what experiment is 227

Experiment 227: Butter

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Stats/Strengths [ ]

Pod Color:  Green

Gender:  Male

"Livin' large and in charge!"

Voice Actor:  Bill Fagerbakke

Special Abilities:

This big lummox may be so, but be not fool-ed. 227's main purpose is to charge into things at such an alarming speed as to break down solid titanium!

His design was inspired by two prehistoric creatures; the Woolly Rhino and the Mammoth, and is as strong as the two combined! As for his name, it was supposed to be 'Batter' as he was meant to be like literal battering ram. But defect in program had 227 butt heads rather than actually ram into things. So, Butter it is! That, and the butter-like patch of fur on his back.

One True Place:  His talents for ramming into things proved to come in handy in breaking down reenforced doors for military operations; as such, he now works as part of an Experiments division of the U.S. government alongside those like 201 and 234 .

Experiment 227: Butter

• Edit source

Stats/Strengths [ ]

Pod Color:  Green

Gender:  Male

"Livin' large and in charge!"

Voice Actor:  Bill Fagerbakke

Special Abilities:

This big lummox may be so, but be not fool-ed. 227's main purpose is to charge into things at such an alarming speed as to break down solid titanium!

His design was inspired by two prehistoric creatures; the Woolly Rhino and the Mammoth, and is as strong as the two combined! As for his name, it was supposed to be 'Batter' as he was meant to be like literal battering ram. But defect in program had 227 butt heads rather than actually ram into things. So, Butter it is! That, and the butter-like patch of fur on his back.

One True Place:  His talents for ramming into things proved to come in handy in breaking down reenforced doors for military operations; as such, he now works as part of an Experiments division of the U.S. government alongside those like 201 and 234 .

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Butter (Experiment 227)

Butter , a.k.a. Experiment 227 , is an illegal alien experiment created by Jumba Jookiba . He is designed to be able to batter through thick doors and barricades. His one true place is with the police as a battering ram and in jumba's custody.

Physical appearance [ ]

Butter is a large tan mammoth-like creature with a large head, two tiny little antennae, a big round green nose instead of trunk, green markings on his back, legs at the middle of his torso with external toes, a big hump near his face, and tusks as large as the entire front of his body.

Special Abilities [ ]

Butter can batter through thick doors by using his tusks and large head.

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Lilo & Stitch – Experiments: 2-Series » Characters

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Lilo & Stitch franchise character index Lilo Pelekai and Stitch (Experiment 626) | Major Characters | Minor Characters | Stitch! anime | Stitch & Ai Experiments : 0-Series | 1-Series | 2-Series | 3-Series | 4-Series | 5-Series | 6-Series

List of 2-Series experiments

• X-200: Adam
• X-201: Geigenstein — This experiment's white pod was in Mrs. Hasagawa's dish in "Mrs. Hasagawa's Cats", but it was not activated. Its function is unknown.
• X-202: Jam — A purple bat/lizard-like experiment with four arms, a lion-like tail, large wings on his shoulders and a Stitch-like face. He is designed to jam radars with his high-pitched screech. He was activated at the end of Stitch! The Movie , although his red pod was mislabeled as 455. He is voiced by Frank Welker . ( Appearances: Stitch! The Movie , Leroy & Stitch )
• X-203: Snipe — This experiment's green pod was seen in Stitch! The Movie . Its function is unknown.
• X-204: Nosox — A gray experiment shaped like a four-legged washing machine. He is designed to make socks disappear. His blue pod was among the twelve new pods Lilo and Stitch brought home in "Drowsy". Nosox was one of the experiments rescued in "Snafu", because Gantu caught him around "Amnesio". ( Appearances: "Snafu", Leroy & Stitch , Stitch! )
• X-205: Cheney — This experiment's pod was seen in "Skip". Its function is unknown.
• X-206: Maggie
• X-207: Barcode
• X-208: Hoax
• X-209: Smoot
• X-210: Retro — A small orange mammalian/reptilian dinosaur-like experiment with a purple nose, tiny gold-tipped ears, gold markings on his back and spots around his eyes and a thick, short tail and legs. He is designed to turn enemy weapons and technology into their most primitive state by wrapping his tongue around the object, rendering the object useless as he lets go. This process also works on people and other items, and it can be reversed by spanking his bottom three times while his tongue is wrapped around the de-evolved person or thing. His one true place is making a prehistoric zoo. His pod is blue. He is voiced by Frank Welker . His appearance under Hämsterviel's possession in "Woops" was an error. In the Stitch! anime, it is also shown that Retro's ability can also work on experiments, as when Stitch was hit by Retro's powers in one episode, he reverted to his original destructive programming. ( Appearances: "Retro", "Woops", Leroy & Stitch , Stitch! )
• X-211: Jangle
• X-212: 2-Late
• X-214: Pix — A blue camera-like experiment with small arms and three legs that are similar to a tripod. He is designed to take only bad pictures of people. He takes the pictures with his "nose" and develops the pictures like an instant camera with the pictures coming out of his mouth. His one true place is with Mrs. Hasagawa as one of her "cats". ( Appearances: "Mrs. Hasagawa's Cats", Leroy & Stitch , Stitch! )
• X-215: Crammer
• X-218: Target
• X-219: Missy
• X-220: Millie — A giant green millipede-like experiment with a koala-like face, a wide mouth, a big blue nose, black eyes, Nosy (199)-like ears and ten short tentacle limbs. This experiment is designed to plug the holes in an air filter crucial to all hyperdrives. ( Appearance: Leroy & Stitch )
• X-221: Sparky — See folder below
• X-222: Poxy — A tiny pale green-grey germ-like experiment with pink-purple spots and four white grey-tipped antennae. He is designed to transmit disease to popular planetary leaders and disable them. The symptoms are purple pimples, smelly feet, a swollen eye, and uncontrollable burping. When he turns to good, he could cure health problems. Ends up with (actually in) Gantu. He was rescued in "Snafu" and later uses his powers to cure people according to a game on the Lilo & Stitch 2: Stitch Has a Glitch DVD. His incredibly tiny pod is green. He is voiced by Tress MacNeille . This experiment's design was first shown on the Lilo & Stitch DVD's "Create Your Own Alien Experiment" bonus feature game, alongside two experiments who were never seen in The Series . ( Appearances: "Poxy", "Snafu")
• X-223: Glitch — A bright green experiment that resembles a cross between Morpholomew (316) and Poxy (222) with a round torso, pudgy arms and legs, a large round head with a little mouth, a round nose, dark green eyes, a small arrow-shaped mark above his face note  in his episode, his marking was originally V-shaped and two thin antennae. He is designed to turn technology against its user by entering machines and electronics, using technopathy , and making them malfunction, operating like a computer virus. Lilo tricked him into being downloaded into her video game. He was released as of Leroy & Stitch to help fight the Leroy clones. His one true place is Lilo's video game, rendering the games harder. His pod is green. ( Appearances: "Glitch", Leroy & Stitch )
• X-224: Tweak
• X-225: Mashy — Believed to be a light blue dinosaur-like experiment, with a huge mouth, with tiny horns above each nostril, two large ears, and a large body. An experiment matching that description can be seen in Leroy & Stitch . He was presumably designed to crush orbs of precious uburnium in his mouth, which Clip (177) was originally made to do, due to an error on Jumba's part, uburnium being close to the word for hair on his planet. ( Supposed appearance: Leroy & Stitch )
• X-226: Combo
• X-227: Butter — A large tan mammoth-like creature with two tiny little antennae, a big round green nose instead of a trunk, green markings on his back, legs at the middle of his torso with external toes, a big hump near his face, and tusks as large as the entire front of his body. Able to batter through even the thickest doors. ( Appearance: Leroy & Stitch )
• X-228: Melty — A small, red, dragon-like experiment with small bat-like wings, a reptilian head with thin pointed ears, black eyes, and a thin body. He is designed to melt enemy fortresses, weapons, and transportation, among other things, with the bright blue blasts from his mouth. His one true place is burning metal at a recycling plant. His pod is green. He is voiced by Tress MacNeille . ( Appearances: "Melty", "Remmy", Leroy & Stitch )
• X-229: Kingpin — Believed to be an unlucky experiment that looks like a yellow ten-pin bowling pin with rabbit ears, black eyes, white stomach, and a large light blue nose. An experiment matching that description can be seen in Leroy & Stitch . He is presumably designed as a target for military war games. ( Supposed appearance: Leroy & Stitch )
• X-230: Checkup
• X-231: Sprok — This experiment's blue pod was seen in the experiment profiler special feature on the Lilo & Stitch 2: Stitch Has a Glitch DVD. Its function is unknown.
• X-232: Poser — This experiment's green pod was seen in Stitch! The Movie . Its function is unknown.
• X-233: Pitch
• X-234: Shush — A reddish-pink opossum/mouse-like experiment with black eyes, large ears and a speaker at the end of its long and fluffy raccoon-like ringed tail. He is designed to eavesdrop on private enemy conversations. To stop this experiment from eavesdropping, someone must pat him on the head, so he curls up his speaker-like tail and folds his large ears downward. His one true place is with Cobra Bubbles as a CIA operative. His pod is green. ( Appearances: "Shush", Leroy & Stitch )
• X-235: Docker — This experiment's white pod was in Mrs. Hasagawa's dish in "Mrs. Hasagawa's Cats", but it was not activated. Its function is unknown.
• X-236: Charger — This experiment's green pod was seen in the Flash game Stitch Speed Chase on Disney Channel's website. Its function is unknown.
• X-237: Blip
• X-238: Bworp — This experiment's green pod was seen in the Flash game Stitch Speed Chase on Disney Channel's website. Its function is unknown.
• X-239: Clickster — This experiment is mentioned in "Drowsy" when Pleakley said, "Experiment 239 designed to cause traffic jams." However, it does not cause traffic jams; it was mistaken for Stopgo (102). Its actual function is unknown.
• X-241: Press-5
• X-242: Brownout
• X-243: Pane
• X-244: Bore
• X-245: Sournote
• X-246: Creamer
• X-247: Qwerty
• X-248: Belle — A small cyan experiment with a pitchfork-shaped head with an upside-down arrow-shaped mark on her forehead, a small body, thin arms, and a small lion-like tail. She is designed to scare people with a loud high-pitched shriek. Her one true place is Nani's alarm clock. She is voiced by Tara Strong . ( Appearances: "Belle", Leroy & Stitch )
• X-249: Sproing — A dark blue and white roughly koala-like experiment with a spring-like body, a wide mouth, round nose, dark eyes, two little ears and little antennae who is designed to launch boulders. Sproing's one true place is helping people reach high places. ( Appearance: Leroy & Stitch )
• X-250: Lacrosse
• X-251: Link — A small bright yellow, pudgy, vaguely rabbit-like experiment with red eyes, a small round nose, and long striped antennae that shoot a slimy bluish glue-like substance that will only dissolve in mud. He is designed to bind together incompatible individuals, usually by the hand or wrist. His one true place is helping arguing couples bungee jump. His pod is green. ( Appearances: "Link", Leroy & Stitch , Stitch! )
• X-252: Crete
• X-253: Uncrete
• X-254: Mr. Stenchy — See folder below
• X-255: Mrs. Sickly — A cyan experiment that bears a striking resemblance to Mr. Stenchy. Like Mr. Stenchy, she is designed to be an irresistibly cute stink-bomb , although her fumes are actually nauseatingly sweet rather than noxious. She appeared in the Stitch! anime and lived with Mr. Stenchy. Apparently, if the two of them are put together, they can devastate entire planets. She is voiced by Michelle Ruff . ( Appearance: Stitch! )
• X-256: Addy
• X-257: Rattat
• X-258: Sample — See folder below
• X-259: Rash
• X-261: B. V. Beaverton
• X-262: Ace — See folder below
• X-264: Poach
• X-267: Wishy-Washy — A pudgy lavender-bluish teddy bear-like experiment with fairy-like wings that enable him to fly. He also has a "wand" on his head that lights up every time a wish is granted, and is also good for throwing an unsuspecting opponent, like Stitch. He is designed to be a wish giver that grants any wish he hears , but the wishes are granted literally and may not turn out quite as expected . In addition to rejecting wishes for more wishes, he also has a wish limit, indicated by a small meter on his stomach which starts out completely red. As wishes are granted, the meter slowly goes down. When white, all the wishes are gone, and he is deemed useless. His pod is green. ( Appearances: "Wishy-Washy", Leroy & Stitch , Stitch! )
• X-268: Celsenheit
• X-269: Gyrotta
• X-270: Gillmore
• X-271: Noso
• X-272: Wormhole — A purple and cyan caterpillar-like experiment with black eyes, two dark purple-tipped antennae, four dark purple-tipped legs and blue mouth inside. He first appeared in the Stitch! anime, where he is shown to be nice instead of evil and can speak fluent English . His antennae also flicker and light up. He can fold himself into a ball while in a levitating-like position, and this opens up a wormhole directly behind him, specially designed to connect to the exact moment that one enters, but in a parallel universe. These wormholes last for a few days period, and Wormhole can locate any one of them which is open. While he can create one at any time, he has absolutely no power over which universe they may lead to. Leroy & Stitch erroneously gave him the number 275, which is Tickle-Tummy's number. ( Appearance: Stitch! )
• X-273: Boxboom

• X-275: Tickle-Tummy — A round, pink experiment with rabbit-like ears, no legs, a clownish face, two hands with long fingers and a large patterned torso, which she uses to jump really high. Her primary function is to tickle people, since she tickled Reuben into hysterics after he denied being ticklish. She was caught by Gantu and rescued in "Snafu". She was accidentally left off the list of experiments in Leroy & Stitch , with X-275 being Wormhole, and 272 being listed as "Mamf". It is revealed in Stitch! that she is indeed Experiment 275 and Wormhole has taken Experiment 272. Jess Winfield explained that the error was due to (in-universe) Jumba not maintaining an organized database. ( Appearances: "Snafu", Stitch! )
• X-276: Remmy — A blue experiment with a huge head that resembles Inky from Pac-Man . He is designed to enter a sleeping person's head and turn dreams into nightmares. If the person wakes up while he is still inside, he will remain there permanently to turn all future dreams into nightmares. Also, 276 was designed to attack at peak of the subconscious enjoyment. His one true place is making Virtual Reality games. His name is in reference to the REM note  rapid eye movement stage of sleep, in which dreams occur. His pod is green. He is voiced by Jeff Bennett . ( Appearances: "Remmy", Leroy & Stitch , Stitch! )
• X-277: Snooty — A light purple bat-like experiment with a furless, triangle-like body, little legs, two fingers and a thumb on each of his wings, hardly any neck, fanged wide mouth, two little nostrils, pointed ears and black eyes. He is designed to find and enrich "Snootonium," a rare element that becomes extremely dangerous once enriched, which has a similar chemical makeup as that of mucus on Earth. To help clear her sinuses, Lilo's friend Victoria decides to keep Snooty as a pet, as his one true place. His pod is red, but a pod labeled 277 was also seen in "Mrs. Hasagawa's Cats", where it was colored white instead. ( Appearances: "Snooty", Leroy & Stitch )
• X-278: Pasthole
• X-279: Futurehole — This experiment's yellow pod was seen in the experiment profiler special feature on the Lilo & Stitch 2: Stitch Has a Glitch DVD. Its function is unknown.
• X-280: Benedict Arnold
• X-282: Click
• X-283: Quarklifter
• X-284: Pixel
• X-285: Lax — A purple parrot-like experiment with a small antenna, a beak and tail feathers. He is designed to fire a green ray from his antenna that will cause anything it hits to stop working, and can also climb walls . A person hit by his ray will relax, and a machine hit with the ray will shut down. The ray can be blocked or bounced off reflective surfaces. However, the ray wears off in time. The Recess gang helped Lilo capture 285. His one true place is at the airport, making grouchy business people enjoy their vacation. His pod is green. He is voiced by Rob Paulsen . ( Appearances: "Lax", Leroy & Stitch )
• X-286: Gellasifier — This experiment's red pod was seen in the experiment profiler special feature on the Lilo & Stitch 2: Stitch Has a Glitch DVD. Its function is unknown.
• X-287: Burl
• X-288: Boomer — A small white and brown experiment with a curved head and lightweight body. He is designed to be a living boomerang. His one true place is with Mrs. Hasagawa as one of her "cats". ( Appearances: "Mrs. Hasagawa's Cats", Leroy & Stitch , Stitch! )
• X-289: Stringulator
• X-290: U-port
• X-291: Catalyst
• X-292: Whatsamattafoyou
• X-293: Vacuum
• X-294: Poppapoppup
• X-295: Spineless
• X-296: Crash — This experiment's green pod was seen in the Flash game Stitch Speed Chase on Disney Channel's website. Its function is unknown.
• X-297: Shortstuff — A red-orange crab-like experiment with four claws, four legs, dark blue eyes and two antennae on his head, able to swivel at the waist more than 360° . He is designed to destroy machinery by entering the mechanism and cutting the internal electrical wiring with his claws. His size was greatly increased by accident when he was zapped by Jumba's growth ray. As a result of his growth, his one true place is as an amusement park ride. His pod is green. He is voiced by Nancy Cartwright . He was seen in the Stitch! anime back at his original size. ( Appearances: "Shortstuff", Leroy & Stitch , Stitch! , Disney Tsum Tsum note  Non-playable event character only )
• X-299: Dimensionator

Notable 2-Series experiments

• Adaptational Villainy : In the video game, Kingdom Hearts: Birth by Sleep , where he is a mandatory boss battle. Justified though as the game takes place at a time before the events of Lilo & Stitch , so he was still evil by then.
• Ascended Extra : One of the more prominent experiments, eventually becoming the first of Stitch's cousins to appear in a Disney work outside of the Lilo & Stitch franchise. By extension, he is also the only Disney television character to appear in a Kingdom Hearts game so far. He has also made several appearances in the anime due to his popularity, and was one of only three experiments other than Stitch and Reuben to appear in its first season (the other two being Angel and Felix).
• Big Damn Heroes : Gets several in Stitch! The Movie (see The Movie 's page for more details on this trope).
• Psycho Electro : An electric being that has a good bit of the mischievous personality that Stitch has, down to having his own Evil Laugh . It must run in their family.
• The Quiet One : The only word he ever says is "cousins" when wanting to save the other experiments.
• Retractable Appendages : Has an extra pair of arms like Stitch, though he doesn't use them much. However, his first showing of his extra arms plays a role to Stitch accepting him as a cousin.
• Ride the Lightning : He can travel through electrical currents and can fly through the air. This also changes his appearance, with the lower half of his body expanding to appear as a long electric streak.
• Shock and Awe : His main ability and the basis for his name.
• Small Role, Big Impact : While not exactly a minor character, Sparky's appearances in Lilo & Stitch: The Series are only occasional. However, his actions during Stitch! The Movie are the reason for why Gantu and Reuben (625) spend the series stranded on Earth in a spaceship too damaged to fly, preventing them from leaving even if they wanted to.
• Starter Villain : He is the first experiment that Lilo & Stitch capture and reform.
• Weaksauce Weakness : A simple glass vase can trap him since glass is not conductive to electricity.

• Cuteness Proximity : He's actually designed with the trope in mind, using his adorable looks to get people to lower their defenses and take him in before eventually letting off his unholy stench .
• Evil Smells Bad : Jumba's intent for 254 is to make his stench so unbearable that large areas would become unhabitable, though he didn't expect Plorgonar to be an exception.
• Innocent Blue Eyes : He has giant blue eyes that reflect his innocent and cute nature.
• Nice Guy : He is genuinely nice, but his ability prevents him from staying with non-Plorgonarians, and experiments like Stitch and Reuben don't like being upstaged by his cuteness .
• Nonstandard Character Design : He is one of the only experiments with visible sclera and irises, unlike the others who have completely black or single-colored eyes.
• No-Sell : His ability has the opposite effect on Plorgonarians, who love the awful smell he makes. In fact, his one true place is to be on Plorgonar.
• Palette Swap : Has one in his immediate successor and wife Mrs. Sickly (255), who only appears in the anime's third season episode "A Very Stinky Christmas". She is a teal-colored version of him with yellow eyes who produces a scent that is too sickly sweet.
• Ridiculously Cute Critter : Jumba deliberately made him this; he is a little pink fluffy creature with a big head and little floppy antennae. Unfortunately, this also is why Stitch and later Reuben are jealous of him .
• Stink Bomb : A living one; he lets out a foul odor after 48 hours, leaving any planet unhospitable (except for Pleakley's planet Plorgonar, which finds his scent to be a rare and valuable perfume).
• Weaponized Stench : He can release a powerful odor upon unsuspecting victims who are caught off guard by his cuteness.

• Aliens Speaking English : In the anime, he can now speak independently of his own recorded sounds, albeit filtered by his speaker effects.
• Ascended Extra : He's one of the four experiments other than the Mid Six-Twos who was made into a costumed character for the Disney Parks and appears in "Stitch Meets High School Musical ", the other three being Sparky, Felix, and 627.
• Character Tic : Hopping from foot to foot whenever he copies sounds.
• Cloudcuckoolander : He seems oblivious to his surroundings, ignoring when he should be quiet.
• Incessant Music Madness : His very purpose, he'll play nonstop music to annoy others into insanity.
• Involuntary Dance : In the anime he causes others to dance with his music.
• Perpetual Smiler : He always smiles and is blissfully oblivious to his surroundings. Averted in his anime episode, when he gets angry at people trying to stop him and his rhythm.
• Suddenly Voiced : He never spoke on his own accord in The Series , but in the anime, he can now verbally communicate in his own filtered voice.

• The Ace : It's his name , which reflects how he is a true superhero among the experiments. He even inspires Stitch to be a hero in his anime episode.
• Aliens Speaking English : In the anime, where he speaks with a stereotypical "heroic" voice.
• Ascended Extra : Downplayed ; in Lilo & Stitch: The Series , he only appeared in one half-length episode, and his screentime and prominence in the said episode were reduced when it was turned into a Clip Show . In the Stitch! anime, note  specifically during Shin-Ei Animation 's run he makes minor appearances in two episodes before getting a full-length post-season episode note  set before the third season finale and treated as a regular episode internationally that actually focused on him. Adding onto that, he makes another minor appearance in the first of the two post-series specials.
• Epic Fail : From Jumba's perspective, Ace is this; since the former was creating evil experiments, the latter was a failure in that he was the only experiment created that was purely good.
• Flying Brick : Becomes this in the anime, gaining the ability to fly while still having super strength.
• Heroic Build : He has a muscular frame and is a superhero.
• Nice Guy : He is one of the few experiments to be completely good at the start due to Jumba messing up his programming. He saves a cat from a burning building and puts out said fire.
• Primary-Color Champion : Perhaps to highlight just how much of a good guy he is, he has predominantly red fur, a yellow-colored belly, and a blue nose.
• Red Is Heroic : He's mostly red and is 100% heroic, much to the chagrin of his creator.
• Saying Sound Effects Out Loud : Oddly does this in his anime episode.
• Smug Smiler : He has a cocky toothy grin that never leaves his face.
• Suddenly Speaking : In the original series, he is silent save for a "heroic"-sounding cough from inhaling smoke in the burning house; in the anime, he speaks with a stereotypical "heroic" voice.
• Super-Breath : Has heat breath as one of his powers, but this was only shown in the original storyboards of his Lilo & Stitch: The Series episode. In said storyboards, he uses this power to melt the ice Slushy made on a road, unintentionally ruining part of Jumba's plan to convince Mortlegax to keep the Kweltikwan in E.G.O.
• Token Heroic Orc : Zig-Zagged . While he's certainly not the only experiment with no evil powers or behavior, he is notable for being the only one who was (accidentally) created to be an outright hero .
• White Gloves : Zig-Zagged ; his hands and forearms give him the appearance of having these to fit with his heroic looks.

Video Example(s):

Sparky (Experiment 226) is an electrokinetic experiment designed to create power outages.

Example of: Shock and Awe

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• Published: 07 July 2021

Quantum phases of matter on a 256-atom programmable quantum simulator

• Sepehr Ebadi 1 ,
• Tout T. Wang 1 ,
• Harry Levine 1 ,
• Alexander Keesling 1 , 2 ,
• Giulia Semeghini 1 ,
• Ahmed Omran 1 , 2 ,
• Dolev Bluvstein 1 ,
• Rhine Samajdar   ORCID: orcid.org/0000-0001-5171-7798 1 ,
• Hannes Pichler 3 , 4 ,
• Wen Wei Ho   ORCID: orcid.org/0000-0001-7702-2900 1 , 5 ,
• Soonwon Choi   ORCID: orcid.org/0000-0002-1247-062X 6 ,
• Subir Sachdev   ORCID: orcid.org/0000-0002-2432-7070 1 ,
• Markus Greiner 1 ,
• Vladan Vuletić   ORCID: orcid.org/0000-0002-9786-0538 7 &
• Mikhail D. Lukin   ORCID: orcid.org/0000-0002-8658-1007 1  

Nature volume  595 ,  pages 227–232 ( 2021 ) Cite this article

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• Phase transitions and critical phenomena
• Quantum simulation
• Ultracold gases

Motivated by far-reaching applications ranging from quantum simulations of complex processes in physics and chemistry to quantum information processing 1 , a broad effort is currently underway to build large-scale programmable quantum systems. Such systems provide insights into strongly correlated quantum matter 2 , 3 , 4 , 5 , 6 , while at the same time enabling new methods for computation 7 , 8 , 9 , 10 and metrology 11 . Here we demonstrate a programmable quantum simulator based on deterministically prepared two-dimensional arrays of neutral atoms, featuring strong interactions controlled by coherent atomic excitation into Rydberg states 12 . Using this approach, we realize a quantum spin model with tunable interactions for system sizes ranging from 64 to 256 qubits. We benchmark the system by characterizing high-fidelity antiferromagnetically ordered states and demonstrating quantum critical dynamics consistent with an Ising quantum phase transition in (2 + 1) dimensions 13 . We then create and study several new quantum phases that arise from the interplay between interactions and coherent laser excitation 14 , experimentally map the phase diagram and investigate the role of quantum fluctuations. Offering a new lens into the study of complex quantum matter, these observations pave the way for investigations of exotic quantum phases, non-equilibrium entanglement dynamics and hardware-efficient realization of quantum algorithms.

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Observing and braiding topological Majorana modes on programmable quantum simulators

Dynamical topological phase realized in a trapped-ion quantum simulator

A programmable qudit-based quantum processor

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Preskill, J. Quantum computing in the NISQ era and beyond. Quantum 2 , 79 (2018).

Article   Google Scholar  

Zhang, J. et al. Observation of a many-body dynamical phase transition with a 53-qubit quantum simulator. Nature 551 , 601–604 (2017).

Article   ADS   CAS   PubMed   PubMed Central   Google Scholar  

Gross, C. & Bloch, I. Quantum simulations with ultracold atoms in optical lattices. Science 357 , 995–1001 (2017).

Article   ADS   CAS   PubMed   Google Scholar  

Choi, J.-y. et al. Exploring the many-body localization transition in two dimensions. Science 352 , 1547–1552 (2016).

Article   ADS   MathSciNet   CAS   PubMed   MATH   Google Scholar  

Mazurenko, A. et al. A cold-atom Fermi–Hubbard antiferromagnet. Nature 545 , 462–466 (2017).

Bernien, H. et al. Probing many-body dynamics on a 51-atom quantum simulator. Nature 551 , 579–584 (2017).

Neill, C. et al. Accurately computing electronic properties of a quantum ring. Preprint at https://arxiv.org/abs/2012.00921v2 (2021).

Wang, C. S. et al. Efficient multiphoton sampling of molecular vibronic spectra on a superconducting bosonic processor. Phys. Rev. X 10 , 021060 (2020).

ADS   CAS   Google Scholar  

Arute, F. et al. Quantum supremacy using a programmable superconducting processor. Nature 574 , 505–510 (2019).

Zhong, H.-S. et al. Quantum computational advantage using photons. Science 370 , 1460–1463 (2020).

Giovannetti, V., Lloyd, S. & Maccone, L. Advances in quantum metrology. Nat. Photon . 5 , 222–229 (2011).

Article   ADS   CAS   Google Scholar  

Browaeys, A. & Lahaye, T. Many-body physics with individually controlled Rydberg atoms. Nat. Phys . 16 , 132–142 (2020).

Article   CAS   Google Scholar  

Sachdev, S. Quantum Phase Transitions 2nd edn (Cambridge Univ. Press, 2011).

Samajdar, R., Ho, W. W., Pichler, H., Lukin, M. D. & Sachdev, S. Complex density wave orders and quantum phase transitions in a model of square-lattice Rydberg atom arrays. Phys. Rev. Lett . 124 , 103601 (2020).

Pagano, G. et al. Quantum approximate optimization of the long-range Ising model with a trapped-ion quantum simulator. Proc. Natl Acad. Sci. USA 117 , 25396–25401 (2020).

Article   ADS   CAS   PubMed   PubMed Central   MathSciNet   Google Scholar  

Friis, N. et al. Observation of entangled states of a fully controlled 20-qubit system. Phys. Rev. X 8 , 021012 (2018).

CAS   Google Scholar  

Harris, R. et al. Phase transitions in a programmable quantum spin glass simulator. Science 361 , 162–165 (2018).

Article   ADS   MathSciNet   CAS   PubMed   Google Scholar  

Labuhn, H. et al. Tunable two-dimensional arrays of single Rydberg atoms for realizing quantum Ising models. Nature 534 , 667–670 (2016).

Morgado, M. & Whitlock, S. Quantum simulation and computing with Rydberg qubits. AVS Quantum Sci . 3 , 023501 (2021).

Lienhard, V. et al. Observing the space- and time-dependent growth of correlations in dynamically tuned synthetic Ising models with antiferromagnetic interactions. Phys. Rev. X 8 , 021070 (2018).

Guardado-Sanchez, E. et al. Probing the quench dynamics of antiferromagnetic correlations in a 2D quantum Ising spin system. Phys. Rev. X 8 , 021069 (2018).

Kim, H., Park, Y., Kim, K., Sim, H.-S. & Ahn, J. Detailed balance of thermalization dynamics in Rydberg-atom quantum simulators. Phys. Rev. Lett . 120 , 180502 (2018).

de Léséleuc, S. et al. Observation of a symmetry-protected topological phase of interacting bosons with Rydberg atoms. Science 365 , 775–780 (2019).

Article   ADS   MathSciNet   PubMed   MATH   CAS   Google Scholar  

Keesling, A. et al. Quantum Kibble–Zurek mechanism and critical dynamics on a programmable Rydberg simulator. Nature 568 , 207–211 (2019).

Madjarov, I. S. et al. High-fidelity entanglement and detection of alkaline-earth Rydberg atoms. Nat. Phys . 16 , 857–861 (2020).

Omran, A. et al. Generation and manipulation of Schrödinger cat states in Rydberg atom arrays. Science 365 , 570–574 (2019).

Graham, T. M. et al. Rydberg mediated entanglement in a two-dimensional neutral atom qubit array. Phys. Rev. Lett . 123 , 230501 (2019).

Levine, H. et al. Parallel implementation of high-fidelity multiqubit gates with neutral atoms. Phys. Rev. Lett . 123 , 170503 (2019).

Madjarov, I. S. et al. An atomic-array optical clock with single-atom readout. Phys. Rev. X 9 , 041052 (2019).

Young, A. W. et al. Half-minute-scale atomic coherence and high relative stability in a tweezer clock. Nature 588 , 408–413 (2020).

Schymik, K.-N. et al. Enhanced atom-by-atom assembly of arbitrary tweezers arrays. Phys. Rev. A 102 , 063107 (2020).

Kumar, A., Wu, T.-Y., Giraldo, F. & Weiss, D. S. Sorting ultracold atoms in a three-dimensional optical lattice in a realization of Maxwell’s demon. Nature 561 , 83–87 (2018).

Ohl de Mello, D. et al. Defect-free assembly of 2D clusters of more than 100 single-atom quantum systems. Phys. Rev. Lett . 122 , 203601 (2019).

Barredo, D., Lienhard, V., de Léséleuc, S., Lahaye, T. & Browaeys, A. Synthetic three-dimensional atomic structures assembled atom by atom. Nature 561 , 79–82 (2018).

Barredo, D., de Léséleuc, S., Lienhard, V., Lahaye, T. & Browaeys, A. An atom-by-atom assembler of defect-free arbitrary 2D atomic arrays. Science 354 , 1021–1023 (2016).

Jaksch, D. et al. Fast quantum gates for neutral atoms. Phys. Rev. Lett . 85 , 2208 (2000).

Lukin, M. D. et al. Dipole blockade and quantum information processing in mesoscopic atomic ensembles. Phys. Rev. Lett . 87 , 037901 (2001).

Gardas, B., Dziarmaga, J., Zurek, W. H. & Zwolak, M. Defects in quantum computers. Sci. Rep . 8 , 4539 (2018).

Article   ADS   PubMed   PubMed Central   CAS   Google Scholar  

Zurek, W. H., Dorner, U. & Zoller, P. Dynamics of a quantum phase transition. Phys. Rev. Lett . 95 , 105701 (2005).

Article   ADS   PubMed   CAS   Google Scholar  

Felser, T., Notarnicola, S. & Montangero, S. Efficient tensor network ansatz for high-dimensional quantum many-body problems. Phys. Rev. Lett . 126 , 170603 (2021).

Huang, H.-Y., Kueng, R. & Preskill, J. Predicting many properties of a quantum system from very few measurements. Nat. Phys . 16 , 1050–1057 (2020).

Verresen, R., Lukin, M. D. & Vishwanath, A. Prediction of toric code topological order from Rydberg blockade. Preprint at https://arxiv.org/abs/2011.12310 (2020).

Samajdar, R., Ho, W. W., Pichler, H., Lukin, M. D. & Sachdev, S. Quantum phases of Rydberg atoms on a kagome lattice. Proc. Natl Acad. Sci. USA 118 , e2015785118 (2021).

Article   CAS   PubMed   PubMed Central   Google Scholar  

Semeghini, G. et al. Probing topological spin liquids on a programmable quantum simulator. Preprint at https://arxiv.org/abs/2104.04119 (2021).

Saskin, S., Wilson, J. T., Grinkemeyer, B. & Thompson, J. D. Narrow-line cooling and imaging of ytterbium atoms in an optical tweezer array. Phys. Rev. Lett . 122 , 143002 (2019).

Anderegg, L. et al. An optical tweezer array of ultracold molecules. Science 365 , 1156–1158 (2019).

Liu, L. R. et al. Building one molecule from a reservoir of two atoms. Science 360 , 900–903 (2018).

Turner, C. J., Michailidis, A. A., Abanin, D. A., Serbyn, M. & Papić, Z. Weak ergodicity breaking from quantum many-body scars. Nat. Phys . 14 , 745–749 (2018).

Surace, F. M. et al. Lattice gauge theories and string dynamics in Rydberg atom quantum simulators. Phys. Rev. X 10 , 021041 (2020).

Bluvstein, D. et al. Controlling quantum many-body dynamics in driven Rydberg atom arrays. Science 371 , 1355–1359 (2021).

Article   ADS   CAS   PubMed   MathSciNet   Google Scholar  

Diehl, H. W. The theory of boundary critical phenomena. Int. J. Mod. Phys. B 11 , 3503–3523 (1997).

Article   ADS   Google Scholar  

Bañuls, M. C. et al. Simulating lattice gauge theories within quantum technologies. Eur. Phys. J. D 74 , 165 (2020).

Notarnicola, S., Collura, M. & Montangero, S. Real-time-dynamics quantum simulation of (1 + 1)-dimensional lattice QED with Rydberg atoms. Phys. Rev. Research 2 , 013288 (2020).

Weimer, H., Müller, M., Lesanovsky, I., Zoller, P. & Büchler, H. P. A Rydberg quantum simulator. Nat. Phys . 6 , 382–388 (2010).

Auger, J. M., Bergamini, S. & Browne, D. E. Blueprint for fault-tolerant quantum computation with Rydberg atoms. Phys. Rev. A 96 , 052320 (2017).

Farhi, E., Goldstone, J. & Gutmann, S. A quantum approximate optimization algorithm. Preprint at https://arxiv.org/abs/1411.4028 (2014).

Zhou, L., Wang, S.-T., Choi, S., Pichler, H. & Lukin, M. D. Quantum approximate optimization algorithm: performance, mechanism, and implementation on near-term devices. Phys. Rev. X 10 , 021067 (2020).

Wild, D. S., Sels, D., Pichler, H. & Lukin, M. D. Quantum sampling algorithms for near-term devices. Preprint at https://arxiv.org/abs/2005.14059 (2020).

Scholl, P. et al. Programmable quantum simulation of 2D antiferromagnets with hundreds of Rydberg atoms. Nature https://doi.org/10.1038/s41586-021-03585-1 (2021).

Kim, D. et al. Large-scale uniform optical focus array generation with a phase spatial light modulator. Opt. Lett . 44 , 3178–3181 (2019).

Article   ADS   PubMed   Google Scholar  

Endres, M. et al. Atom-by-atom assembly of defect-free one-dimensional cold atom arrays. Science 354 , 1024–1027 (2016).

Lee, W., Kim, H. & Ahn, J. Defect-free atomic array formation using the Hungarian matching algorithm. Phys. Rev. A 95 , 053424 (2017).

Sheng, C. et al. Efficient preparation of 2D defect-free atom arrays with near-fewest sorting-atom moves. Phys. Rev. Research 3 , 023008 (2021).

Levine, H. et al. High-fidelity control and entanglement of Rydberg-atom qubits. Phys. Rev. Lett . 121 , 123603 (2018).

Bowman, D. et al. High-fidelity phase and amplitude control of phase-only computer generated holograms using conjugate gradient minimisation. Opt. Express 25 , 11692–11700 (2017).

Zupancic, P. et al. Ultra-precise holographic beam shaping for microscopic quantum control. Opt. Express 24 , 13881–13893 (2016).

Beterov, I. I., Ryabtsev, I. I., Tretyakov, D. B. & Entin, V. M. Quasiclassical calculations of blackbody-radiation-induced depopulation rates and effective lifetimes of Rydberg nS, nP , and nD alkali-metal atoms with n  ≤ 80. Phys. Rev. A 79 , 052504 (2009).

Bhattacharjee, S. M. & Seno, F. A measure of data collapse for scaling. J. Phys. Math. Gen . 34 , 6375 (2001).

Article   ADS   CAS   MATH   Google Scholar  

Hasenbusch, M. Monte Carlo study of surface critical phenomena: The special point. Phys. Rev. B 84 , 134405 (2011).

White, S. R. Density matrix formulation for quantum renormalization groups. Phys. Rev. Lett . 69 , 2863 (1992).

White, S. R. Density-matrix algorithms for quantum renormalization groups. Phys. Rev. B 48 , 10345 (1993).

Stoudenmire, E. M. & White, S. R. Studying two-dimensional systems with the density matrix renormalization group. Annu. Rev. Condens. Matter Phys . 3 , 111–128 (2012).

Fishman, M., White, S. R. & Stoudenmire, E. M. The ITensor software library for tensor network calculations. Preprint at https://arxiv.org/abs/2007.14822 (2020).

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Acknowledgements

We thank many members of the Harvard AMO community, particularly E. Urbach, S. Dakoulas and J. Doyle for enabling safe and productive operation of our laboratories during 2020. We thank H. Bernien, D. Englund, M. Endres, N. Gemelke, D. Kim, P. Stark and A. Zibrov for discussions and experimental help. We acknowledge financial support from the Center for Ultracold Atoms, the US National Science Foundation, the Vannevar Bush Faculty Fellowship, the US Department of Energy (DE-SC0021013 and DOE Quantum Systems Accelerator Center, contract no. 7568717), the Office of Naval Research, the Army Research Office MURI and the DARPA ONISQ programme. T.T.W. acknowledges support from Gordon College. H.L. acknowledges support from the National Defense Science and Engineering Graduate (NDSEG) fellowship. G.S. acknowledges support from a fellowship from the Max Planck/Harvard Research Center for Quantum Optics. D.B. acknowledges support from the NSF Graduate Research Fellowship Program (grant DGE1745303) and the Fannie and John Hertz Foundation. W.W.H. is supported by the Moore Foundation’s EPiQS Initiative grant no. GBMF4306, the NUS development grant AY2019/2020, and the Stanford Institute of Theoretical Physics. S.C. acknowledges support from the Miller Institute for Basic Research in Science. R.S. and S.S. were supported by the US Department of Energy under grant DE-SC0019030. The DMRG calculations were performed using the ITensor Library 73 . The computations in this paper were run on the FASRC Cannon cluster supported by the FAS Division of Science Research Computing Group at Harvard University.

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Sepehr Ebadi, Tout T. Wang, Harry Levine, Alexander Keesling, Giulia Semeghini, Ahmed Omran, Dolev Bluvstein, Rhine Samajdar, Wen Wei Ho, Subir Sachdev, Markus Greiner & Mikhail D. Lukin

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Contributions

S.E., T.T.W., H.L., A.K., G.S, A.O. and D.B. contributed to building the experimental set-up, performed the measurements and analysed the data. Theoretical analysis was performed by R.S., H.P., W.W.H. and S.C. All work was supervised by S.S., M.G., V.V. and M.D.L. All authors discussed the results and contributed to the manuscript.

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Correspondence to Mikhail D. Lukin .

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M.G., V.V. and M.D.L. are co-founders and shareholders of QuEra Computing. A.K. and A.O. are shareholders of QuEra Computing. All other authors declare no competing interests.

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Extended data figures and tables

Extended data fig. 1 large arrays of optical tweezers..

The experimental platform produces optical tweezer arrays with up to ~1,000 tweezers and ~50% loading probability per tweezer after 100 ms of magneto-optical trap loading time. a , Camera image of an array of 34 × 30 tweezers (1,020 traps), including aberration correction. b , Sample image of random loading into this tweezer array, with 543 loaded atoms. Atoms are detected on an EMCCD camera with fluorescence imaging.

Extended Data Fig. 2 Correcting for aberrations in the SLM tweezer array.

The aberration correction procedure uses the orthogonality of Zernike polynomials and the fact that correcting aberrations increases tweezer light shifts on the atoms. To independently measure and correct each aberration type, Zernike polynomials are added with variable amplitude to the SLM phase hologram, with values optimized to maximize tweezer light shifts. a , Two common aberration types: horizontal coma (upper) and primary spherical (lower), for which ~50 milliwaves compensation on each reduces aberrations and results in higher-depth traps. b , Correcting for aberrations associated with the 13 lowest-order Zernike polynomials. The sum of all polynomials with their associated coefficients gives the total wavefront correction (RMS ~70 milliwaves) for our optical system, which is summed with the optical tweezer hologram on the SLM. c , Trap depths across a 26 × 13 trap array before and after correction for aberrations. Aberration correction results in tighter focusing (higher trap light shift) and improved homogeneity. Trap depths are measured by probing the light shift of each trap on the \(|5{S}_{1/2},F=2\rangle \to |5{P}_{3/2},F{\prime} =2\rangle \) transition. d , Aberration correction also results in higher and more homogeneous trap frequencies across the array. Trap frequencies are measured by modulating tweezer depths at variable frequencies, resulting in parametric heating and atom loss when the modulation frequency is twice the radial trap frequency. The measurement after correction for aberrations shows a narrower spectrum and higher trap frequencies (averaged over the whole array).

Extended Data Fig. 3 Rearrangement protocol.

a , Sample sequence of individual rearrangement steps. There are two pre-sorting moves (1, 2). Move 3 is the single ejection move. Moves 4–6 consist of parallel vertical sorting within each column, including both upward and downward moves. The upper panel illustrates the frequency spectrum of the waveform in the vertical and horizontal AODs during these moves, with the underlying grid corresponding to the calibrated frequencies that map to SLM array rows and columns. b , Spectrograms representing the horizontal and vertical AOD waveforms over the duration of a single vertical frequency scan during a realistic rearrangement procedure for a 26 × 13 array. The heat-maps show frequency spectra of the AOD waveforms over small time intervals during the scan.

Extended Data Fig. 4 Generating homogeneous Rydberg beams.

a , Measured Gaussian-beam illumination on the SLM for shaping the 420-nm Rydberg beam. A Gaussian fit to these data is used as an input for the hologram optimization algorithm. b , Measured wavefront error through our optical system (after correction), showing a reduction of aberrations to λ /100. c , Computer-generated hologram for creating the 420-nm top-hat beam. d , Measured light intensity of the 420-nm top-hat beam (top), and the cross-section along where atoms will be positioned (bottom). Vertical lines denote the 105-μm region where the beam should be flat. e , Using the measured top-hat intensity, a phase correction is calculated for adding to the initial hologram. f , Resulting top-hat beam after feedback shows considerably improved homogeneity. pk–pk, peak to peak.

Extended Data Fig. 5 Characterizing microwave-enhanced Rydberg detection fidelity.

The effect of strong microwave (MW) pulses on Rydberg atoms is measured by preparing atoms in \(|g\rangle \) , exciting to \(|r\rangle \) with a Rydberg π-pulse, and then applying the microwave pulse before de-exciting residual Rydberg atoms with a final Rydberg π-pulse. (The entire sequence occurs while tweezers are briefly turned off.) a , Broad resonances are observed with varying microwave frequency, corresponding to transitions from \(|r\rangle \)  =  \(|70S\rangle \) to other Rydberg states. Note that the transitions to \(|69P\rangle \) and \(|70P\rangle \) are in the range of 10–12 GHz, and over this entire range there is strong transfer out of  \(|r\rangle \) . Other resonances might be due to multiphoton effects. b , With fixed 6.9-GHz microwave frequency and varying pulse time, there is a rapid transfer out of the Rydberg state on the timescale of several nanoseconds. Over short timescales, there may be coherent oscillations that return population back to \(|r\rangle \) , so a 100-ns pulse is used for enhancement of loss signal of \(|r\rangle \) in the experiment.

Extended Data Fig. 6 Coarse-grained local staggered magnetization.

a , Examples of Rydberg populations n i after a faster (top) and slower (bottom) linear sweep. b , Corresponding coarse-grained local staggered magnetizations m i clearly show larger extents of antiferromagnetically ordered domains (dark blue or dark red) for the slower sweep (bottom) than for the faster sweep (top), as expected from the Kibble–Zurek mechanism. c , Isotropic correlation functions \({G}_{m}^{(2)}\) for the corresponding coarse-grained local staggered magnetizations after a faster (top) or a slower (bottom) sweep. d , As a function of radial distance, correlations \({G}_{m}^{(2)}\) decay exponentially with a length scale corresponding to the correlation length ξ . The two decay curves correspond to faster (orange) and slower (blue) sweeps.

Extended Data Fig. 7 Extracting the quantum critical point.

a , The mean Rydberg excitation density \(\langle n\rangle \) versus detuning Δ / Ω on a 16 × 16 array. The data are fitted within a window (dashed lines) to a cubic polynomial (red curve) as a means of smoothing the data. b , The peak in the numerical derivative of the fitted data (red curve) corresponds to the critical point Δ c / Ω  = 1.12(4) (red shaded regions show uncertainty ranges, obtained from varying fit windows). In contrast, the point-by-point slope of the data (grey) is too noisy to be useful. c , Order parameter \(\mathop{ {\mathcal F} }\limits^{ \sim }({\rm{\pi }},{\rm{\pi }})\) for the chequerboard phase versus Δ / Ω measured on a 16 × 16 array with the value of the critical point from b superimposed (red line), showing the clear growth of the order parameter after the critical point. d , DMRG simulations of  \(\langle n\rangle \) versus Δ / Ω on a 10 × 10 array. For comparison against the experimental fitting procedure, the data from numerics are also fitted to a cubic polynomial within the indicated window (dashed lines). e , The point-by-point slope of the numerical data (blue curve) has a peak at Δ c / Ω  = 1.18 (blue dashed line), in good agreement with the results (red dashed line) from both the numerical derivative of the cubic fit on the same data (red curve) and the result of the experiment. f , DMRG simulation of \(\mathop{ {\mathcal F} }\limits^{ \sim }({\rm{\pi }},{\rm{\pi }})\) versus Δ / Ω , with the exact quantum critical point from numerics shown (red line).

Extended Data Fig. 8 Optimization of data collapse.

a , Distance D between rescaled correlation length \(\mathop{\xi }\limits^{ \sim }\) versus \(\mathop{\varDelta }\limits^{ \sim }\) curves depends on both the location of the quantum critical point Δ c / Ω and on the correlation length critical exponent ν . The independently determined Δ c / Ω (blue line, with uncertainty range in grey) and the experimentally extracted value of ν (dashed red line, with uncertainty range corresponding to the red shaded region) are marked on the plot. b , Our determination of ν (red) from data collapse around the independently determined Δ c / Ω (blue) is consistent across arrays of different sizes. c – e , Data collapse is clearly better at the experimentally determined value ( ν  = 0.62) as compared with the mean-field ( ν  = 0.5) or the (1 + 1)D ( ν  = 1) values. The horizontal extent of the data corresponds to the region of overlap of all rescaled datasets.

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Ebadi, S., Wang, T.T., Levine, H. et al. Quantum phases of matter on a 256-atom programmable quantum simulator. Nature 595 , 227–232 (2021). https://doi.org/10.1038/s41586-021-03582-4

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Published : 07 July 2021

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DOI : https://doi.org/10.1038/s41586-021-03582-4

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Experiment 227

• Edit source

Designation #: 227

Danger Level: Assistant

• 1 Appearance
• 2 Mechanics
• 5 Additional Notes

Appearance [ ]

Experiment 227 is a short creature with light blue colored skin. Experiment 227's head is wide with two small cat-like eyes. Experiment 227 has a nervous expression with two small buck teeth. He has blue spots all over his body, and he wears a purple beret. Experiment 227 has no fingers or toes, and wears a peach colored shirt that says "KISS the ARTIST" on it. Lastly, Experiment 227 holds a pencil in his right hand.

Mechanics [ ]

When Experiment 227 is activated, he can be found in a random classroom in the schoolhouse (usually standing in a corner). When the player walks up to him, text will appear at the top of the screen that says "What do you want 227 to draw?", and buttons with a poorly drawn BSODA, Zesty Bar, Yellow Door Lock, and Safety Scissors will appear under it. If the player clicks on any of the buttons, Experiment 227 will draw the same poorly drawn item that the player chose. The item can then be taken and used.

The items that Experiment 227 draws are less effective versions of their original counterparts, and but can still save the player if they are in danger.

• Sketched BSODA: When shot at an NPC, the spray will disappear after 5 seconds.
• Sketched Zesty Bar: The player's stamina will be boosted for a shorter amount of time.
• Sketched Yellow Door Lock: Will only stick to a door for 20 seconds.
• Sketched Safety Scissors: Has a 50/50 chance of breaking when being used.

Gallery [ ]

Additional Notes [ ]

• Experiment 227's name is based off of Leonardo Da Vinci , a famous artist.
• 1 Experiment 047
• 2 Experiment 001
• 3 Experiment 347

Lilo & Stitch: The Series #227

Lilo & Stitch: The Series » Lilo & Stitch: The Series #227 - Snafu: Experiment 120 released by Disney on June 23, 2006.

Summary Short summary describing this episode.

Snafu: Experiment 120 last edited by cloudguy on 01/30/22 02:41AM View full history

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Deviation Actions

Lilo and Stitch - Experiment 227 Butter

Description.

• Season 1 Experiments
• Ultimate Monster Experiment
• Experiments Activated On-Screen
• Talking experiments
• Transmutated Experiments
• Lilo & Stitch: The Series Experiments
• Experiments Deactivated On-Screen

Experiment 627 is an illegal genetic experiment created by Jumba Jookiba , and the first experiment to be created on Earth with limited alien technology. He serves as a minor antagonist in Lilo & Stitch: The Series , and is designed to be a better prototype of Stitch . Unlike the other known experiments (with the exception of Leroy ), it is impossible for him to be rehabilitated, so he was dehydrated without ever being given a name or one true place.

• 1.1 Stitch! The Movie
• 1.2 Lilo & Stitch: The Series
• 1.3 Leroy & Stitch
• 1.4 The Origin of Stitch
• 1.5 Stitch! anime
• 2 Personality
• 3.1 Physical appearance
• 3.2 Special abilities
• 3.3 Weaknesses

Background and appearances [ ]

Experiment 627 was the 627th genetic experiment created by Jumba , and the second to be made without Hämsterviel 's funding. He was designed to have all of Stitch 's powers, including those of 20 other experiments, with none of their weaknesses.

Stitch! The Movie [ ]

627's creation was oddly foreshadowed near the end of the film. When Pleakley pointed out that the remaining 623 experiments were evil, Jumba stated that said experiments could be turned good (like Stitch and Sparky beforehand), and they wouldn't be bad anymore. He then whispered that he was fixing for 627. Apparently, Jumba had been secretly planning on creating an Experiment 627 for quite some time.

Lilo & Stitch: The Series [ ]

627 moments after his activation

In the episode " 627 ", Stitch cleverly defeated and rehabilitated Experiment 515 in only two minutes, but grew egotistical when he kept bragging about how great and special he was.

Stitch then began acting rudely towards Lilo and everyone else at dinnertime and threw a plate of cranberry sauce in Jumba 's face. This angered him enough that he resolved to put Stitch in his place, resulting in the creation of Experiment 627.

Once Jumba had finished creating 627 and activated the latter, 627 escaped his container and fled into the jungle, but not before Pleakley discovered him on Jumba's ship . 627 soon after came across Experiment 625 and attacked, drooling on him and eating his sandwich.

627 with Gantu

Seeing 627 as an accomplice for Gantu in catching the other experiments, Reuben took 627 back to Gantu's ship , where 627 demonstrated his incredible powers to Gantu on Reuben. Impressed, Gantu and 627 arrived at a farmhouse the next day to capture Experiment 603 . 627 easily defeated Stitch, and the former and Gantu escaped with 603.

Following this, 627 began to easily beat Stitch at capturing other experiments (most notably 567 , 390 and 607 ), and relentlessly bullied and tormented Stitch and Reuben, much to their indignity.

Eventually, Gantu decided to use 627 to conquer the galaxy by himself, even quitting his job of working for Hämsterviel . When Reuben insulted Gantu's take-over-the-galaxy uniform, 627 blasted Reuben with Gantu's blaster , afterwards laughing an unusually large amount. Reuben then slipped on a stray drop of plasma, causing 627 to excessively laugh even more. Gantu condemned 627's laughter, while Reuben took notice of this.

Reuben later telephoned Lilo and informed her of what he had discovered, wanting to get rid of 627 as much as Lilo and Stitch did. After Reuben's report, Jumba clarified that since he had given 627 extra of everything , he might have given him an extra-large sense of humor as well.

627 about to battle Stitch

Shortly after, Lilo and Stitch (with some help from Reuben) lured 627 and Gantu to the middle of the town for a final battle. Stitch was able to defeat 627 by making a fool of himself during the battle and using the latter's abnormally large sense of humor against him.

Eventually, 627 laughed himself into unconsciousness and was then deactivated by Lilo using a home food dehydrator she ordered from a TV commercial earlier. After he was dehydrated, Lilo took his pod and placed it in her pocket for safekeeping.

In " Remmy ", 627 was one of the experiments in Lilo's dream. This is the only time he is ever seen as good.

627 was seen on a computer screen in " Ace ", posing as an evil creation of Jumba's as part of a hoax to fool Mortlegax , the head of E.G.O. industries.

Leroy & Stitch [ ]

627 was briefly mentioned by Jumba in Leroy & Stitch , suggesting that he had forgotten that he even made a 627 when, oddly enough, Gantu remembered while thinking about what to name the newly-created experiment .

The Origin of Stitch [ ]

627 was one of the experiments that were gliding on the screen, but he was numbered 613 instead of 627.

Stitch! anime [ ]

627 appeared in Season 2 of the Stitch! anime episode " The Return of 627 ". Hämsterviel had not only reactivated 627, but also enhanced his vocabulary (thus enabling him to speak in complete sentences instead of just repeating the word "evil" over and over) as well as his power.

As part of the alien rodent's latest plan, 627 disguised himself as a prince to woo Angel and lure her into a castle in the forest (actually a giant rocket waiting to be blasted into space). Angel was just the bait for Stitch , who took it and was captured and frozen solid by the fake prince. Stitch breaks out, but 627 reveals his true identity and who he's working for. He then seals Angel in a net against the wall and begins to fight Stitch, though not before freezing Gantu as well.

Meanwhile, Yuna , Jumba , Pleakley , and BooGoo follow Stitch to the castle and arrive just as 627 was about to deal the finishing blow. Due to them falling in and squishing each other, 627 begins laughing, immediately unfreezing Gantu and reminding everyone of 627's one weakness. Everyone then attempts to get 627 to laugh by dancing. Eventually, it works and 627 laughs into unconsciousness again. He is then sealed in a container, but Hämsterviel activates the rocket (after Gantu and Reuben escape with Angel) and blocks all the exits with an alloy not even Stitch can break through. All seems lost until 627 wakes up, breaks out of the container, and easily melts through the alloy, allowing everyone to escape.

Later, the vehicle Hämsterviel tried to use to carve the Spiritual Stone into small pieces goes out of control and collides with Gantu's space scooter, leaving it and the still-captured Angel pinned to the front. Stitch jumps on to save her, but the ship is about to crash into a cliff. Stitch doesn't seem to be able to stop it and he and Angel are about to be crushed, but they are rescued by 627, who picks up Hämsterviel's ship and throws it into the distance, destroying it. Stitch thanks him for saving him twice and calls him "cousin" (finally accepting him into the ʻohana ). 627 simply hops on Gantu's scooter and says that he's welcome, but next time he won't be so lucky and if anyone's going to destroy Stitch, it's him. He then flies the scooter into space, not to be seen again.

Although not technically an appearance, 627 was mentioned in the Season 2 anime episode " Sprout 2.0 ". As stated by Hämsterviel and Reuben, Sprout 's son was "infused with DNA of Experiment 627, or was it 672/726?", referencing how experiments are often mislabeled throughout the franchise with the throwaway excuse that "Jumba's database is untidy."

Personality [ ]

627 is a slobbering, vicious, cruel bully and vile minion. He is shown to be "extra-evil" and possesses a very strong sense of humor. He constantly torments and abuses others, often out of boredom. He is also incapable of rehabilitation and can only say, "Evil!" for reasons unknown. He shows that he thinks of nothing more than to cause all kinds of destruction.

There is little sense of morals within this experiment. He chooses to be evil for the sake of being so, and also wants to ruin everybody's happiest (or even saddest) moments. 627 would do anything under the category of evil. As one can tell, he is quite hyperactive (very amusingly so). He also has a huge sense of nasty humor, laughing the biggest laugh at the littlest joke, mostly practical jokes or something bad that happens to others. His laughter is also his weakness, however. When he starts laughing, it is usually hard for him to stop, leaving him wide open to mostly anything.

627 doesn't seem to normally kill things. He takes more joy out of bullying or undermining others rather than outright killing. He also tends to try and make fun of anyone, strong or weak, and only attacks those who either annoy him or fight back against his evil. Another added softness to him is that he will sometimes ally himself with other evildoers to do their bidding. But even then, 627 is quick to betraying or subverting a villain's plans simply out of the fun of it.

Biology [ ]

Physical appearance [ ].

Experiment 627 is very much similar in appearance to his predecessor experiment, Stitch, only with some noticeable differences. He resembles a koala-like creature with an elongated cone-shaped head with a large knot on the top and a wiry body. He has red fur, lighter tan fur color on his belly and chest, brown patch of hair on his back, purple nose, and dead-on black eyes. His ears are long and pointed upward, and stick up straighter than Stitch's too, almost like devil horns, with two notches at the top, tan insides and brown tips at the back, and his claws/toes are black. He also has a Xenomorph -like extendable mouth, making one ugly and horrific "cousin".

In the Stitch! anime, 627 disguises himself as a prince in order to woo Angel . In this disguise, 627 wears a light blue coat, dark blue pants, white socks, a white cape and a wig of blond hair. He also wears a mask able to open up that sports blue eyes (though they might as well be lenses meant to deceive).

Special abilities [ ]

627 has all of Stitch's abilities, doesn't sink in water, and cannot be turned to good. He also has the powers of 20 other experiments and, according to Jumba, makes good tamales too.

His other powers include:

• Enhanced physical attributes: Like most other experiments, 627 is very high in endurance, agility, and most notably, strength. He can lift things that weigh thousands of tons heavier than himself, and can even outmatch Stitch's strength. 627 also has a mind close enough to a supercomputer and has extra retractable limbs (to a maximum of six and extra head). He is an expert in all kinds of evil fields, with infiltration and sabotage as his specialties. He possesses extensive martial arts training and impressive fitness and agility, rivaling the skills displayed by his nemesis Stitch. His attack is also enhanced by sharp claws on his paws, and on occasion, he has used his sharp claws and outstretched hands to similar effect.
• Plasma blasts: From unknown experiment (possibly either from Plasmoid or Splodyhead ); 627 can generate green plasma that melts anything it touches. The emission type can range from concentrated laser-like blasts from his hands to regurgitating corrosive and condensed plasma from his mouth. He can also fire it from his eyes like a laser.
• Frost breath: From Slushy ; 627 is able to freeze enemies.
• Telekinesis: From unknown experiment; 627 can create a telekinetic field of that inhibits the majority of a victim's body movement (only their eyes can move). The field is moved by his head and can be fired in the forms of energy blasts and concentrated beams.
• Electrokinesis: From Sparky ; 627 has the power to create his own forms of electrical energy. He can absorb other forms of electricity and use it tenfold. He generally uses this power as an offensive attack, but it can still be used for destroying machinery, electronics, etc., through ways like blackouts, malfunctions, etc.
• Fire breath: From unknown experiment; seen only in Stitch!
• Shooting spikes: From Spike ; seen only in Stitch!
• Rotating claws: From Deforestator ; seen only in Stitch!
• Diamond power: From unknown experiment; seen only in Stitch! . 627 can create and control diamond-like powers. He was able to encase Stitch in diamond by biting him.
• Energy web: From unknown experiment; seen only in Stitch!
• Creating illusions: From unknown experiment; seen only in Stitch!
• Claw growth: From unknown experiment; seen only in Stitch!

Weaknesses [ ]

627's only apparent weakness is his overactive and infantile sense of humor, causing him to laugh uncontrollably. First, his powers begin to fade, and then he goes into a state of cataplexy and collapses.

• Leroy was not rehabilitated either, and all we know about 628 is that it exists and its pod color.
• He along with 628 are also the only two illegal genetic experiments that Jumba created in his spaceship on Earth using limited alien technology, since Jumba had lost access to his laboratory following his arrest at the beginning of the original film and would not get it back until the events of Leroy & Stitch .
• Ironically, at the start of the original film, Stitch's spacesuit is red to symbolize Stitch's original evil and destructive nature before being adopted by Lilo.
• Despite Jumba saying it was impossible to deactivate 627, he was able to deactivate the other 625 experiments that were created before 627, excluding Stitch. However, he likely meant that there was no possible method on Earth to dehydrate the experiments, given the limited advanced technology.
• In said parody, when 627 and the other experiments are looking up at the ceiling, 627 is colored blue and Stitch is colored red due to a coloring error.
• 627's manner of defeat is similar to the Toon Patrol from Who Framed Roger Rabbit , though while most of the Toon Patrol die from laughter, 627 just passes out long enough to be dehydrated.
• 627's pod color is blue.
• 627 is one of the three known experiments that has more than one head, the other two being Forehead and Swapper , having four heads and two heads respectively. However, 627 usually only appears with one head, but with the second head being retractable, similar to how some experiments possess a set of retractable arms. Furthermore, 627's second head only appeared once in a brief scene in his debut and did not appear in the Stitch! anime.
• In Leroy & Stitch , Jumba had apparently forgotten about him when he suggested to call Leroy "627", only for Gantu to remind him that he already made an Experiment 627.
• Even though he was still dehydrated into pod form at the time of Leroy & Stitch , two yellow versions of him appear in the background cheering after the " Aloha ʻOe " performance in the film. It is most likely that the production staff reused 627's design to fill the crowd of experiments in that scene to cut production costs and recolored him to hide that fact, much like they did with several other experiments during the climax at Aloha Stadium . (In fact, in the same scene in question, duplicates of several other experiments – many of whom are not even recolored – can also be seen cheering.)
• The anime episode " The Return of 627 " is the only time 627 calls Stitch "cuz", referring to that he sees him as family, even though 627 said he will destroy Stitch next time.
• 627 may have also been mentioned in Season 3 of the anime episode " Ace's Back! ". After Ace makes his appearance, he is seen looking through a book of his exploits and goes on to explain some of the heroic deeds he has accomplished in the recent past. He then illustrates, "And that's not to mention the mayhem caused by all the experiments Hämsterviel has transmuted into his evil minions." One of the silhouettes Ace is fighting looks very similar to 627 with the upward pointed ears and six arms.
• He is one of the few experiments that are actually villains, along with Cyber, Chopsuey , Leroy and his clones , and Dark End , while all the other experiments were following their primary function.

Gallery [ ]

•

• • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • ( ) • • • • • • • • • • • • • • • • • • • • • • • • • • • • • ( ) Other • • ( ) • 1 Angel (624) 2 Tantalog language 3 Reuben (625) Test: Cell Bio Exam 2 Ch 16&19 HW Q's 13 multiple choice questions. Term BiP is found in high concentration in the lumen of the ER but is not present in significant concentrations elsewhere in the cell. How do you think this condition is established and maintained? Choose matching definition Bip is degraded in the lysosomes due to lack of kdel sequence. Bip is secreted out of the cell through exocytosis. Bip is actively transported to the golgi apparatus for processing. BiP contains a KDEL sequence, causing it to be retained in the ER. Don't know? 1 of 13 Term If the gene encoding BiP acquires a mutation that disrupts the protein's binding site for hydrophobic amino acids, what kind of impact might this have on the cell? Choose matching definition In the absence of SRP and ER membranes, a prolactin precursor molecule is synthesized. The unfolded and misfolded polypeptides would aggregate with each other, forming insoluble deposits. Neither The mutation would lead to increased secretion of bip from the cell. Don't know? 2 of 13 Term How might you explain the discrepancy between the normal length of prolactin (199 amino acids) and the length of the polypeptide synthesized in your experiment (227 amino acids)? Choose matching definition In the absence of SRP and ER membranes, a prolactin precursor molecule is synthesized. The experiment caused a mutation in the prolactin receptor, altering its length. The experiment led to The deletion Of 28 amino acids from the prolactin gene. The experiment resulted in the fusion of prolactin with another hormone. Don't know? 3 of 13 Definition SRP binds to the ER signal sequence of the newly forming polypeptide chain and halts protein synthesis, thereby preventing the chain from growing beyond 70 amino acids. Inside cells, this blockage will normally be maintained until the SRP binds the ribosome to the ER membrane. Without this blockage, a complete prolactin chain might be produced by cells and released into the cytosol, rather than being transported into the ER lumen. Choose matching term BiP is found in high concentration in the lumen of the ER but is not present in significant concentrations elsewhere in the cell. How do you think this condition is established and maintained? The imported protein enters the organelle through a protein pore that consists of more than two dozen proteins and is large enough to be readily seen with the electron microscope. (nuclear import, mitochondrial import, both, or neither) You perform a third experiment, in which you add both SRP and ER membrane vesicles to your protein-synthesizing system, and find that translation of the prolactin mRNA now produces a polypeptide 199 amino acids long. How can you explain this result? Where would you expect to find this polypeptide? You perform a second experiment, in which you add SRP to your cell-free protein-synthesizing system, and find that translation stops after a polypeptide about 70 amino acids long has been produced. How can you explain this result? Can you think of any purpose this phenomenon might serve for the cell? Don't know? 4 of 13 Definition In the presence of ER membrane vesicles, the SRP binds the mRNA-ribosome complex to the ER membrane, where signal peptidase cleaves the ER signal sequence from the newly-forming prolactin chain as it moves across the ER membrane. Removal of the ER signal sequence reduces the length of the final polypeptide from 227 amino acids to 199 amino acids. The final polypeptide chain is released into the ER lumen. Choose matching term The imported protein enters the organelle through a protein pore that consists of more than two dozen proteins and is large enough to be readily seen with the electron microscope. (nuclear import, mitochondrial import, both, or neither) How might you explain the discrepancy between the normal length of prolactin (199 amino acids) and the length of the polypeptide synthesized in your experiment (227 amino acids)? You perform a third experiment, in which you add both SRP and ER membrane vesicles to your protein-synthesizing system, and find that translation of the prolactin mRNA now produces a polypeptide 199 amino acids long. How can you explain this result? Where would you expect to find this polypeptide? You perform a second experiment, in which you add SRP to your cell-free protein-synthesizing system, and find that translation stops after a polypeptide about 70 amino acids long has been produced. How can you explain this result? Can you think of any purpose this phenomenon might serve for the cell? Don't know? 5 of 13 Term The polypeptide to be transported into the organelle has a specific short stretch of amino acids that targets the polypeptide to the organelle. (nuclear import, mitochondrial import, both, or neither) Choose matching definition both mitochondrial import neither nuclear import Don't know? 6 of 13 Term The signal sequence is always at the polypeptide's N-terminus and is cut off by a peptidase within the organelle. (nuclear import, mitochondrial import, both, or neither) Choose matching definition peroxisome import nuclear import mitochondrial import alternative sorting model Don't know? 7 of 13 Term The signal sequence is recognized and bound by a receptor protein in the organelle's outer membrane. (nuclear import, mitochondrial import, both, or neither) Choose matching definition mitochondrial import alternative sorting model nuclear import peroxisome import Don't know? 8 of 13 Term ATP hydrolysis is known to be required for the translocation process. (nuclear import, mitochondrial import, both, or neither) Choose matching definition alternative sorting model mitochondrial import peroxisome import nuclear import Don't know? 9 of 13 Term GTP hydrolysis is known to be required for the translocation process. (nuclear import, mitochondrial import, both, or neither) Choose matching definition nuclear import mitochondrial import growth factor importin Don't know? 10 of 13 Term Chaperone proteins are involved during translocation of the protein. (nuclear import, mitochondrial import, both, or neither) Choose matching definition peroxisome import mitochondrial import alternative sorting model nuclear import Don't know? 11 of 13 Definition neither Choose matching term Chaperone proteins are involved during translocation of the protein. (nuclear import, mitochondrial import, both, or neither) The imported protein enters the organelle through a protein pore that consists of more than two dozen proteins and is large enough to be readily seen with the electron microscope. (nuclear import, mitochondrial import, both, or neither) The imported protein is transported in a membranous vesicle prior to import. (nuclear import, mitochondrial import, both, or neither) The polypeptide to be transported into the organelle has a specific short stretch of amino acids that targets the polypeptide to the organelle. (nuclear import, mitochondrial import, both, or neither) Don't know? 12 of 13 Term The imported protein enters the organelle through a protein pore that consists of more than two dozen proteins and is large enough to be readily seen with the electron microscope. (nuclear import, mitochondrial import, both, or neither) Choose matching definition nuclear import importin mitochondrial import growth factor Don't know? 13 of 13 224 IMAGES Physics 227: Ultrasound experiment w/ condom Experiment 227 Quantum scalar wave imprinting Eksperimen#227: Menulis pake magnet #experiment #fisika #lifehacks Experiment 227 ACHM 227 Experiment 6 PreLab Lecture Experiment 227 VIDEO Science Experiment By Ak sir Atmosphere kya hai 🔭🧪 Why Is a Freezer Harder To Open The Second Time? (Powered By Anker SOLIX C1000) Matchstick reaction part 1, rocket vs machiesh experiment#amazingfacts @YouTube #500subs #trending Excess நம்ப வீட்டு தீபாவளி கொண்டாட்டம் The Machine to Kill Bad People (1952) by Roberto Rossellini, Clip: Celestino re-photographs a mule COMMENTS Butter (227) Butter, also known as Experiment 227, is an illegal genetic experiment created by Jumba Jookiba and a character in the Lilo & Stitch franchise. He is designed to batter through thick doors and barricades. Experiment 227 was the 227th genetic experiment created by Jumba with Hämsterviel's funding. He was designed to batter through thick doors and barricades. 227 and the other first 624 ... Experiment 227: Butter Warning: Experiment 227 Activated! Primary Function: Living Battering Ram This big lummox may be so, but be not fool-ed. 227's main purpose is to charge into things at such an alarming speed as to break down solid titanium! His design was inspired by two prehistoric creatures; the Woolly Rhino and the Mammoth, and is as strong as the two combined! As for his name, it was supposed to be 'Batter ... Experiment 227: Butter Pod Color: Green Gender: Male Voice Actor: Bill Fagerbakke Special Abilities: This big lummox may be so, but be not fool-ed. 227's main purpose is to charge into things at such an alarming speed as to break down solid titanium! His design was inspired by two prehistoric creatures; the Woolly Rhino and the Mammoth, and is as strong as the two combined! As for his name, it was supposed to be ... Butter (Experiment 227) Butter, a.k.a. Experiment 227, is an illegal alien experiment created by Jumba Jookiba. He is designed to be able to batter through thick doors and barricades. His one true place is with the police as a battering ram and in jumba's custody. Butter is a large tan mammoth-like creature with a large head, two tiny little antennae, a big round green nose instead of trunk, green markings on his ... Snooty (277) Snooty, also known as Experiment 277, is an illegal genetic experiment created by Jumba Jookiba and a character in the Lilo & Stitch franchise. He is designed to mine and enrich Snootonium, a rare intergalactic energy source that becomes unstable and dangerous once enriched. Luckily, there is none on Earth, which Gantu sees as no reason to capture Snooty, only doing so under Hämsterviel's ... Lilo & Stitch This experiment's design was first shown on the Lilo & Stitch DVD's "Create Your Own Alien Experiment" bonus feature game, ... X-227: Butter — A large tan mammoth-like creature with two tiny little antennae, a big round green nose instead of a trunk, green markings on his back, legs at the middle of his torso with external toes, a big hump ... Wormhole (272) Wormhole, also known as Experiment 272, is an illegal genetic experiment created by Jumba Jookiba and a character in the Lilo & Stitch franchise. He is designed to generate portals to parallel universes. He also has advanced language programming to assist him as he traverses alternate realities. Jumba implanted a tracking device so that he would be able to locate Wormhole in whatever universe ... Experiment 227 Experiment 227 - Butter. Primary Function : Designed to break through doors and barricades. Experiment 227 can batter through thick doors by using his tusks and large head. Experiment 227 is able to calculate the exact amount of force required to break down anything in its path. One True Place : With the police as a battering ram. Quantum phases of matter on a 256-atom programmable quantum ... Linear sweeps are done from Δ = −16 MHz to 14 MHz ( Δ / Ω = −3.7 to 3.3) at sweep rates s = 15, 21, 30, 42, 60, 85 and 120 MHz μs −1. Data for locating the quantum critical point ... Experiment 227: CAD Workstation Experiment 227 is a CAD workstation, designed around a 12-core i7-12700K processor and an RTX A4000 16GB video card. General System Design. This build is designed around a 12-core i7-12700K processor and an RTX A4000 16GB video card. Software Workload/Customer Need. Experiment 227 Designation #: 227 Danger Level: Assistant Experiment 227 is a short creature with light blue colored skin. Experiment 227's head is wide with two small cat-like eyes. Experiment 227 has a nervous expression with two small buck teeth. He has blue spots all over his body, and he wears a purple beret. Experiment 227 has no fingers or toes, and wears a peach colored shirt that says "KISS the ... Lilo & Stitch: The Series #227 Lilo & Stitch: The Series » Lilo & Stitch: The Series #227 - Snafu: Experiment 120 released by Disney on June 23, 2006. Snafu: Experiment 120 last edited by cloudguy on 01/30/22 02:41AM View full ... Lilo and Stitch dlee1293847 on DeviantArt https://www.deviantart.com/dlee1293847/art/Ben-10-Omniverse-Skurd-First-Appearance-970704212 dlee1293847 Lake 227 Lake 227 is one of 58 lakes located in the Experimental Lakes Area ... In the culmination of an experiment spanning over 37 years in lake 227, American limnologist David W. Schindler suggested that the level of phosphorus is the dominant factor in controlling eutrophication, ... Tickle-Tummy (275) Tickle-Tummy, also known as Experiment 275, is an illegal genetic experiment created by Jumba Jookiba and a character in the Lilo & Stitch franchise. She is designed to tickle anyone into submission, rendering opponents helpless with laughter; they sometimes even cause an accident in the process. She was captured by Gantu but was rescued in "Snafu". Experiment 275 was the 275th genetic ... MSE 227L MSE 227 Lab Report - Experiment 4. Other 50% (4) 4. Experiment 4 MSE 227 LAB. Assignments None. 7. 9-Corrosion - Lecture notes Experiment 9. Lecture notes 100% (6) 9. 1-XRAY diffraction combined new. Lecture notes 100% (1) 5. MSE227L Lab 3 - Chima Ojukwu Lab. Coursework None. 5. MSE227L Lab 5 - Chima Ojukwu Lab. Coursework None. New. 7. Solved How might you explain the discrepancy between the The mRNA coding for prolactin is translated in a cell-free protein-synthesizing system containing ribosomes, amino acids, tRNAs, aminoacyl-tRNA synthetases, ATP, GTP, and the appropriate initiation, elongation, and termination factors. Under these conditions, a polypeptide chain of 227 amino acids is produced. There are 2 steps to solve this one. Experiment 4 MSE 227 LAB MSE 227 Lab Report - Experiment 4; 2-Charpy Impact-modified 2018; 8-Precipitation Hardening of Aluminum; Preview text. Abstract Tensile properties of two polymers: LDPE (Low-Density Polyethylene) and HDPE (High- Density Polyethylene), steel, and aluminum were measured at a constant strain rate on the Tension testing machine. Before each ... Chapter 19 Reading Quiz Flashcards What experiment would be necessary to accomplish this task? ... Removal of the ER signal sequence reduces the length of the final polypeptide from 227 amino acids to 199 amino acids. The final polypeptide chain is released into the ER lumen. Using the techniques of genetic engineering, you design a protein you want to accumulate within the ER ... 627 Experiment 627 is an illegal genetic experiment created by Jumba Jookiba, and the first experiment to be created on Earth with limited alien technology. He serves as a minor antagonist in Lilo & Stitch: The Series, and is designed to be a better prototype of Stitch. Unlike the other known experiments (with the exception of Leroy), it is impossible for him to be rehabilitated, so he was ... Experiment #8 MSE227L The experiment was performed with the use of heat- treatment crucible and a furnace for solution treatment of 500 degrees Celsius for 30 min. Once the heat treatment is done the test was split up into the natural aging phase where five specimens are measured for its hardness and is measured at 30 min, 90 min, 1 day, and 1-week increments. Experiment #2 MSE227L labarotory experiment no. notched bar impact test (charpy) submitted to fulfil the requirement of mse 227l (16636) monday nights 7:00 pm california state. Skip to document. ... (MSE 227) 16 Documents. Students shared 16 documents in this course. University California State University, Northridge. Academic year: 2020/2021. Uploaded by: JP. Cell Bio Exam 2 Ch 16&19 HW Q's How might you explain the discrepancy between the normal length of prolactin (199 amino acids) and the length of the polypeptide synthesized in your experiment (227 amino acids)? You perform a second experiment, in which you add SRP to your cell-free protein-synthesizing system, and find that translation stops after a polypeptide about 70 amino ... essay homework paper phd project resume review speech study thesis