students to take a critical thinking course. Since 1983, the Association for Informal Logic and Critical Thinking has sponsored sessions in conjunction with the divisional meetings of the American Philosophical Association (APA). In 1987, the APA’s Committee on Pre-College Philosophy commissioned a consensus statement on critical thinking for purposes of educational assessment and instruction (Facione 1990a). Researchers have developed standardized tests of critical thinking abilities and dispositions; for details, see the Supplement on Assessment . Educational jurisdictions around the world now include critical thinking in guidelines for curriculum and assessment.
For details on this history, see the Supplement on History .
Before considering the definition of critical thinking, it will be helpful to have in mind some examples of critical thinking, as well as some examples of kinds of thinking that would apparently not count as critical thinking.
Dewey (1910: 68–71; 1933: 91–94) takes as paradigms of reflective thinking three class papers of students in which they describe their thinking. The examples range from the everyday to the scientific.
Transit : “The other day, when I was down town on 16th Street, a clock caught my eye. I saw that the hands pointed to 12:20. This suggested that I had an engagement at 124th Street, at one o’clock. I reasoned that as it had taken me an hour to come down on a surface car, I should probably be twenty minutes late if I returned the same way. I might save twenty minutes by a subway express. But was there a station near? If not, I might lose more than twenty minutes in looking for one. Then I thought of the elevated, and I saw there was such a line within two blocks. But where was the station? If it were several blocks above or below the street I was on, I should lose time instead of gaining it. My mind went back to the subway express as quicker than the elevated; furthermore, I remembered that it went nearer than the elevated to the part of 124th Street I wished to reach, so that time would be saved at the end of the journey. I concluded in favor of the subway, and reached my destination by one o’clock.” (Dewey 1910: 68–69; 1933: 91–92)
Ferryboat : “Projecting nearly horizontally from the upper deck of the ferryboat on which I daily cross the river is a long white pole, having a gilded ball at its tip. It suggested a flagpole when I first saw it; its color, shape, and gilded ball agreed with this idea, and these reasons seemed to justify me in this belief. But soon difficulties presented themselves. The pole was nearly horizontal, an unusual position for a flagpole; in the next place, there was no pulley, ring, or cord by which to attach a flag; finally, there were elsewhere on the boat two vertical staffs from which flags were occasionally flown. It seemed probable that the pole was not there for flag-flying.
“I then tried to imagine all possible purposes of the pole, and to consider for which of these it was best suited: (a) Possibly it was an ornament. But as all the ferryboats and even the tugboats carried poles, this hypothesis was rejected. (b) Possibly it was the terminal of a wireless telegraph. But the same considerations made this improbable. Besides, the more natural place for such a terminal would be the highest part of the boat, on top of the pilot house. (c) Its purpose might be to point out the direction in which the boat is moving.
“In support of this conclusion, I discovered that the pole was lower than the pilot house, so that the steersman could easily see it. Moreover, the tip was enough higher than the base, so that, from the pilot’s position, it must appear to project far out in front of the boat. Moreover, the pilot being near the front of the boat, he would need some such guide as to its direction. Tugboats would also need poles for such a purpose. This hypothesis was so much more probable than the others that I accepted it. I formed the conclusion that the pole was set up for the purpose of showing the pilot the direction in which the boat pointed, to enable him to steer correctly.” (Dewey 1910: 69–70; 1933: 92–93)
Bubbles : “In washing tumblers in hot soapsuds and placing them mouth downward on a plate, bubbles appeared on the outside of the mouth of the tumblers and then went inside. Why? The presence of bubbles suggests air, which I note must come from inside the tumbler. I see that the soapy water on the plate prevents escape of the air save as it may be caught in bubbles. But why should air leave the tumbler? There was no substance entering to force it out. It must have expanded. It expands by increase of heat, or by decrease of pressure, or both. Could the air have become heated after the tumbler was taken from the hot suds? Clearly not the air that was already entangled in the water. If heated air was the cause, cold air must have entered in transferring the tumblers from the suds to the plate. I test to see if this supposition is true by taking several more tumblers out. Some I shake so as to make sure of entrapping cold air in them. Some I take out holding mouth downward in order to prevent cold air from entering. Bubbles appear on the outside of every one of the former and on none of the latter. I must be right in my inference. Air from the outside must have been expanded by the heat of the tumbler, which explains the appearance of the bubbles on the outside. But why do they then go inside? Cold contracts. The tumbler cooled and also the air inside it. Tension was removed, and hence bubbles appeared inside. To be sure of this, I test by placing a cup of ice on the tumbler while the bubbles are still forming outside. They soon reverse” (Dewey 1910: 70–71; 1933: 93–94).
Dewey (1910, 1933) sprinkles his book with other examples of critical thinking. We will refer to the following.
Weather : A man on a walk notices that it has suddenly become cool, thinks that it is probably going to rain, looks up and sees a dark cloud obscuring the sun, and quickens his steps (1910: 6–10; 1933: 9–13).
Disorder : A man finds his rooms on his return to them in disorder with his belongings thrown about, thinks at first of burglary as an explanation, then thinks of mischievous children as being an alternative explanation, then looks to see whether valuables are missing, and discovers that they are (1910: 82–83; 1933: 166–168).
Typhoid : A physician diagnosing a patient whose conspicuous symptoms suggest typhoid avoids drawing a conclusion until more data are gathered by questioning the patient and by making tests (1910: 85–86; 1933: 170).
Blur : A moving blur catches our eye in the distance, we ask ourselves whether it is a cloud of whirling dust or a tree moving its branches or a man signaling to us, we think of other traits that should be found on each of those possibilities, and we look and see if those traits are found (1910: 102, 108; 1933: 121, 133).
Suction pump : In thinking about the suction pump, the scientist first notes that it will draw water only to a maximum height of 33 feet at sea level and to a lesser maximum height at higher elevations, selects for attention the differing atmospheric pressure at these elevations, sets up experiments in which the air is removed from a vessel containing water (when suction no longer works) and in which the weight of air at various levels is calculated, compares the results of reasoning about the height to which a given weight of air will allow a suction pump to raise water with the observed maximum height at different elevations, and finally assimilates the suction pump to such apparently different phenomena as the siphon and the rising of a balloon (1910: 150–153; 1933: 195–198).
Diamond : A passenger in a car driving in a diamond lane reserved for vehicles with at least one passenger notices that the diamond marks on the pavement are far apart in some places and close together in others. Why? The driver suggests that the reason may be that the diamond marks are not needed where there is a solid double line separating the diamond lane from the adjoining lane, but are needed when there is a dotted single line permitting crossing into the diamond lane. Further observation confirms that the diamonds are close together when a dotted line separates the diamond lane from its neighbour, but otherwise far apart.
Rash : A woman suddenly develops a very itchy red rash on her throat and upper chest. She recently noticed a mark on the back of her right hand, but was not sure whether the mark was a rash or a scrape. She lies down in bed and thinks about what might be causing the rash and what to do about it. About two weeks before, she began taking blood pressure medication that contained a sulfa drug, and the pharmacist had warned her, in view of a previous allergic reaction to a medication containing a sulfa drug, to be on the alert for an allergic reaction; however, she had been taking the medication for two weeks with no such effect. The day before, she began using a new cream on her neck and upper chest; against the new cream as the cause was mark on the back of her hand, which had not been exposed to the cream. She began taking probiotics about a month before. She also recently started new eye drops, but she supposed that manufacturers of eye drops would be careful not to include allergy-causing components in the medication. The rash might be a heat rash, since she recently was sweating profusely from her upper body. Since she is about to go away on a short vacation, where she would not have access to her usual physician, she decides to keep taking the probiotics and using the new eye drops but to discontinue the blood pressure medication and to switch back to the old cream for her neck and upper chest. She forms a plan to consult her regular physician on her return about the blood pressure medication.
Candidate : Although Dewey included no examples of thinking directed at appraising the arguments of others, such thinking has come to be considered a kind of critical thinking. We find an example of such thinking in the performance task on the Collegiate Learning Assessment (CLA+), which its sponsoring organization describes as
a performance-based assessment that provides a measure of an institution’s contribution to the development of critical-thinking and written communication skills of its students. (Council for Aid to Education 2017)
A sample task posted on its website requires the test-taker to write a report for public distribution evaluating a fictional candidate’s policy proposals and their supporting arguments, using supplied background documents, with a recommendation on whether to endorse the candidate.
Immediate acceptance of an idea that suggests itself as a solution to a problem (e.g., a possible explanation of an event or phenomenon, an action that seems likely to produce a desired result) is “uncritical thinking, the minimum of reflection” (Dewey 1910: 13). On-going suspension of judgment in the light of doubt about a possible solution is not critical thinking (Dewey 1910: 108). Critique driven by a dogmatically held political or religious ideology is not critical thinking; thus Paulo Freire (1968 [1970]) is using the term (e.g., at 1970: 71, 81, 100, 146) in a more politically freighted sense that includes not only reflection but also revolutionary action against oppression. Derivation of a conclusion from given data using an algorithm is not critical thinking.
What is critical thinking? There are many definitions. Ennis (2016) lists 14 philosophically oriented scholarly definitions and three dictionary definitions. Following Rawls (1971), who distinguished his conception of justice from a utilitarian conception but regarded them as rival conceptions of the same concept, Ennis maintains that the 17 definitions are different conceptions of the same concept. Rawls articulated the shared concept of justice as
a characteristic set of principles for assigning basic rights and duties and for determining… the proper distribution of the benefits and burdens of social cooperation. (Rawls 1971: 5)
Bailin et al. (1999b) claim that, if one considers what sorts of thinking an educator would take not to be critical thinking and what sorts to be critical thinking, one can conclude that educators typically understand critical thinking to have at least three features.
One could sum up the core concept that involves these three features by saying that critical thinking is careful goal-directed thinking. This core concept seems to apply to all the examples of critical thinking described in the previous section. As for the non-examples, their exclusion depends on construing careful thinking as excluding jumping immediately to conclusions, suspending judgment no matter how strong the evidence, reasoning from an unquestioned ideological or religious perspective, and routinely using an algorithm to answer a question.
If the core of critical thinking is careful goal-directed thinking, conceptions of it can vary according to its presumed scope, its presumed goal, one’s criteria and threshold for being careful, and the thinking component on which one focuses. As to its scope, some conceptions (e.g., Dewey 1910, 1933) restrict it to constructive thinking on the basis of one’s own observations and experiments, others (e.g., Ennis 1962; Fisher & Scriven 1997; Johnson 1992) to appraisal of the products of such thinking. Ennis (1991) and Bailin et al. (1999b) take it to cover both construction and appraisal. As to its goal, some conceptions restrict it to forming a judgment (Dewey 1910, 1933; Lipman 1987; Facione 1990a). Others allow for actions as well as beliefs as the end point of a process of critical thinking (Ennis 1991; Bailin et al. 1999b). As to the criteria and threshold for being careful, definitions vary in the term used to indicate that critical thinking satisfies certain norms: “intellectually disciplined” (Scriven & Paul 1987), “reasonable” (Ennis 1991), “skillful” (Lipman 1987), “skilled” (Fisher & Scriven 1997), “careful” (Bailin & Battersby 2009). Some definitions specify these norms, referring variously to “consideration of any belief or supposed form of knowledge in the light of the grounds that support it and the further conclusions to which it tends” (Dewey 1910, 1933); “the methods of logical inquiry and reasoning” (Glaser 1941); “conceptualizing, applying, analyzing, synthesizing, and/or evaluating information gathered from, or generated by, observation, experience, reflection, reasoning, or communication” (Scriven & Paul 1987); the requirement that “it is sensitive to context, relies on criteria, and is self-correcting” (Lipman 1987); “evidential, conceptual, methodological, criteriological, or contextual considerations” (Facione 1990a); and “plus-minus considerations of the product in terms of appropriate standards (or criteria)” (Johnson 1992). Stanovich and Stanovich (2010) propose to ground the concept of critical thinking in the concept of rationality, which they understand as combining epistemic rationality (fitting one’s beliefs to the world) and instrumental rationality (optimizing goal fulfillment); a critical thinker, in their view, is someone with “a propensity to override suboptimal responses from the autonomous mind” (2010: 227). These variant specifications of norms for critical thinking are not necessarily incompatible with one another, and in any case presuppose the core notion of thinking carefully. As to the thinking component singled out, some definitions focus on suspension of judgment during the thinking (Dewey 1910; McPeck 1981), others on inquiry while judgment is suspended (Bailin & Battersby 2009, 2021), others on the resulting judgment (Facione 1990a), and still others on responsiveness to reasons (Siegel 1988). Kuhn (2019) takes critical thinking to be more a dialogic practice of advancing and responding to arguments than an individual ability.
In educational contexts, a definition of critical thinking is a “programmatic definition” (Scheffler 1960: 19). It expresses a practical program for achieving an educational goal. For this purpose, a one-sentence formulaic definition is much less useful than articulation of a critical thinking process, with criteria and standards for the kinds of thinking that the process may involve. The real educational goal is recognition, adoption and implementation by students of those criteria and standards. That adoption and implementation in turn consists in acquiring the knowledge, abilities and dispositions of a critical thinker.
Conceptions of critical thinking generally do not include moral integrity as part of the concept. Dewey, for example, took critical thinking to be the ultimate intellectual goal of education, but distinguished it from the development of social cooperation among school children, which he took to be the central moral goal. Ennis (1996, 2011) added to his previous list of critical thinking dispositions a group of dispositions to care about the dignity and worth of every person, which he described as a “correlative” (1996) disposition without which critical thinking would be less valuable and perhaps harmful. An educational program that aimed at developing critical thinking but not the correlative disposition to care about the dignity and worth of every person, he asserted, “would be deficient and perhaps dangerous” (Ennis 1996: 172).
Dewey thought that education for reflective thinking would be of value to both the individual and society; recognition in educational practice of the kinship to the scientific attitude of children’s native curiosity, fertile imagination and love of experimental inquiry “would make for individual happiness and the reduction of social waste” (Dewey 1910: iii). Schools participating in the Eight-Year Study took development of the habit of reflective thinking and skill in solving problems as a means to leading young people to understand, appreciate and live the democratic way of life characteristic of the United States (Aikin 1942: 17–18, 81). Harvey Siegel (1988: 55–61) has offered four considerations in support of adopting critical thinking as an educational ideal. (1) Respect for persons requires that schools and teachers honour students’ demands for reasons and explanations, deal with students honestly, and recognize the need to confront students’ independent judgment; these requirements concern the manner in which teachers treat students. (2) Education has the task of preparing children to be successful adults, a task that requires development of their self-sufficiency. (3) Education should initiate children into the rational traditions in such fields as history, science and mathematics. (4) Education should prepare children to become democratic citizens, which requires reasoned procedures and critical talents and attitudes. To supplement these considerations, Siegel (1988: 62–90) responds to two objections: the ideology objection that adoption of any educational ideal requires a prior ideological commitment and the indoctrination objection that cultivation of critical thinking cannot escape being a form of indoctrination.
Despite the diversity of our 11 examples, one can recognize a common pattern. Dewey analyzed it as consisting of five phases:
The process of reflective thinking consisting of these phases would be preceded by a perplexed, troubled or confused situation and followed by a cleared-up, unified, resolved situation (Dewey 1933: 106). The term ‘phases’ replaced the term ‘steps’ (Dewey 1910: 72), thus removing the earlier suggestion of an invariant sequence. Variants of the above analysis appeared in (Dewey 1916: 177) and (Dewey 1938: 101–119).
The variant formulations indicate the difficulty of giving a single logical analysis of such a varied process. The process of critical thinking may have a spiral pattern, with the problem being redefined in the light of obstacles to solving it as originally formulated. For example, the person in Transit might have concluded that getting to the appointment at the scheduled time was impossible and have reformulated the problem as that of rescheduling the appointment for a mutually convenient time. Further, defining a problem does not always follow after or lead immediately to an idea of a suggested solution. Nor should it do so, as Dewey himself recognized in describing the physician in Typhoid as avoiding any strong preference for this or that conclusion before getting further information (Dewey 1910: 85; 1933: 170). People with a hypothesis in mind, even one to which they have a very weak commitment, have a so-called “confirmation bias” (Nickerson 1998): they are likely to pay attention to evidence that confirms the hypothesis and to ignore evidence that counts against it or for some competing hypothesis. Detectives, intelligence agencies, and investigators of airplane accidents are well advised to gather relevant evidence systematically and to postpone even tentative adoption of an explanatory hypothesis until the collected evidence rules out with the appropriate degree of certainty all but one explanation. Dewey’s analysis of the critical thinking process can be faulted as well for requiring acceptance or rejection of a possible solution to a defined problem, with no allowance for deciding in the light of the available evidence to suspend judgment. Further, given the great variety of kinds of problems for which reflection is appropriate, there is likely to be variation in its component events. Perhaps the best way to conceptualize the critical thinking process is as a checklist whose component events can occur in a variety of orders, selectively, and more than once. These component events might include (1) noticing a difficulty, (2) defining the problem, (3) dividing the problem into manageable sub-problems, (4) formulating a variety of possible solutions to the problem or sub-problem, (5) determining what evidence is relevant to deciding among possible solutions to the problem or sub-problem, (6) devising a plan of systematic observation or experiment that will uncover the relevant evidence, (7) carrying out the plan of systematic observation or experimentation, (8) noting the results of the systematic observation or experiment, (9) gathering relevant testimony and information from others, (10) judging the credibility of testimony and information gathered from others, (11) drawing conclusions from gathered evidence and accepted testimony, and (12) accepting a solution that the evidence adequately supports (cf. Hitchcock 2017: 485).
Checklist conceptions of the process of critical thinking are open to the objection that they are too mechanical and procedural to fit the multi-dimensional and emotionally charged issues for which critical thinking is urgently needed (Paul 1984). For such issues, a more dialectical process is advocated, in which competing relevant world views are identified, their implications explored, and some sort of creative synthesis attempted.
If one considers the critical thinking process illustrated by the 11 examples, one can identify distinct kinds of mental acts and mental states that form part of it. To distinguish, label and briefly characterize these components is a useful preliminary to identifying abilities, skills, dispositions, attitudes, habits and the like that contribute causally to thinking critically. Identifying such abilities and habits is in turn a useful preliminary to setting educational goals. Setting the goals is in its turn a useful preliminary to designing strategies for helping learners to achieve the goals and to designing ways of measuring the extent to which learners have done so. Such measures provide both feedback to learners on their achievement and a basis for experimental research on the effectiveness of various strategies for educating people to think critically. Let us begin, then, by distinguishing the kinds of mental acts and mental events that can occur in a critical thinking process.
By definition, a person who does something voluntarily is both willing and able to do that thing at that time. Both the willingness and the ability contribute causally to the person’s action, in the sense that the voluntary action would not occur if either (or both) of these were lacking. For example, suppose that one is standing with one’s arms at one’s sides and one voluntarily lifts one’s right arm to an extended horizontal position. One would not do so if one were unable to lift one’s arm, if for example one’s right side was paralyzed as the result of a stroke. Nor would one do so if one were unwilling to lift one’s arm, if for example one were participating in a street demonstration at which a white supremacist was urging the crowd to lift their right arm in a Nazi salute and one were unwilling to express support in this way for the racist Nazi ideology. The same analysis applies to a voluntary mental process of thinking critically. It requires both willingness and ability to think critically, including willingness and ability to perform each of the mental acts that compose the process and to coordinate those acts in a sequence that is directed at resolving the initiating perplexity.
Consider willingness first. We can identify causal contributors to willingness to think critically by considering factors that would cause a person who was able to think critically about an issue nevertheless not to do so (Hamby 2014). For each factor, the opposite condition thus contributes causally to willingness to think critically on a particular occasion. For example, people who habitually jump to conclusions without considering alternatives will not think critically about issues that arise, even if they have the required abilities. The contrary condition of willingness to suspend judgment is thus a causal contributor to thinking critically.
Now consider ability. In contrast to the ability to move one’s arm, which can be completely absent because a stroke has left the arm paralyzed, the ability to think critically is a developed ability, whose absence is not a complete absence of ability to think but absence of ability to think well. We can identify the ability to think well directly, in terms of the norms and standards for good thinking. In general, to be able do well the thinking activities that can be components of a critical thinking process, one needs to know the concepts and principles that characterize their good performance, to recognize in particular cases that the concepts and principles apply, and to apply them. The knowledge, recognition and application may be procedural rather than declarative. It may be domain-specific rather than widely applicable, and in either case may need subject-matter knowledge, sometimes of a deep kind.
Reflections of the sort illustrated by the previous two paragraphs have led scholars to identify the knowledge, abilities and dispositions of a “critical thinker”, i.e., someone who thinks critically whenever it is appropriate to do so. We turn now to these three types of causal contributors to thinking critically. We start with dispositions, since arguably these are the most powerful contributors to being a critical thinker, can be fostered at an early stage of a child’s development, and are susceptible to general improvement (Glaser 1941: 175)
Educational researchers use the term ‘dispositions’ broadly for the habits of mind and attitudes that contribute causally to being a critical thinker. Some writers (e.g., Paul & Elder 2006; Hamby 2014; Bailin & Battersby 2016a) propose to use the term ‘virtues’ for this dimension of a critical thinker. The virtues in question, although they are virtues of character, concern the person’s ways of thinking rather than the person’s ways of behaving towards others. They are not moral virtues but intellectual virtues, of the sort articulated by Zagzebski (1996) and discussed by Turri, Alfano, and Greco (2017).
On a realistic conception, thinking dispositions or intellectual virtues are real properties of thinkers. They are general tendencies, propensities, or inclinations to think in particular ways in particular circumstances, and can be genuinely explanatory (Siegel 1999). Sceptics argue that there is no evidence for a specific mental basis for the habits of mind that contribute to thinking critically, and that it is pedagogically misleading to posit such a basis (Bailin et al. 1999a). Whatever their status, critical thinking dispositions need motivation for their initial formation in a child—motivation that may be external or internal. As children develop, the force of habit will gradually become important in sustaining the disposition (Nieto & Valenzuela 2012). Mere force of habit, however, is unlikely to sustain critical thinking dispositions. Critical thinkers must value and enjoy using their knowledge and abilities to think things through for themselves. They must be committed to, and lovers of, inquiry.
A person may have a critical thinking disposition with respect to only some kinds of issues. For example, one could be open-minded about scientific issues but not about religious issues. Similarly, one could be confident in one’s ability to reason about the theological implications of the existence of evil in the world but not in one’s ability to reason about the best design for a guided ballistic missile.
Facione (1990a: 25) divides “affective dispositions” of critical thinking into approaches to life and living in general and approaches to specific issues, questions or problems. Adapting this distinction, one can usefully divide critical thinking dispositions into initiating dispositions (those that contribute causally to starting to think critically about an issue) and internal dispositions (those that contribute causally to doing a good job of thinking critically once one has started). The two categories are not mutually exclusive. For example, open-mindedness, in the sense of willingness to consider alternative points of view to one’s own, is both an initiating and an internal disposition.
Using the strategy of considering factors that would block people with the ability to think critically from doing so, we can identify as initiating dispositions for thinking critically attentiveness, a habit of inquiry, self-confidence, courage, open-mindedness, willingness to suspend judgment, trust in reason, wanting evidence for one’s beliefs, and seeking the truth. We consider briefly what each of these dispositions amounts to, in each case citing sources that acknowledge them.
Some of the initiating dispositions, such as open-mindedness and willingness to suspend judgment, are also internal critical thinking dispositions, in the sense of mental habits or attitudes that contribute causally to doing a good job of critical thinking once one starts the process. But there are many other internal critical thinking dispositions. Some of them are parasitic on one’s conception of good thinking. For example, it is constitutive of good thinking about an issue to formulate the issue clearly and to maintain focus on it. For this purpose, one needs not only the corresponding ability but also the corresponding disposition. Ennis (1991: 8) describes it as the disposition “to determine and maintain focus on the conclusion or question”, Facione (1990a: 25) as “clarity in stating the question or concern”. Other internal dispositions are motivators to continue or adjust the critical thinking process, such as willingness to persist in a complex task and willingness to abandon nonproductive strategies in an attempt to self-correct (Halpern 1998: 452). For a list of identified internal critical thinking dispositions, see the Supplement on Internal Critical Thinking Dispositions .
Some theorists postulate skills, i.e., acquired abilities, as operative in critical thinking. It is not obvious, however, that a good mental act is the exercise of a generic acquired skill. Inferring an expected time of arrival, as in Transit , has some generic components but also uses non-generic subject-matter knowledge. Bailin et al. (1999a) argue against viewing critical thinking skills as generic and discrete, on the ground that skilled performance at a critical thinking task cannot be separated from knowledge of concepts and from domain-specific principles of good thinking. Talk of skills, they concede, is unproblematic if it means merely that a person with critical thinking skills is capable of intelligent performance.
Despite such scepticism, theorists of critical thinking have listed as general contributors to critical thinking what they variously call abilities (Glaser 1941; Ennis 1962, 1991), skills (Facione 1990a; Halpern 1998) or competencies (Fisher & Scriven 1997). Amalgamating these lists would produce a confusing and chaotic cornucopia of more than 50 possible educational objectives, with only partial overlap among them. It makes sense instead to try to understand the reasons for the multiplicity and diversity, and to make a selection according to one’s own reasons for singling out abilities to be developed in a critical thinking curriculum. Two reasons for diversity among lists of critical thinking abilities are the underlying conception of critical thinking and the envisaged educational level. Appraisal-only conceptions, for example, involve a different suite of abilities than constructive-only conceptions. Some lists, such as those in (Glaser 1941), are put forward as educational objectives for secondary school students, whereas others are proposed as objectives for college students (e.g., Facione 1990a).
The abilities described in the remaining paragraphs of this section emerge from reflection on the general abilities needed to do well the thinking activities identified in section 6 as components of the critical thinking process described in section 5 . The derivation of each collection of abilities is accompanied by citation of sources that list such abilities and of standardized tests that claim to test them.
Observational abilities : Careful and accurate observation sometimes requires specialist expertise and practice, as in the case of observing birds and observing accident scenes. However, there are general abilities of noticing what one’s senses are picking up from one’s environment and of being able to articulate clearly and accurately to oneself and others what one has observed. It helps in exercising them to be able to recognize and take into account factors that make one’s observation less trustworthy, such as prior framing of the situation, inadequate time, deficient senses, poor observation conditions, and the like. It helps as well to be skilled at taking steps to make one’s observation more trustworthy, such as moving closer to get a better look, measuring something three times and taking the average, and checking what one thinks one is observing with someone else who is in a good position to observe it. It also helps to be skilled at recognizing respects in which one’s report of one’s observation involves inference rather than direct observation, so that one can then consider whether the inference is justified. These abilities come into play as well when one thinks about whether and with what degree of confidence to accept an observation report, for example in the study of history or in a criminal investigation or in assessing news reports. Observational abilities show up in some lists of critical thinking abilities (Ennis 1962: 90; Facione 1990a: 16; Ennis 1991: 9). There are items testing a person’s ability to judge the credibility of observation reports in the Cornell Critical Thinking Tests, Levels X and Z (Ennis & Millman 1971; Ennis, Millman, & Tomko 1985, 2005). Norris and King (1983, 1985, 1990a, 1990b) is a test of ability to appraise observation reports.
Emotional abilities : The emotions that drive a critical thinking process are perplexity or puzzlement, a wish to resolve it, and satisfaction at achieving the desired resolution. Children experience these emotions at an early age, without being trained to do so. Education that takes critical thinking as a goal needs only to channel these emotions and to make sure not to stifle them. Collaborative critical thinking benefits from ability to recognize one’s own and others’ emotional commitments and reactions.
Questioning abilities : A critical thinking process needs transformation of an inchoate sense of perplexity into a clear question. Formulating a question well requires not building in questionable assumptions, not prejudging the issue, and using language that in context is unambiguous and precise enough (Ennis 1962: 97; 1991: 9).
Imaginative abilities : Thinking directed at finding the correct causal explanation of a general phenomenon or particular event requires an ability to imagine possible explanations. Thinking about what policy or plan of action to adopt requires generation of options and consideration of possible consequences of each option. Domain knowledge is required for such creative activity, but a general ability to imagine alternatives is helpful and can be nurtured so as to become easier, quicker, more extensive, and deeper (Dewey 1910: 34–39; 1933: 40–47). Facione (1990a) and Halpern (1998) include the ability to imagine alternatives as a critical thinking ability.
Inferential abilities : The ability to draw conclusions from given information, and to recognize with what degree of certainty one’s own or others’ conclusions follow, is universally recognized as a general critical thinking ability. All 11 examples in section 2 of this article include inferences, some from hypotheses or options (as in Transit , Ferryboat and Disorder ), others from something observed (as in Weather and Rash ). None of these inferences is formally valid. Rather, they are licensed by general, sometimes qualified substantive rules of inference (Toulmin 1958) that rest on domain knowledge—that a bus trip takes about the same time in each direction, that the terminal of a wireless telegraph would be located on the highest possible place, that sudden cooling is often followed by rain, that an allergic reaction to a sulfa drug generally shows up soon after one starts taking it. It is a matter of controversy to what extent the specialized ability to deduce conclusions from premisses using formal rules of inference is needed for critical thinking. Dewey (1933) locates logical forms in setting out the products of reflection rather than in the process of reflection. Ennis (1981a), on the other hand, maintains that a liberally-educated person should have the following abilities: to translate natural-language statements into statements using the standard logical operators, to use appropriately the language of necessary and sufficient conditions, to deal with argument forms and arguments containing symbols, to determine whether in virtue of an argument’s form its conclusion follows necessarily from its premisses, to reason with logically complex propositions, and to apply the rules and procedures of deductive logic. Inferential abilities are recognized as critical thinking abilities by Glaser (1941: 6), Facione (1990a: 9), Ennis (1991: 9), Fisher & Scriven (1997: 99, 111), and Halpern (1998: 452). Items testing inferential abilities constitute two of the five subtests of the Watson Glaser Critical Thinking Appraisal (Watson & Glaser 1980a, 1980b, 1994), two of the four sections in the Cornell Critical Thinking Test Level X (Ennis & Millman 1971; Ennis, Millman, & Tomko 1985, 2005), three of the seven sections in the Cornell Critical Thinking Test Level Z (Ennis & Millman 1971; Ennis, Millman, & Tomko 1985, 2005), 11 of the 34 items on Forms A and B of the California Critical Thinking Skills Test (Facione 1990b, 1992), and a high but variable proportion of the 25 selected-response questions in the Collegiate Learning Assessment (Council for Aid to Education 2017).
Experimenting abilities : Knowing how to design and execute an experiment is important not just in scientific research but also in everyday life, as in Rash . Dewey devoted a whole chapter of his How We Think (1910: 145–156; 1933: 190–202) to the superiority of experimentation over observation in advancing knowledge. Experimenting abilities come into play at one remove in appraising reports of scientific studies. Skill in designing and executing experiments includes the acknowledged abilities to appraise evidence (Glaser 1941: 6), to carry out experiments and to apply appropriate statistical inference techniques (Facione 1990a: 9), to judge inductions to an explanatory hypothesis (Ennis 1991: 9), and to recognize the need for an adequately large sample size (Halpern 1998). The Cornell Critical Thinking Test Level Z (Ennis & Millman 1971; Ennis, Millman, & Tomko 1985, 2005) includes four items (out of 52) on experimental design. The Collegiate Learning Assessment (Council for Aid to Education 2017) makes room for appraisal of study design in both its performance task and its selected-response questions.
Consulting abilities : Skill at consulting sources of information comes into play when one seeks information to help resolve a problem, as in Candidate . Ability to find and appraise information includes ability to gather and marshal pertinent information (Glaser 1941: 6), to judge whether a statement made by an alleged authority is acceptable (Ennis 1962: 84), to plan a search for desired information (Facione 1990a: 9), and to judge the credibility of a source (Ennis 1991: 9). Ability to judge the credibility of statements is tested by 24 items (out of 76) in the Cornell Critical Thinking Test Level X (Ennis & Millman 1971; Ennis, Millman, & Tomko 1985, 2005) and by four items (out of 52) in the Cornell Critical Thinking Test Level Z (Ennis & Millman 1971; Ennis, Millman, & Tomko 1985, 2005). The College Learning Assessment’s performance task requires evaluation of whether information in documents is credible or unreliable (Council for Aid to Education 2017).
Argument analysis abilities : The ability to identify and analyze arguments contributes to the process of surveying arguments on an issue in order to form one’s own reasoned judgment, as in Candidate . The ability to detect and analyze arguments is recognized as a critical thinking skill by Facione (1990a: 7–8), Ennis (1991: 9) and Halpern (1998). Five items (out of 34) on the California Critical Thinking Skills Test (Facione 1990b, 1992) test skill at argument analysis. The College Learning Assessment (Council for Aid to Education 2017) incorporates argument analysis in its selected-response tests of critical reading and evaluation and of critiquing an argument.
Judging skills and deciding skills : Skill at judging and deciding is skill at recognizing what judgment or decision the available evidence and argument supports, and with what degree of confidence. It is thus a component of the inferential skills already discussed.
Lists and tests of critical thinking abilities often include two more abilities: identifying assumptions and constructing and evaluating definitions.
In addition to dispositions and abilities, critical thinking needs knowledge: of critical thinking concepts, of critical thinking principles, and of the subject-matter of the thinking.
We can derive a short list of concepts whose understanding contributes to critical thinking from the critical thinking abilities described in the preceding section. Observational abilities require an understanding of the difference between observation and inference. Questioning abilities require an understanding of the concepts of ambiguity and vagueness. Inferential abilities require an understanding of the difference between conclusive and defeasible inference (traditionally, between deduction and induction), as well as of the difference between necessary and sufficient conditions. Experimenting abilities require an understanding of the concepts of hypothesis, null hypothesis, assumption and prediction, as well as of the concept of statistical significance and of its difference from importance. They also require an understanding of the difference between an experiment and an observational study, and in particular of the difference between a randomized controlled trial, a prospective correlational study and a retrospective (case-control) study. Argument analysis abilities require an understanding of the concepts of argument, premiss, assumption, conclusion and counter-consideration. Additional critical thinking concepts are proposed by Bailin et al. (1999b: 293), Fisher & Scriven (1997: 105–106), Black (2012), and Blair (2021).
According to Glaser (1941: 25), ability to think critically requires knowledge of the methods of logical inquiry and reasoning. If we review the list of abilities in the preceding section, however, we can see that some of them can be acquired and exercised merely through practice, possibly guided in an educational setting, followed by feedback. Searching intelligently for a causal explanation of some phenomenon or event requires that one consider a full range of possible causal contributors, but it seems more important that one implements this principle in one’s practice than that one is able to articulate it. What is important is “operational knowledge” of the standards and principles of good thinking (Bailin et al. 1999b: 291–293). But the development of such critical thinking abilities as designing an experiment or constructing an operational definition can benefit from learning their underlying theory. Further, explicit knowledge of quirks of human thinking seems useful as a cautionary guide. Human memory is not just fallible about details, as people learn from their own experiences of misremembering, but is so malleable that a detailed, clear and vivid recollection of an event can be a total fabrication (Loftus 2017). People seek or interpret evidence in ways that are partial to their existing beliefs and expectations, often unconscious of their “confirmation bias” (Nickerson 1998). Not only are people subject to this and other cognitive biases (Kahneman 2011), of which they are typically unaware, but it may be counter-productive for one to make oneself aware of them and try consciously to counteract them or to counteract social biases such as racial or sexual stereotypes (Kenyon & Beaulac 2014). It is helpful to be aware of these facts and of the superior effectiveness of blocking the operation of biases—for example, by making an immediate record of one’s observations, refraining from forming a preliminary explanatory hypothesis, blind refereeing, double-blind randomized trials, and blind grading of students’ work. It is also helpful to be aware of the prevalence of “noise” (unwanted unsystematic variability of judgments), of how to detect noise (through a noise audit), and of how to reduce noise: make accuracy the goal, think statistically, break a process of arriving at a judgment into independent tasks, resist premature intuitions, in a group get independent judgments first, favour comparative judgments and scales (Kahneman, Sibony, & Sunstein 2021). It is helpful as well to be aware of the concept of “bounded rationality” in decision-making and of the related distinction between “satisficing” and optimizing (Simon 1956; Gigerenzer 2001).
Critical thinking about an issue requires substantive knowledge of the domain to which the issue belongs. Critical thinking abilities are not a magic elixir that can be applied to any issue whatever by somebody who has no knowledge of the facts relevant to exploring that issue. For example, the student in Bubbles needed to know that gases do not penetrate solid objects like a glass, that air expands when heated, that the volume of an enclosed gas varies directly with its temperature and inversely with its pressure, and that hot objects will spontaneously cool down to the ambient temperature of their surroundings unless kept hot by insulation or a source of heat. Critical thinkers thus need a rich fund of subject-matter knowledge relevant to the variety of situations they encounter. This fact is recognized in the inclusion among critical thinking dispositions of a concern to become and remain generally well informed.
Experimental educational interventions, with control groups, have shown that education can improve critical thinking skills and dispositions, as measured by standardized tests. For information about these tests, see the Supplement on Assessment .
What educational methods are most effective at developing the dispositions, abilities and knowledge of a critical thinker? In a comprehensive meta-analysis of experimental and quasi-experimental studies of strategies for teaching students to think critically, Abrami et al. (2015) found that dialogue, anchored instruction, and mentoring each increased the effectiveness of the educational intervention, and that they were most effective when combined. They also found that in these studies a combination of separate instruction in critical thinking with subject-matter instruction in which students are encouraged to think critically was more effective than either by itself. However, the difference was not statistically significant; that is, it might have arisen by chance.
Most of these studies lack the longitudinal follow-up required to determine whether the observed differential improvements in critical thinking abilities or dispositions continue over time, for example until high school or college graduation. For details on studies of methods of developing critical thinking skills and dispositions, see the Supplement on Educational Methods .
Scholars have denied the generalizability of critical thinking abilities across subject domains, have alleged bias in critical thinking theory and pedagogy, and have investigated the relationship of critical thinking to other kinds of thinking.
McPeck (1981) attacked the thinking skills movement of the 1970s, including the critical thinking movement. He argued that there are no general thinking skills, since thinking is always thinking about some subject-matter. It is futile, he claimed, for schools and colleges to teach thinking as if it were a separate subject. Rather, teachers should lead their pupils to become autonomous thinkers by teaching school subjects in a way that brings out their cognitive structure and that encourages and rewards discussion and argument. As some of his critics (e.g., Paul 1985; Siegel 1985) pointed out, McPeck’s central argument needs elaboration, since it has obvious counter-examples in writing and speaking, for which (up to a certain level of complexity) there are teachable general abilities even though they are always about some subject-matter. To make his argument convincing, McPeck needs to explain how thinking differs from writing and speaking in a way that does not permit useful abstraction of its components from the subject-matters with which it deals. He has not done so. Nevertheless, his position that the dispositions and abilities of a critical thinker are best developed in the context of subject-matter instruction is shared by many theorists of critical thinking, including Dewey (1910, 1933), Glaser (1941), Passmore (1980), Weinstein (1990), Bailin et al. (1999b), and Willingham (2019).
McPeck’s challenge prompted reflection on the extent to which critical thinking is subject-specific. McPeck argued for a strong subject-specificity thesis, according to which it is a conceptual truth that all critical thinking abilities are specific to a subject. (He did not however extend his subject-specificity thesis to critical thinking dispositions. In particular, he took the disposition to suspend judgment in situations of cognitive dissonance to be a general disposition.) Conceptual subject-specificity is subject to obvious counter-examples, such as the general ability to recognize confusion of necessary and sufficient conditions. A more modest thesis, also endorsed by McPeck, is epistemological subject-specificity, according to which the norms of good thinking vary from one field to another. Epistemological subject-specificity clearly holds to a certain extent; for example, the principles in accordance with which one solves a differential equation are quite different from the principles in accordance with which one determines whether a painting is a genuine Picasso. But the thesis suffers, as Ennis (1989) points out, from vagueness of the concept of a field or subject and from the obvious existence of inter-field principles, however broadly the concept of a field is construed. For example, the principles of hypothetico-deductive reasoning hold for all the varied fields in which such reasoning occurs. A third kind of subject-specificity is empirical subject-specificity, according to which as a matter of empirically observable fact a person with the abilities and dispositions of a critical thinker in one area of investigation will not necessarily have them in another area of investigation.
The thesis of empirical subject-specificity raises the general problem of transfer. If critical thinking abilities and dispositions have to be developed independently in each school subject, how are they of any use in dealing with the problems of everyday life and the political and social issues of contemporary society, most of which do not fit into the framework of a traditional school subject? Proponents of empirical subject-specificity tend to argue that transfer is more likely to occur if there is critical thinking instruction in a variety of domains, with explicit attention to dispositions and abilities that cut across domains. But evidence for this claim is scanty. There is a need for well-designed empirical studies that investigate the conditions that make transfer more likely.
It is common ground in debates about the generality or subject-specificity of critical thinking dispositions and abilities that critical thinking about any topic requires background knowledge about the topic. For example, the most sophisticated understanding of the principles of hypothetico-deductive reasoning is of no help unless accompanied by some knowledge of what might be plausible explanations of some phenomenon under investigation.
Critics have objected to bias in the theory, pedagogy and practice of critical thinking. Commentators (e.g., Alston 1995; Ennis 1998) have noted that anyone who takes a position has a bias in the neutral sense of being inclined in one direction rather than others. The critics, however, are objecting to bias in the pejorative sense of an unjustified favoring of certain ways of knowing over others, frequently alleging that the unjustly favoured ways are those of a dominant sex or culture (Bailin 1995). These ways favour:
A common thread in this smorgasbord of accusations is dissatisfaction with focusing on the logical analysis and evaluation of reasoning and arguments. While these authors acknowledge that such analysis and evaluation is part of critical thinking and should be part of its conceptualization and pedagogy, they insist that it is only a part. Paul (1981), for example, bemoans the tendency of atomistic teaching of methods of analyzing and evaluating arguments to turn students into more able sophists, adept at finding fault with positions and arguments with which they disagree but even more entrenched in the egocentric and sociocentric biases with which they began. Martin (1992) and Thayer-Bacon (1992) cite with approval the self-reported intimacy with their subject-matter of leading researchers in biology and medicine, an intimacy that conflicts with the distancing allegedly recommended in standard conceptions and pedagogy of critical thinking. Thayer-Bacon (2000) contrasts the embodied and socially embedded learning of her elementary school students in a Montessori school, who used their imagination, intuition and emotions as well as their reason, with conceptions of critical thinking as
thinking that is used to critique arguments, offer justifications, and make judgments about what are the good reasons, or the right answers. (Thayer-Bacon 2000: 127–128)
Alston (2001) reports that her students in a women’s studies class were able to see the flaws in the Cinderella myth that pervades much romantic fiction but in their own romantic relationships still acted as if all failures were the woman’s fault and still accepted the notions of love at first sight and living happily ever after. Students, she writes, should
be able to connect their intellectual critique to a more affective, somatic, and ethical account of making risky choices that have sexist, racist, classist, familial, sexual, or other consequences for themselves and those both near and far… critical thinking that reads arguments, texts, or practices merely on the surface without connections to feeling/desiring/doing or action lacks an ethical depth that should infuse the difference between mere cognitive activity and something we want to call critical thinking. (Alston 2001: 34)
Some critics portray such biases as unfair to women. Thayer-Bacon (1992), for example, has charged modern critical thinking theory with being sexist, on the ground that it separates the self from the object and causes one to lose touch with one’s inner voice, and thus stigmatizes women, who (she asserts) link self to object and listen to their inner voice. Her charge does not imply that women as a group are on average less able than men to analyze and evaluate arguments. Facione (1990c) found no difference by sex in performance on his California Critical Thinking Skills Test. Kuhn (1991: 280–281) found no difference by sex in either the disposition or the competence to engage in argumentative thinking.
The critics propose a variety of remedies for the biases that they allege. In general, they do not propose to eliminate or downplay critical thinking as an educational goal. Rather, they propose to conceptualize critical thinking differently and to change its pedagogy accordingly. Their pedagogical proposals arise logically from their objections. They can be summarized as follows:
A common thread in these proposals is treatment of critical thinking as a social, interactive, personally engaged activity like that of a quilting bee or a barn-raising (Thayer-Bacon 2000) rather than as an individual, solitary, distanced activity symbolized by Rodin’s The Thinker . One can get a vivid description of education with the former type of goal from the writings of bell hooks (1994, 2010). Critical thinking for her is open-minded dialectical exchange across opposing standpoints and from multiple perspectives, a conception similar to Paul’s “strong sense” critical thinking (Paul 1981). She abandons the structure of domination in the traditional classroom. In an introductory course on black women writers, for example, she assigns students to write an autobiographical paragraph about an early racial memory, then to read it aloud as the others listen, thus affirming the uniqueness and value of each voice and creating a communal awareness of the diversity of the group’s experiences (hooks 1994: 84). Her “engaged pedagogy” is thus similar to the “freedom under guidance” implemented in John Dewey’s Laboratory School of Chicago in the late 1890s and early 1900s. It incorporates the dialogue, anchored instruction, and mentoring that Abrami (2015) found to be most effective in improving critical thinking skills and dispositions.
What is the relationship of critical thinking to problem solving, decision-making, higher-order thinking, creative thinking, and other recognized types of thinking? One’s answer to this question obviously depends on how one defines the terms used in the question. If critical thinking is conceived broadly to cover any careful thinking about any topic for any purpose, then problem solving and decision making will be kinds of critical thinking, if they are done carefully. Historically, ‘critical thinking’ and ‘problem solving’ were two names for the same thing. If critical thinking is conceived more narrowly as consisting solely of appraisal of intellectual products, then it will be disjoint with problem solving and decision making, which are constructive.
Bloom’s taxonomy of educational objectives used the phrase “intellectual abilities and skills” for what had been labeled “critical thinking” by some, “reflective thinking” by Dewey and others, and “problem solving” by still others (Bloom et al. 1956: 38). Thus, the so-called “higher-order thinking skills” at the taxonomy’s top levels of analysis, synthesis and evaluation are just critical thinking skills, although they do not come with general criteria for their assessment (Ennis 1981b). The revised version of Bloom’s taxonomy (Anderson et al. 2001) likewise treats critical thinking as cutting across those types of cognitive process that involve more than remembering (Anderson et al. 2001: 269–270). For details, see the Supplement on History .
As to creative thinking, it overlaps with critical thinking (Bailin 1987, 1988). Thinking about the explanation of some phenomenon or event, as in Ferryboat , requires creative imagination in constructing plausible explanatory hypotheses. Likewise, thinking about a policy question, as in Candidate , requires creativity in coming up with options. Conversely, creativity in any field needs to be balanced by critical appraisal of the draft painting or novel or mathematical theory.
How to cite this entry . Preview the PDF version of this entry at the Friends of the SEP Society . Look up topics and thinkers related to this entry at the Internet Philosophy Ontology Project (InPhO). Enhanced bibliography for this entry at PhilPapers , with links to its database.
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Critical thinking and problem-solving are essential skills that are closely intertwined. While critical thinking involves analyzing and evaluating information, problem-solving specifically focuses on identifying, selecting, and defending solutions to issues. However, there are challenges and problems associated with critical thinking that can impact our ability to solve problems effectively. We will go over this in more detail in the next section, but it will be helpful to have an overview while looking at problem solving with critical thinking.
" Barrier " by Hans-Jörg Aleff is licensed under CC BY-NC-SA 2.0 .
Critical thinking plays a vital role in problem-solving by enabling us to approach issues systematically and thoughtfully. Here are some examples of how critical thinking can be applied to problem-solving:
To efficiently and effectively solve problems, it is essential to be organized and mindful of critical steps and strategies. Here is a problem-solving action checklist that incorporates critical thinking principles:
By assuming the attributes of a critical thinker—curiosity, reflection, knowledge-seeking, openness to change, probing, organization, and ethics—you can effectively tackle challenges and devise intelligent solutions. Critical thinking and problem-solving, when combined, create a powerful toolset for navigating the complexities of everyday life and achieving success.
Example \(\pageindex{1}\), example of critical thinking challenges for students in central valley, ca, cognitive biases.
Example 1: Imagine you are working on a group project about water conservation practices in rural Central Valley. You believe that traditional irrigation methods are the best because that’s what your family has always used. This is confirmation bias. You seek out information that supports traditional methods and ignore newer, potentially more efficient techniques like drip irrigation. Additionally, you may rely heavily on the first article you read about traditional methods (anchoring bias), or overestimate the importance of a recent drought news story without considering long-term data (availability heuristic). These biases can lead to flawed conclusions and hinder the adoption of better practices.
Example 2: Imagine you are working on a group project about urban water conservation practices in Fresno. You believe that traditional lawn watering schedules are the best because that’s what your neighborhood has always used. This is confirmation bias. You seek out information that supports traditional schedules and ignore newer, potentially more efficient techniques like xeriscaping or smart irrigation systems. Additionally, you may rely heavily on the first article you read about traditional methods (anchoring bias) or overestimate the importance of a recent heatwave news story without considering long-term climate data (availability heuristic). These biases can lead to flawed conclusions and hinder the adoption of better practices.
Example 1: You are a student advocating for better working conditions for undocumented immigrant workers in the agricultural sector. During a class debate, you become very passionate and emotional because this issue affects many people you know personally. Your emotions could cloud your judgment, leading you to dismiss valid points from the opposing side without rational consideration. This emotional influence can prevent you from engaging in a balanced and critical analysis of the situation.
Example 2: You are a student advocating for better housing conditions for low-income families in Fresno. During a class debate, you become very passionate and emotional because this issue affects many people you know personally. Your emotions could cloud your judgment, leading you to dismiss valid points from the opposing side without rational consideration. This emotional influence can prevent you from engaging in a balanced and critical analysis of the situation.
Example 1: You are assigned to write a research paper on the economic impacts of crop rotation in Central Valley agriculture. If you rely solely on a few articles from non-credible sources and do not access comprehensive agricultural studies, your paper may lack depth and accuracy. Without complete and accurate information, it is challenging to evaluate the benefits and drawbacks of crop rotation, potentially leading to misguided conclusions and recommendations.
Example 2: You are assigned to write a research paper on the economic impacts of gentrification in Fresno. If you rely solely on a few articles from non-credible sources and do not access comprehensive urban development studies, your paper may lack depth and accuracy. Without complete and accurate information, it is challenging to evaluate the benefits and drawbacks of gentrification, potentially leading to misguided conclusions and recommendations.
Example 1: You have grown up working on your family’s farm and believe you know everything there is to know about agriculture in the Central Valley. When tasked with creating a business plan for sustainable farming, you might overlook innovative practices and new research. Your overconfidence could prevent you from seeking input from experts or considering alternative methods, resulting in a plan that is less effective and sustainable than it could be.
Example 2: You have grown up in Fresno and believe you know everything there is to know about the city’s urban development. When tasked with creating a business plan for sustainable city planning, you might overlook innovative practices and new research. Your overconfidence could prevent you from seeking input from experts or considering alternative methods, resulting in a plan that is less effective and sustainable than it could be.
Understanding and addressing these problems of critical thinking is crucial for students, especially those growing up in the agricultural context of rural Central Valley, CA. By recognizing cognitive biases, managing emotional influences, seeking complete information, and maintaining a humble attitude towards their knowledge and abilities, students can enhance their critical thinking skills and make better-informed decisions in both their academic and personal lives.
Problem-solving with critical thinking for community college students.
Critical thinking plays a vital role in problem-solving by enabling us to approach issues systematically and thoughtfully. Here are some examples of how critical thinking can be applied to problem-solving in various life scenarios community college students might encounter:
Example 1: When you have a disagreement with a classmate over a group project, critical thinking helps you move past the initial frustration. By analyzing the situation, you can identify the root cause of the disagreement, consider each person’s perspective, and work towards a compromise that benefits the entire group. This approach helps maintain a positive working relationship and ensures the project progresses smoothly.
Example 2: When you have a disagreement with a classmate over a group project in your sociology class at Fresno City College, critical thinking helps you move past the initial frustration. By analyzing the situation, you can identify the root cause of the disagreement, consider each person’s perspective, and work towards a compromise that benefits the entire group. This approach helps maintain a positive working relationship and ensures the project progresses smoothly.
Example 1: As a member of the student government, you notice declining attendance at campus events. By applying critical thinking, you can evaluate past event attendance, gather student feedback, and analyze promotional strategies. This thorough analysis enables you to develop targeted marketing campaigns and event ideas that better engage the student body, leading to increased participation and a more vibrant campus community.
Example 2: As a member of the student government at Los Angeles City College, you notice declining attendance at campus events. By applying critical thinking, you can evaluate past event attendance, gather student feedback, and analyze promotional strategies. This thorough analysis enables you to develop targeted marketing campaigns and event ideas that better engage the student body, leading to increased participation and a more vibrant campus community.
Example 1: In a sociology class, you are assigned a research project on social issues affecting rural communities. Critical thinking allows you to evaluate various sources of information, identify key themes, and synthesize data to draw meaningful conclusions. By critically assessing the reliability of your sources and the relevance of your findings, you can create a well-supported and insightful research paper.
Example 2: In a sociology class at San Francisco City College, you are assigned a research project on social issues affecting urban communities. Critical thinking allows you to evaluate various sources of information, identify key themes, and synthesize data to draw meaningful conclusions. By critically assessing the reliability of your sources and the relevance of your findings, you can create a well-supported and insightful research paper.
Example 1: As a peer tutor in a biology class, you notice some students are struggling with the concept of cellular respiration. Using critical thinking, you can devise a series of guiding questions and hands-on activities that help students break down the process into manageable parts. This method encourages active learning and helps students build a deeper understanding of the material.
Example 2: As a peer tutor in a biology class at Fresno City College, you notice some students are struggling with the concept of cellular respiration. Using critical thinking, you can devise a series of guiding questions and hands-on activities that help students break down the process into manageable parts. This method encourages active learning and helps students build a deeper understanding of the material.
Example 1: When preparing for a job interview for a part-time position at a local business, critical thinking helps you reflect on your previous work experiences and skills. By anticipating potential interview questions, you can formulate thoughtful responses that highlight your strengths and demonstrate how you can contribute to the company. This preparation increases your confidence and effectiveness in presenting yourself as the ideal candidate.
Example 2: When preparing for a job interview for a part-time position at a local business in Los Angeles, critical thinking helps you reflect on your previous work experiences and skills. By anticipating potential interview questions, you can formulate thoughtful responses that highlight your strengths and demonstrate how you can contribute to the company. This preparation increases your confidence and effectiveness in presenting yourself as the ideal candidate.
Example 1: Balancing tuition, textbooks, and living expenses can be challenging. Critical thinking enables you to create a detailed budget that accounts for all sources of income and expenses. By analyzing your spending habits and identifying areas where you can cut costs or increase savings, you can develop a financial plan that ensures you can afford your education and maintain your lifestyle.
Example 2: Balancing tuition, textbooks, and living expenses in San Francisco can be challenging. Critical thinking enables you to create a detailed budget that accounts for all sources of income and expenses. By analyzing your spending habits and identifying areas where you can cut costs or increase savings, you can develop a financial plan that ensures you can afford your education and maintain your lifestyle.
By applying critical thinking to problem-solving in various aspects of life, community college students can navigate challenges more effectively and make informed decisions. Whether dealing with interpersonal conflicts, organizational issues, academic projects, teaching and learning, job interviews, or financial planning, critical thinking provides a structured approach to achieving successful outcomes.
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The above section was remixed from the following Open Educational Resources: Introductory Composition, Basic Reading and Writing by Lumen, Module 1: Success Skills, Section 1.3 Critical Thinking by Lumen Learning , under CC BY NC SA .
Critical thinking refers to the ability to analyze information objectively and make a reasoned judgment. It involves the evaluation of sources, such as data, facts, observable phenomena, and research findings.
Good critical thinkers can draw reasonable conclusions from a set of information, and discriminate between useful and less useful details to solve problems or make decisions. These skills are especially helpful at school and in the workplace, where employers prioritize the ability to think critically. Find out why and see how you can demonstrate that you have this ability.
The circumstances that demand critical thinking vary from industry to industry. Some examples include:
Employers want job candidates who can evaluate a situation using logical thought and offer the best solution.
Someone with critical thinking skills can be trusted to make decisions independently, and will not need constant handholding.
Hiring a critical thinker means that micromanaging won't be required. Critical thinking abilities are among the most sought-after skills in almost every industry and workplace. You can demonstrate critical thinking by using related keywords in your resume and cover letter and during your interview.
If critical thinking is a key phrase in the job listings you are applying for, be sure to emphasize your critical thinking skills throughout your job search.
You can use critical thinking keywords (analytical, problem solving, creativity, etc.) in your resume. When describing your work history, include top critical thinking skills that accurately describe you. You can also include them in your resume summary, if you have one.
For example, your summary might read, “Marketing Associate with five years of experience in project management. Skilled in conducting thorough market research and competitor analysis to assess market trends and client needs, and to develop appropriate acquisition tactics.”
Include these critical thinking skills in your cover letter. In the body of your letter, mention one or two of these skills, and give specific examples of times when you have demonstrated them at work. Think about times when you had to analyze or evaluate materials to solve a problem.
You can use these skill words in an interview. Discuss a time when you were faced with a particular problem or challenge at work and explain how you applied critical thinking to solve it.
Some interviewers will give you a hypothetical scenario or problem, and ask you to use critical thinking skills to solve it. In this case, explain your thought process thoroughly to the interviewer. He or she is typically more focused on how you arrive at your solution rather than the solution itself. The interviewer wants to see you analyze and evaluate (key parts of critical thinking) the given scenario or problem.
Of course, each job will require different skills and experiences, so make sure you read the job description carefully and focus on the skills listed by the employer.
Keep these in-demand skills in mind as you refine your critical thinking practice —whether for work or school.
Part of critical thinking is the ability to carefully examine something, whether it is a problem, a set of data, or a text. People with analytical skills can examine information, understand what it means, and properly explain to others the implications of that information.
Often, you will need to share your conclusions with your employers or with a group of classmates or colleagues. You need to be able to communicate with others to share your ideas effectively. You might also need to engage in critical thinking in a group. In this case, you will need to work with others and communicate effectively to figure out solutions to complex problems.
Critical thinking often involves creativity and innovation. You might need to spot patterns in the information you are looking at or come up with a solution that no one else has thought of before. All of this involves a creative eye that can take a different approach from all other approaches.
To think critically, you need to be able to put aside any assumptions or judgments and merely analyze the information you receive. You need to be objective, evaluating ideas without bias.
Problem-solving is another critical thinking skill that involves analyzing a problem, generating and implementing a solution, and assessing the success of the plan. Employers don’t simply want employees who can think about information critically. They also need to be able to come up with practical solutions.
University of Louisville. " What is Critical Thinking ."
American Management Association. " AMA Critical Skills Survey: Workers Need Higher Level Skills to Succeed in the 21st Century ."
by John Coleman
Critical thinking is the ability to analyze and effectively break down an issue in order to make a decision or find a solution. At the heart of critical thinking is the ability to formulate deep, different, and effective questions. For effective questioning, start by holding your hypotheses loosely. Be willing to fundamentally reconsider your initial conclusions — and do so without defensiveness. Second, listen more than you talk through active listening. Third, leave your queries open-ended, and avoid yes-or-no questions. Fourth, consider the counterintuitive to avoid falling into groupthink. Fifth, take the time to stew in a problem, rather than making decisions unnecessarily quickly. Last, ask thoughtful, even difficult, follow-ups.
Are you tackling a new and difficult problem at work? Recently promoted and trying to both understand your new role and bring a fresh perspective? Or are you new to the workforce and seeking ways to meaningfully contribute alongside your more experienced colleagues? If so, critical thinking — the ability to analyze and effectively break down an issue in order to make a decision or find a solution — will be core to your success. And at the heart of critical thinking is the ability to formulate deep, different, and effective questions.
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If you are new to critical thinking or wish to deepen your conception of it, we recommend you review the content below and bookmark this page for future reference.
"Critical thinking is the intellectually disciplined process of actively and skillfully conceptualizing, applying, analyzing, synthesizing, and/or evaluating information gathered from, or generated by, observation, experience, reflection, reasoning, or communication, as a guide to belief and action. In its exemplary form, it is based on universal intellectual values that transcend subject matter divisions: clarity, accuracy, precision, consistency, relevance, sound evidence, good reasons, depth, breadth, and fairness..."
"Critical thinking is self-guided, self-disciplined thinking which attempts to reason at the highest level of quality in a fairminded way. People who think critically attempt, with consistent and conscious effort, to live rationally, reasonably, and empathically. They are keenly aware of the inherently flawed nature of human thinking when left unchecked. They strive to diminish the power of their egocentric and sociocentric tendencies. They use the intellectual tools that critical thinking offers – concepts and principles that enable them to analyze, assess, and improve thinking. They work diligently to develop the intellectual virtues of intellectual integrity, intellectual humility, intellectual civility, intellectual empathy, intellectual sense of justice and confidence in reason. They realize that no matter how skilled they are as thinkers, they can always improve their reasoning abilities and they will at times fall prey to mistakes in reasoning, human irrationality, prejudices, biases, distortions, uncritically accepted social rules and taboos, self-interest, and vested interest.
They strive to improve the world in whatever ways they can and contribute to a more rational, civilized society. At the same time, they recognize the complexities often inherent in doing so. They strive never to think simplistically about complicated issues and always to consider the rights and needs of relevant others. They recognize the complexities in developing as thinkers, and commit themselves to life-long practice toward self-improvement. They embody the Socratic principle: The unexamined life is not worth living , because they realize that many unexamined lives together result in an uncritical, unjust, dangerous world."
The Problem:
Everyone thinks; it is our nature to do so. But much of our thinking, left to itself, is biased, distorted, partial, uninformed, or down-right prejudiced. Yet the quality of our lives and that of what we produce, make, or build depends precisely on the quality of our thought. Shoddy thinking is costly, both in money and in quality of life. Excellence in thought, however, must be systematically cultivated.
A Brief Definition:
Critical thinking is the art of analyzing and evaluating thinking with a view to improving it. The Result:
A well-cultivated critical thinker:
Critical thinking is, in short, self-directed, self-disciplined, self-monitored, and self-corrective thinking. It requires rigorous standards of excellence and mindful command of their use. It entails effective communication and problem-solving abilities, and a commitment to overcoming our native egocentrism and sociocentrism. Read more about our concept of critical thinking .
Our conception of critical thinking is based on the substantive approach developed by Dr. Richard Paul and his colleagues at the Center and Foundation for Critical Thinking over multiple decades. It is relevant to every subject, discipline, and profession, and to reasoning through the problems of everyday life. It entails five essential dimensions of critical thinking:
At the left is an overview of the first three dimensions. In sum, the elements or structures of thought enable us to "take our thinking apart" and analyze it. The intellectual standards are used to assess and evaluate the elements. The intellectual traits are dispositions of mind embodied by the fairminded critical thinker. To cultivate the mind, we need command of these essential dimensions, and we need to consistently apply them as we think through the many problems and issues in our lives.
To learn more about the elements of thought and how to apply the intellectual standards, check out our interactive model. Simply click on the link below, scroll to the bottom of the page, and explore the model with your mouse.
Why the Analysis of Thinking Is Important If you want to think well, you must understand at least the rudiments of thought, the most basic structures out of which all thinking is made. You must learn how to take thinking apart. Analyzing the Logic of a Subject When we understand the elements of reasoning, we realize that all subjects, all disciplines, have a fundamental logic defined by the structures of thought embedded within them. Therefore, to lay bare a subject’s most fundamental logic, we should begin with these questions:
The Critical Thinking Bookstore
Our online bookstore houses numerous books and teacher's manuals , Thinker's Guides , videos , and other educational materials .
Learn From Our Fellows and Scholars
Watch our Event Calendar , which provides an overview of all upcoming conferences and academies hosted by the Foundation for Critical Thinking. Clicking an entry on the Event Calendar will bring up that event's details, and the option to register. For those interested in online learning, the Foundation offers accredited online courses in critical thinking for both educators and the general public, as well as an online test for evaluating basic comprehension of critical thinking concepts . We are in the process of developing more online learning tools and tests to offer the community.
Utilizing this Website
This website contains large amounts research and an online library of articles , both of which are freely available to the public. We also invite you to become a member of the Critical Thinking Community , where you will gain access to more tools and materials. If you cannot locate a resource on a specific topic or concept, try searching for it using our Search Tool . The Search Tool is at the upper-right of every page on the website.
13 Easy Steps To Improve Your Critical Thinking Skills
With the sheer volume of information that we’re bombarded with on a daily basis – and with the pervasiveness of fake news and social media bubbles – the ability to look at evidence, evaluate the trustworthiness of a source, and think critically is becoming more important than ever. This is why, for me, critical thinking is one of the most vital skills to cultivate for future success.
Critical thinking isn’t about being constantly negative or critical of everything. It’s about objectivity and having an open, inquisitive mind. To think critically is to analyze issues based on hard evidence (as opposed to personal opinions, biases, etc.) in order to build a thorough understanding of what’s really going on. And from this place of thorough understanding, you can make better decisions and solve problems more effectively.
To put it another way, critical thinking means arriving at your own carefully considered conclusions instead of taking information at face value. Here are 13 ways you can cultivate this precious skill:
1. Always vet new information with a cautious eye. Whether it’s an article someone has shared online or data that’s related to your job, always vet the information you're presented with. Good questions to ask here include, "Is this information complete and up to date?” “What evidence is being presented to support the argument?” and “Whose voice is missing here?”
2. Look at where the information has come from. Is the source trustworthy? What is their motivation for presenting this information? For example, are they trying to sell you something or get you to take a certain action (like vote for them)?
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3. Consider more than one point of view. Everyone has their own opinions and motivations – even highly intelligent people making reasonable-sounding arguments have personal opinions and biases that shape their thinking. So, when someone presents you with information, consider whether there are other sides to the story.
4. Practice active listening. Listen carefully to what others are telling you, and try to build a clear picture of their perspective. Empathy is a really useful skill here since putting yourself in another person's shoes can help you understand where they're coming from and what they might want. Try to listen without judgment – remember, critical thinking is about keeping an open mind.
5. Gather additional information where needed. Whenever you identify gaps in the information or data, do your own research to fill those gaps. The next few steps will help you do this objectively…
6. Ask lots of open-ended questions. Curiosity is a key trait of critical thinkers, so channel your inner child and ask lots of "who," "what," and "why" questions.
7. Find your own reputable sources of information, such as established news sites, nonprofit organizations, and education institutes. Try to avoid anonymous sources or sources with an ax to grind or a product to sell. Also, be sure to check when the information was published. An older source may be unintentionally offering up wrong information just because events have moved on since it was published; corroborate the info with a more recent source.
8. Try not to get your news from social media. And if you do see something on social media that grabs your interest, check the accuracy of the story (via reputable sources of information, as above) before you share it.
9. Learn to spot fake news. It's not always easy to spot false or misleading content, but a good rule of thumb is to look at the language, emotion, and tone of the piece. Is it using emotionally charged language, for instance, and trying to get you to feel a certain way? Also, look at the sources of facts, figures, images, and quotes. A legit news story will clearly state its sources.
10. Learn to spot biased information. Like fake news, biased information may seek to appeal more to your emotions than logic and/or present a limited view of the topic. So ask yourself, “Is there more to this topic than what’s being presented here?” Do your own reading around the topic to establish the full picture.
11. Question your own biases, too. Everyone has biases, and there’s no point pretending otherwise. The trick is to think objectively about your likes and dislikes, preferences, and beliefs, and consider how these might affect your thinking.
12. Form your own opinions. Remember, critical thinking is about thinking independently. So once you’ve assessed all the information, form your own conclusions about it.
13. Continue to work on your critical thinking skills. I recommend looking at online learning platforms such as Udemy and Coursera for courses on general critical thinking skills, as well as courses on specific subjects like cognitive biases.
Read more about critical thinking and other essential skills in my new book, Future Skills: The 20 Skills & Competencies Everyone Needs To Succeed In A Digital World . Written for anyone who wants to surf the wave of digital transformation – rather than be drowned by it – the book explores why these vital future skills matter and how to develop them.
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Critical thinking, as described by Oxford Languages, is the objective analysis and evaluation of an issue in order to form a judgement.
Active and skillful approach, evaluation, assessment, synthesis, and/or evaluation of information obtained from, or made by, observation, knowledge, reflection, acumen or conversation, as a guide to belief and action, requires the critical thinking process, which is why it's often used in education and academics.
Some even may view it as a backbone of modern thought.
However, it's a skill, and skills must be trained and encouraged to be used at its full potential.
People turn up to various approaches in improving their critical thinking, like:
Critical thinking can help in planning your paper and making it more concise, but it's not obvious at first. We carefully pinpointed some the questions you should ask yourself when boosting critical thinking in writing:
Usage of critical thinking comes down not only to the outline of your paper, it also begs the question: How can we use critical thinking solving problems in our writing's topic?
Let's say, you have a Powerpoint on how critical thinking can reduce poverty in the United States. You'll primarily have to define critical thinking for the viewers, as well as use a lot of critical thinking questions and synonyms to get them to be familiar with your methods and start the thinking process behind it.
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Apply critical thinking skills to complex problems.
Apply a model for solving problems and pose questions to further understanding of specific problems.
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Have you ever tried to find a solution to a problem only to realize you’ve been focusing on the wrong problem from the very beginning? Or you’ve proposed a solution only to have it shut down by your boss or coworkers? How stressful and defeating is that? With massive changes in our world that seem to create the most difficult of circumstances, both personally and professionally, your skills as a critical thinker and problem solver need to be further developed now more than ever.
By the end of this course you will have learned and memorized a practical model to solve problems on your own and with others. These 7 critical steps will ensure that you have looked at a problem from every angle and considered multiple solutions. In fact, this dynamic and holistic approach will help you solve problems once and for all!
In this module, you will be able to apply a model for solving any problem, large or small, in a creative and collaborative way. You will also be able to identify all aspects of a problem and examine role in the problem. You will be able to reframe a goal oriented question.
5 videos 2 readings 2 quizzes 3 discussion prompts
In this module, you will be able to brainstorm solutions to your possible problem. You will choose 3 possible options and analyze the advantages and disadvantages of each option. You will be able to generate more effective solutions.
5 videos 2 readings 1 quiz 2 discussion prompts
In this module, you will be able to explore your own triggers and how they may show up in our reactions. You'll be able to identify potential responses that could trigger negative reactions. You will be able to prepare and make a recommendation to your problem. You will also be able to engage in feedback.
6 videos 1 reading 1 quiz 1 discussion prompt
1 quiz • total 30 minutes.
We asked all learners to give feedback on our instructors based on the quality of their teaching style.
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870 reviews
Reviewed on Oct 1, 2023
It is great course to learn and improve your critical thinking and taking decision based on procedure and principles laind down .
Reviewed on Nov 2, 2022
very informative/supportive course and way of teaching/ online lectures was very convincing and much easy to understand.
Reviewed on Jul 15, 2024
Well designed and all points explained nicely. Sometimes these steps are obvious, but I have seen many miss them, so having this course helps. Thank you.
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The interdependence between the Project-Based Learning (PjBL) Model and the growth and enhancement of Creative Thinking and Mathematical Problem Solving Skills in Elementary Schools is unquestionable nowadays. Prior studies have yet to discover concrete evidence regarding the interdependence being discussed. This study highlighted cognitive abilities related to creative thinking and mathematics problem-solving by implementing the Project-Based Learning Model. This research was a quasi-experiment with a pretest-posttest control group design involving 43 students in the sixth grade of two elementary schools; data was collected through test and classroom observation, and then the data was analyzed using Multivariate Analysis of Variance (MANOVA). Conversely, students exposed to project-based learning models exhibit higher skill levels in creative thinking and problem-solving than those instructed using conventional learning models. The project-based learning model significantly impacted elementary school children’s creative thinking and mathematics problem-solving skills. These findings suggest that the Project-Based Learning Model is acceptable for instructors seeking to foster creativity in teaching mathematics at the primary school level in Indonesia or other countries with comparable settings.
https://doi.org/10.26803/ijlter.23.8.15
Adijaya, M. A., Widiana, I. W., Parwata, I. G. L. A., & Antara, I. G. W. S. (2023). Bloom’s taxonomy revision-oriented learning activities to improve procedural capabilities and learning outcomes. International Journal of Educational Methodology, 9(1), 261–270. https://doi.org/10.12973/ijem.9.1.261
Albab, U., Budiyono, & Indriati, D. (2020). Metacognition skills and higher order thinking skills (HOTS) in mathematics. Journal of Physics: Conference Series, 1613(1), Article 012017. https://doi.org/10.1088/1742-6596/1613/1/012017
Almulla, M. A. (2020). The effectiveness of the project-based learning (PBL) approach as a way to engage students in learning. SAGE Open, 10(3), 1–15. https://doi.org/10.1177/2158244020938702
Amerstorfer, C. M., & Münster-Kistner, C. F. V. (2021). Student perceptions of academic engagement and student-teacher relationships in problem-based learning. Frontiers in Psychology, 12, 1–18. https://doi.org/10.3389/fpsyg.2021.713057
Arends, R. I. (2013). Learning to teach (9th ed.). McGraw-Hill.
Arici, F. (2023). An examination of the effectiveness of problem-based learning method supported by augmented reality in science education. Journal of Computer Assisted Learning, 39(2), 446–476. https://doi.org/10.1111/jcal.12752
Astuti, P., Qohar, A., & Hidayanto, E. (2019). Proses berpikir siswa dalam menyelesaikan soal higher order thinking skills berdasarkan pemahaman konseptual dan prosedural [Students’ thinking process in solving higher order thinking skills questions based on conceptual and procedural understanding]. Jurnal Pendidikan: Teori, Penelitian, dan Pengembangan, 4(1), 117. https://doi.org/10.17977/jptpp.v4i1.11910
Astutik, S., Mahardika, I. K., Indrawati, Sudarti, & Supeno. (2020). HOTS student worksheet to identification of scientific creativity skill, critical thinking skill and creative thinking skill in physics learning. Journal of Physics: Conference Series, 1465(1), Article 012075. https://doi.org/10.1088/1742-6596/1465/1/012075
Aziz, A. A. M. A. (2021). The development of the HOTS mathematical problem-solving framework using the Bar model strategy: A need analysis. Review of International Geographical Education Online, 11(4), 972–981. https://doi.org/10.33403/rigeo.8006811
Babakr, Z. H., Mohamedamin, P., & Kakamad, K. (2019). Piaget’s cognitive developmental theory: Critical review. Education Quarterly Reviews, 2(3), 517–524. https://doi.org/10.31014/aior.1993.02.03.84
Benraghda, A. (2022). Self-assessment as a self-regulated learning approach in English oral presentations: College students’ choices and perceptions. Cogent Education, 9(1), Article 2123472. https://doi.org/10.1080/2331186X.2022.2123472
Cammies, C., Cunningham, J. A., & Pike, R. K. (2022). Not all Bloom and gloom: Assessing constructive alignment, higher order cognitive skills, and their influence on students’ perceived learning within the practical components of an undergraduate biology course. Journal of Biological Education, 58(3), 588–608. https://doi.org/10.1080/00219266.2022.2092191
Chen, J., Kolmos, A., & Du, X. (2021). Forms of implementation and challenges of PBL in engineering education: A review of literature. European Journal of Engineering Education, 46(1), 90–115. https://doi.org/10.1080/03043797.2020.1718615
Cheng, L., Wang, M., Chen, Y., Niu, W., Hong, M., & Zhu, Y. (2022). Design my music instrument: A project-based science, technology, engineering, arts, and mathematics program on the development of creativity. Frontiers in Psychology, 12, 1–8. https://doi.org/10.3389/fpsyg.2021.763948
C?r?t, D. K., & Aydemir, S. (2023). Online scratch activities during the COVID-19 pandemic: Computational and creative thinking. International Journal of Evaluation and Research in Education, 12(4), 2111–2120. https://doi.org/10.11591/ijere.v12i4.24938
Cook, S. C. (2020). Schema-based instruction for mathematical word problem solving: An evidence-based review for students with learning disabilities. Learning Disability Quarterly, 43(2), 75–87. https://doi.org/10.1177/0731948718823080
Creswell, J. W. (2014). Research design: Qualitative, quantitative, and mixed methods approaches (4th ed.). SAGE Publication.
Cruz, S., Lencastre, J. A., & Viseu, F. (2023). Heuristics and usability testing of a project-based learning online course: A case study with structural mathematical concepts. International Journal of Instruction, 16(3), 465–488. https://doi.org/10.29333/iji.2023.16325a
Diego-Mantecon, J. M., Prodromou, T., Lavicza, Z., Blanco, T. F., & Ortiz-Laso, Z. (2021). An attempt to evaluate STEAM project-based instruction from a school mathematics perspective. ZDM – Mathematics Education, 53(5), 1137–1148. https://doi.org/10.1007/s11858-021-01303-9
Edwar, E., Putri, R. I. I., Zulkardi, Z., & Darmawijoyo, D. (2023). Developing a workshop model for high school mathematics teachers constructing HOTS questions through the Pendidikan Matematika Realistik Indonesia approach. Journal on Mathematics Education, 14(4), 603–626. https://doi.org/10.22342/jme.v14i4.pp603-626
Gunawardena, M. (2021). Scaffolding students’ critical thinking: A process not an end game. Thinking Skills and Creativity, 41, Article 100848. https://doi.org/10.1016/j.tsc.2021.100848
Guo, P., Saab, N., Post, L. S., & Admiraal, W. (2020). A review of project-based learning in higher education: Student outcomes and measures. International Journal of Educational Research, 102, Article 101586. https://doi.org/10.1016/j.ijer.2020.101586
Handayani, A. D., & Iswantiningtyas, V. (2020). Javanese traditional games as a teaching and learning media to socialize and introduce mathematics since early age. Journal of Physics: Conference Series, 1521(3), 1–7. https://doi.org/10.1088/1742-6596/1521/3/032008
Hawari, A. D. M., & Noor, A. I. M. (2020). Project based learning pedagogical design in STEAM art education. Asian Journal of University Education, 16(3), 102–111. https://doi.org/10.24191/ajue.v16i3.11072
Hidayati, Y. M., Ngalim, A., Sutama, Arifin, Z., Abidin, Z., & Rahmawati, E. (2020). Level of combinatorial thinking in solving mathematical problems. Journal for the Education of Gifted Young Scientists, 8(3), 1231–1243. https://doi.org/10.17478/JEGYS.751038
Hujjatusnaini, N. (2020). The effect of blended project-based learning integrated with 21st-century skills on pre-service biology teachers’ higher-order thinking skills. Jurnal Pendidikan IPA Indonesia, 11(1), 104–118. https://doi.org/10.15294/jpii.v11i1.27148
Irdalisa, I., Zulherman, Z., Elvianasti, M., Widodo, W. S., & Hanum, E. (2024). Effectiveness of project-based learning on STEAM-based student’s worksheet analysis with ecoprint technique. International Journal of Educational Methodology, 10(1), 123–135. https://doi.org/10.12973/ijem.10.1.923
Jiang, B., & Li, Z. (2021). Effect of Scratch on computational thinking skills of Chinese primary school students. Journal of Computers in Education, 8(4), 505–525. https://doi.org/10.1007/s40692-021-00190-z
Jiang, Y., Xu, N., Xu, S., & Wang, S. (2022). The enlightenment of Piaget’s theory to Chinese primary school education. Advances in Social Science, Education and Humanities Research, 670, 878–882. https://doi.org/10.2991/assehr.k.220704.158
Junianto, J., & Wijaya, A. (2019). Developing students’ mathematical literacy through problem based learning. Journal of Physics: Conference Series, 1320(1), Article 012035. IOP Publishing. https://doi.org/10.1088/1742-6596/1320/1/012035
Karan, E. (2022). Enhancing students’ problem-solving skills through project-based learning. Journal of Problem Based Learning in Higher Education, 10(1), 74–87. https://doi.org/10.54337/ojs.jpblhe.v10i1.6887
Kemendikbudristek. (2023). Laporan PISA Kemendikbudristek [PISA report of the Ministry of Education and Culture]. PISA 2022 Dan Pemulihan Pembelajaran Indonesia (pp. 1–25). https://balaibahasariau.kemdikbud.go.id/wpcontent/uploads/2023/12/LAPORAN-PISA-KEMENDIKBUDRISTEK.pdf
Khalid, M., Saad, S., Hamid, S. R. A., Abdullah, M. R., Ibrahim, H., & Shahrill, M. (2020). Enhancing creativity and problem solving skills through creative problem solving in teaching mathematics. Creativity Studies, 13(2), 270–291. https://doi.org/10.3846/cs.2020.11027
Kharisma, F. N., Susilowati, S. M. E., & Ridlo, S. (2019). The effective learning models in developing problem-solving skills. KnE Social Sciences, 3(18), 595–604 https://doi.org/10.18502/kss.v3i18.4750
Kim, H. W., & Kim, M. K. (2021). A case study of children’s interaction types and learning motivation in small group project-based learning activities in a mathematics classroom. Eurasia Journal of Mathematics, Science and Technology Education, 17(12), em2051. https://doi.org/10.29333/ejmste/11415
Kurniawan, E. S., Mundilarto, M., & Istiyono, E. (2024). Improving student higher order thinking skills using Synectic-HOTS-oriented learning model. International Journal of Evaluation and Research in Education, 13(2), 1132–1140. https://doi.org/10.11591/ijere.v13i2.25002
Lafmejani, A. Q. (2022). Cognitive evolution of the “Human” concept and its adaptation to Piaget’s theory. Caspian Journal of Neurological Sciences, 8(4), 222–233. https://doi.org/10.32598/CJNS.4.31.355.1
Lazi?, B. D., Kneževi?, J. B., & Mari?i?, S. M. (2021). The influence of project-based learning on student achievement in elementary mathematics education. South African Journal of Education, 41(3), Article 1909. https://doi.org/10.15700/saje.v41n3a1909
Leasa, M. (2020). The effect of learning styles on the critical thinking skills in natural science learning of elementary school students. Elementary Education Online, 19(4), 2086–2097. https://doi.org/10.17051/ilkonline.2020.763449
Lee, J. S., & Galindo, E. (2021). Examining project-based learning successes and challenges of mathematics preservice teachers in a teacher residency program: Learning by doing. Interdisciplinary Journal of Problem-Based Learning, 15(1), 1–20. https://doi.org/10.14434/ijpbl.v15i1.28786
Li, Z. (2022). Assessment of scientific thinking and creativity in an electronic educational environment. International Journal of Science Education, 44(3), 463–486. https://doi.org/10.1080/09500693.2022.2032863
Lin, X. (2021). Investigating the unique predictors of word-problem solving using meta-analytic structural equation modeling. Educational Psychology Review, 33(3), 1097?1124. https://doi.org/10.1007/s10648-020-09554-w
Liu, M. (2023). Bayesian optimization and ensemble learning algorithm combined method for deformation prediction of concrete dam. Structures, 54, 981–993. https://doi.org/10.1016/j.istruc.2023.05.136
Lu, X., & Kaiser, G. (2022). Creativity in students’ modelling competencies: Conceptualisation and measurement. Educational Studies in Mathematics, 109(2), 287–311. https://doi.org/10.1007/s10649-021-10055-y
MacLeod, M., & Veen, J. T. V. D. (2020). Scaffolding interdisciplinary project-based learning: A case study. European Journal of Engineering Education, 45(3), 363–377. https://doi.org/10.1080/03043797.2019.1646210
Marbán, J. M., Radwan, E., Radwan, A., & Radwan, W. (2021). Primary and secondary students’ usage of digital platforms for mathematics learning during the COVID19 outbreak: The case of the Gaza strip. Mathematics, 9(2), Article 110. https://doi.org/10.3390/math9020110
Menggo, S., Pramesti, P. D. M. Y., & Krismayani, N. W. (2023). Integrating project-based learning in preparing students’ interpersonal communication skills on speaking courses in Indonesia. International Journal of Learning, Teaching and Educational Research, 22(9), 219–240. https://doi.org/10.26803/ijlter.22.9.12
Meyer, M. W., & Norman, D. (2020). Changing design education for the 21st century. The Journal of Design, Economics, and Innovation, 6(1), 13–49. https://doi.org/10.1016/j.sheji.2019.12.002
Michalsky, T. (2024). Metacognitive scaffolding for preservice teachers’ self-regulated design of higher order thinking tasks. Heliyon, 10(2), e2480. https://doi.org/10.1016/j.heliyon.2024.e24280
Moma, L. (2015). Pengambangan instrumen kemampuan berpikir kreatif matematis untuk siswa SMP [Development of mathematical creative thinking instruments for junior high school students]. Delta-Pi: Jurnal Matematika Dan Pendidikan Matematika, 4(1), 27–41. https://doi.org/10.33387/dpi.v4i1.142
Morteza, T., & Moghaddam, M. Y. (2017). On the plausibility of Bloom’s higher order thinking strategies on learner autonomy: The paradigm shift. Asian-Pacific Journal of Second and Foreign Language Education, 2, Article 14. https://doi.org/10.1186/s40862-017-0037-8
Munar, A., Winarti, W., Nai’mah, N., Rezieka, D. G., & Aulia, A. (2022). Improving higher order thinking skill (HOTs) in early children using picture story book. AL-ISHLAH: Jurnal Pendidikan, 14(3), 4611–4618. https://doi.org/10.35445/alishlah.v14i3.2224
Muttaqin, H., Susanto, Hobri, & Tohir, M. (2021). Students’ creative thinking skills in solving mathematics higher order thinking skills (HOTs) problems based on online trading arithmetic. Journal of Physics: Conference Series, 1832(1), Article 012036. https://doi.org/10.1088/1742-6596/1832/1/012036
Ndiung, S., Sariyasa, Jehadus, E., & Apsari, R. A. (2021). The effect of treffinger creative learning model with the use RME principles on creative thinking skill and mathematics learning outcome. International Journal of Instruction, 14(2), 873–888. https://doi.org/10.29333/iji.2021.14249a
Newton, K. J. (2020). Mathematical flexibility: Aspects of a continuum and the role of prior knowledge. Journal of Experimental Education, 88(4), 503–515. https://doi.org/10.1080/00220973.2019.1586629
Nizaruddin, N., & Kusmaryono, I. (2023). Transforming students’ pseudo-thinking into real thinking in mathematical problem solving. International Journal of Educational Methodology, 9(3), 477–491. https://doi.org/10.12973/ijem.9.3.477
Nuryadin, A., Karlimah, K., Lidinillah, D. A. M., & Apriani, I. F. (2023). Blended learning after the pandemic: The flipped classroom as an alternative learning model for elementary classrooms. Participatory Educational Research, 10(3), 209–225. https://doi.org/10.17275/per.23.52.10.3
OECD (Organisation for Economic Co-operation and Development). (2024). PISA results 2022 (Volume III) – Factsheets: Indonesia. OECD. https://www.oecd.org/en/publications/pisa-results-2022-volume-iii-factsheets_041a90f1-en/indonesia_a7090b49-en.html
Pakpahan, F. H., & Saragih, M. (2022). Theory of cognitive development by Jean Piaget. Journal of Applied Linguistics, 2(2), 55–60. https://doi.org/10.52622/joal.v2i2.79
Palinussa, A. L. (2013). Students’ critical mathematical thinking skills and character: Experiments for junior high school students through realistic mathematics education culture-based. Journal on Mathematics Education, 4(1), 75–94. https://doi.org/10.22342/jme.4.1.566.75-94
Piaget, J. (1936). Origins of intelligence in the child. Routledge & Kegan Paul.
PISA. (2023). PISA 2022 results (Volume I and II) – Country notes: Indonesia. https://www.oecd.org/en/publications/pisa-2022-results-volume-i-and-ii-country-notes_ed6fbcc5-en/indonesia_c2e1ae0e-en.html
Prastiti, T. D., Tresnaningsih, S., Mairing, J. P., & Azkarahman, A. R. (2020). HOTS problem on function and probability: Does it impact to students’ mathematical literacy in Universitas Terbuka? Journal of Physics: Conference Series, 1613(1), Article 012003. https://doi.org/10.1088/1742-6596/1613/1/012003
Puccio, G., Lohiser, A., & Seemiller, C. (2021). Understanding convergent thinking: Developing effective critical thinking. In Creative problem solving: A 21st century workplace skill. SAGE Publications. https://doi.org/10.4135/9781071865637
Purwaningsih, E., Sari, A. M., Yuliati, L., Masjkur, K., Kurniawan, B. R., & Zahiri, M. A. (2020). Improving the problem-solving skills through the development of teaching materials with STEM-PjBL (science, technology, engineering, and mathematics-project based learning) model integrated with TPACK (technological pedagogical content knowledge). Journal of Physics: Conference Series, 1481(1), Article 012133. https://doi.org/10.1088/1742-6596/1481/1/012133
Putri, N., Rusdiana, D., & Suwarma, I. R. (2020). Enhanching physics students’ creative thinking skills using CBL model implemented in STEM in vocational school. Journal of Physics: Conference Series, 1521, Article 042045. https://doi.org/10.1088/1742-6596/1521/4/042045
Rahman, M. S., Juniati, D., & Manuharawati, M. (2023). The quality of mathematical proficiency in solving geometry problem: Difference cognitive independence and motivation. Pegem Journal of Education and Instruction, 13(3), 255–266. https://doi.org/10.47750/pegegog.13.03.27
Rehman, N., Zhang, W., Mahmood, A., Fareed, M. Z., & Batool, S. (2023). Fostering twenty-first century skills among primary school students through math project-based learning. Humanities and Social Sciences Communications, 10(1), Article 424. https://doi.org/10.1057/s41599-023-01914-5
Roble, D. B., Lomibao, L. S., & Luna, C. A. (2021). Developing students’ creative constructs in mathematics with problem-based (PB) and problem posing (PP) tasks. Canadian Journal of Family and Youth, 13(2), 82–94. https://doi.org/10.29173/cjfy29672
Rosidin, U., Suyatna, A., & Abdurrahman, A. (2019). A combined HOTS-based assessment/STEM learning model to improve secondary students’ thinking skills: A development and evaluation study. Journal for the Education of Gifted Young Scientists, 7(3), 435–448. https://doi.org/10.17478/jegys.518464
Rusilowati, A., Negoro, R. A., Aji, A. P., & Subali, B. (2023). Development of waves critical thinking test: Physics essay test for high school student. European Journal of Educational Research, 12(4), 1781–1794. https://doi.org/10.12973/eu-jer.12.4.1781
Safie, N., & Zakaria, S. (2023). Examining the effectiveness of thinking maps usage by analysing students’ achievement in mathematics subject. Journal of Advanced Research in Applied Sciences and Engineering Technology, 31(1), 197–209. https://doi.org/10.37934/ARASET.31.1.197209
Sahudra, T. M., Ary, K. K., Ramadhani, D., Asnawi, A., & Handrianto, C. (2021). The impact of project-based flipped learning model on the technological pedagogical content knowledge skill of prospective teachers. Sustainability (Switzerland), 13(5), Article 2606. https://doi.org/10.3390/su13052606
Saldo, I. J. P., & Walag, A. M. P. (2020). Utilizing problem-based and project-based learning in developing students’ communication and collaboration skills in physics. American Journal of Educational Research, 8(5), 232–237. https://doi.org/10.12691/education-8-5-1
Samsudin, M. A., Jamali, S. M., Zain, A. N. M., & Ebrahim, N. A. (2020). The effect of STEM project based learning on self-efficacy among high-school physics students. Journal of Turkish Science Education, 17(1), 94–108. https://doi.org/10.36681/tused.2020.15
Schindler, M., & Bakker, A. (2020). Affective field during collaborative problem posing and problem solving: A case study. Educational Studies in Mathematics, 105(3), 303?324. https://doi.org/10.1007/s10649-020-09973-0
Schleicher, A. (2018). PISA 2018 insights and interpretations. OECD. Available at https://www.oecd.org/content/dam/oecd/en/about/programmes/edu/pisa/publications/national-reports/pisa-2018/PISA%202018%20Insights%20and%20Interpretations%20FINAL%20PDF.pdf
Serin, H. (2023). Teaching mathematics: The role of project-based learning. International Journal of Social Sciences & Educational Studies, 10(2), Article 28. https://doi.org/10.23918/ijsses.v10i2p378
Setianingsih, R., Sa’dijah, C., As’ari, A. R., & Muksar, M. (2017). Investigating fifth-grade students’ construction of mathematical knowledge through classroom discussion. International Electronic Journal of Mathematics Education, 12(4), 383–396. https://doi.org/10.29333/iejme/619
Shidqi, L., Trisniawati, T., & Rhosyida, N. (2023). The development of kobatar learning media for learning mathematics in elementary school. Advances in Mobile Learning Educational Research, 3(2), 886–892. https://doi.org/10.25082/amler.2023.02.015
Simonton, K. L. (2021). Project-based learning and its potential in physical education: An instructional model inquiry. Curriculum Studies in Health and Physical Education, 12(1), 36–52. https://doi.org/10.1080/25742981.2020.1862683
Sofiyan, S., Amalia, R., & Suwardi, A. B. (2020). Development of mathematical teaching materials based on project-based learning to improve students’ HOTS and character. Journal of Physics: Conference Series, 1460(1), Article 012006. https://doi.org/10.1088/1742-6596/1460/1/012006
Son, A. L., Darhim, D., & Fatimah, S. (2020). Students’ mathematical problem-solving ability based on teaching models intervention and cognitive style. Journal on Mathematics Education, 11(2), 209–222. https://doi.org/10.22342/jme.11.2.10744.209-222
Suanto, E., Maat, S. M., & Zakaria, E. (2023). The effectiveness of the implementation of three dimensions geometry KARA module on higher order thinking skills (HOTS) and motivation. International Journal of Instruction, 16(3), 95–116. https://doi.org/10.29333/iji.2023.1636a
Sukkeewan, P., Songkram, N., & Nasongkhla, J. (2024). Development and validation of a reliable and valid assessment tool for measuring innovative thinking in vocational students. International Journal of Educational Methodology, 10(1), 35–44. https://doi.org/10.12973/ijem.10.1.835
Suratno, S., Wahono, B., Chang, C. Y., Retnowati, A., & Yushardi, Y. (2020). Exploring a direct relationship between students’ problem-solving abilities and academic achievement: A STEM education at a coffee plantation area. Journal of Turkish Science Education, 17(2), 211–224. https://doi.org/10.36681/tused.2020.22
Syahriridani, M., Susilo, H., & Ibrohim, I. (2022). Developing problem based learning through lesson study. Journal of Learning Improvement and Lesson Study, 1(2), 15–22. https://doi.org/10.24036/jlils.v1i2.20
Syamsuddin, A., Juniati, D., & Siswono, T. Y. E. (2020). Understanding the problem solving strategy based on cognitive style as a tool to investigate reflective thinking process of prospective teacher. Universal Journal of Educational Research, 8(6), 2614?2620. https://doi.org/10.13189/ujer.2020.080644
Tamur, M., Ndiung, S., Nurjaman, A., & Jerito, P. (2020). Do differences in measured mathematical abilities moderate the effectiveness of the realistic mathematics education approach? Meta-analysis studies. Jurnal Math Educator Nusantara, 7(1), 13–26. https://doi.org/10.29407/jmen.v7i1.15736
Tanjung, H. S., Nababan, S. A., Sa’dijah, C., & Subanji, S. (2020). Development of assessment tools of critical thinking in mathematics in the context of HOTS. Advances in Mathematics: Scientific Journal, 9(10), 8659–8667. https://doi.org/10.37418/amsj.9.10.91
Tanujaya, B., Prahmana, R. C. I., & Mumu, J. (2021). Mathematics instruction to promote mathematics higher-order thinking skills of students in Indonesia: Moving forward. TEM Journal, 10(4), 1945–1954. https://doi.org/10.18421/TEM104-60
Vink, I. C. D., Hornstra, L., & Kroesbergen, E. H. (2023). Latent profile analysis of working memory: Relations with creativity and academic achievement. Creativity Research Journal, 1–17. https://doi.org/10.1080/10400419.2023.2183323
Wang, X. M. (2023). An online progressive peer assessment approach to project-based learning: A constructivist perspective. Educational Technology Research and Development, 71(5), 2073–2101. https://doi.org/10.1007/s11423-023-10257-6
Widiatsih, A., Wardani, D. A. R., Royhana, U., Djamali, F., & Septory, B. J. (2020). The development of mathematical problems based on higher order thinking skills (HOTS) on comparative material by implementing PBL and its effect on the teacher’s creative thinking skill. Journal of Physics: Conference Series, 1538(1), Article 012110. https://doi.org/10.1088/1742-6596/1538/1/012110
Widyaningsih, S. W., & Yusuf, I. (2019). The project-based learning model is based on simple teaching tools and critical thinking skills. Kasuari: Physics Education Journal (KPEJ), 1(1), 12–21. https://doi.org/10.37891/kpej.v1i1.33
Wijaya, T. T., Zhou, Y., Ware, A., & Hermita, N. (2021). Improving the creative thinking skills of the next generation of mathematics teachers using dynamic mathematics software. International Journal of Emerging Technologies in Learning, 16(13), 212–226. https://doi.org/10.3991/ijet.v16i13.21535
Zubaidah, S., Fuad, N. M., Mahanal, S., & Suarsini, E. (2017). Improving creative thinking skills of students through differentiated science inquiry integrated with a mind map. Journal of Turkish Science Education, 14(4), 77–91. https://doi.org/10.12973/tused.10214a
Zulyusri, Z., Elfira, I., Lufri, L., & Santosa, T. A. (2023). Literature study: Utilization of the PjBL model in science education to improve creativity and critical thinking skills. Jurnal Penelitian Pendidikan IPA, 9(1), 133–143. https://doi.org/10.29303/jppipa.v9i1.2555
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Problem-solving: Problem-solving is perhaps the most important skill that critical thinkers can possess. The ability to solve issues and bounce back from conflict is what helps you succeed, be a leader, and effect change. ... Critical thinking, in part, is the cognitive process of reading the situation: the words coming out of their mouth ...
Critical thinking involves asking questions, defining a problem, examining evidence, analyzing assumptions and biases, avoiding emotional reasoning, avoiding oversimplification, considering other interpretations, and tolerating ambiguity. Dealing with ambiguity is also seen by Strohm & Baukus (1995) as an essential part of critical thinking ...
Simply put, critical thinking is the act of deliberately analyzing information so that you can make better judgements and decisions. It involves using things like logic, reasoning, and creativity, to draw conclusions and generally understand things better. This may sound like a pretty broad definition, and that's because critical thinking is a ...
What are critical thinking skills? Critical thinking skills are the skills you use to analyze information, imagine scenarios holistically, and create rational solutions. It's a type of emotional intelligence that stimulates effective problem-solving and decision-making. When you fine-tune your critical thinking skills, you seek beyond face ...
Problem-solving. Critical thinking and problem-solving are two more terms that are frequently confused. After all, when you think critically, you're often doing so with the objective of solving a problem. The best way to understand how problem-solving and critical thinking differ is to think of problem-solving as much more narrow.
Critical thinking is the discipline of rigorously and skillfully using information, experience, observation, and reasoning to guide your decisions, actions, and beliefs. ... People who score highly in critical thinking assessments are also rated by their managers as having good problem-solving skills, creativity, strong decision-making skills ...
This process of communicating and sharing ideas is key in promoting critical thinking within a team or organization. By encouraging open dialogue and collaborative problem-solving, you create an environment that fosters the development of critical thinking skills in others. 7. Reflect and learn from the process.
Guide to Critical Thinking: Learn to Use Critical Thinking Skills. Written by MasterClass. Last updated: Jun 7, 2021 • 2 min read. Many decision-making and problem-solving tasks require critical thinking skills, which entail the ability to analyze information to reach a rational conclusion. Explore.
These skills enable individuals to analyze complex situations, make informed decisions, and find innovative solutions. Here, we present 25 examples of problem-solving and critical thinking. problem-solving scenarios to help you cultivate and enhance these skills. Ethical dilemma: A company faces a situation where a client asks for a product ...
The exact definition of critical thinking is still debated among scholars. It has been defined in many different ways including the following: . "purposeful, self-regulatory judgment which results in interpretation, analysis, evaluation, and inference, as well as explanation of the evidential, conceptual, methodological, criteriological, or ...
What is the relationship of critical thinking to problem solving, decision-making, higher-order thinking, creative thinking, and other recognized types of thinking? One's answer to this question obviously depends on how one defines the terms used in the question. If critical thinking is conceived broadly to cover any careful thinking about ...
Problem-Solving with Critical Thinking. Critical thinking plays a vital role in problem-solving by enabling us to approach issues systematically and thoughtfully. Here are some examples of how critical thinking can be applied to problem-solving: Interpersonal Conflicts. When a roommate says unkind words, critical thinking helps us look beyond ...
Problem-Solving . Problem-solving is another critical thinking skill that involves analyzing a problem, generating and implementing a solution, and assessing the success of the plan. Employers don't simply want employees who can think about information critically. They also need to be able to come up with practical solutions.
Choosing the right critical thinking course depends on your current skill level and career aspirations. Beginners should look for courses that cover the basics of logical reasoning, argument analysis, and introductory problem-solving techniques.Those with some experience might benefit from intermediate courses focusing on advanced problem-solving strategies, decision-making processes, and the ...
Critical thinking is the ability to analyze and effectively break down an issue in order to make a decision or find a solution. ... Read more on Decision making and problem solving or related ...
Module 1 • 3 hours to complete. This module will help you to develop skills and behaviors required to solve problems and implement solutions more efficiently in an agile manner by using a systematic five-step process that involves both creative and critical thinking. What's included. 31 videos 11 readings 12 quizzes.
Critical thinking and problem-solving can both help you resolve challenges, but the two practices have distinct purposes and strategies. Here are some differences between the two skills: Critical thinking This is a mode of thinking, compared to problem-solving, which is a set of solution-oriented strategies. Since critical thinking strengthens ...
Critical thinking is, in short, self-directed, self-disciplined, self-monitored, and self-corrective thinking. It requires rigorous standards of excellence and mindful command of their use. It entails effective communication and problem-solving abilities, and a commitment to overcoming our native egocentrism and sociocentrism.
6. Ask lots of open-ended questions. Curiosity is a key trait of critical thinkers, so channel your inner child and ask lots of "who," "what," and "why" questions. 7. Find your own reputable ...
Critical thinking, as described by Oxford Languages, is the objective analysis and evaluation of an issue in order to form a judgement. Active and skillful approach, evaluation, assessment, synthesis, and/or evaluation of information obtained from, or made by, observation, knowledge, reflection, acumen or conversation, as a guide to belief and action, requires the critical thinking process ...
Module 1 • 2 hours to complete. In this module, you will be able to apply a model for solving any problem, large or small, in a creative and collaborative way. You will also be able to identify all aspects of a problem and examine role in the problem. You will be able to reframe a goal oriented question. What's included.
This study highlighted cognitive abilities related to creative thinking and mathematics problem-solving by implementing the Project-Based Learning Model. ... Sudarti, & Supeno. (2020). HOTS student worksheet to identification of scientific creativity skill, critical thinking skill and creative thinking skill in physics learning. Journal of ...
Critical Thinking: Boost your problem-solving skills by analyzing situations, evaluating options, and making informed decisions for better outcomes. Mail us on : [email protected]. Share feedback. Workassist is a career support system for individuals offering seamless platform to discover, apply, & hire for a wide range of career opportunities.
Design thinking is an agile problem-solving framework that uses iterative processes. It focuses on understanding and addressing the needs of users throughout the problem-solving journey. Design thinking isn't just about finding quick solutions; it's about addressing existing problems with a user-focused approach.