Examples.csv

Example Title,Fields,Keywords,Prompts,Source,Expected phenomenon,Author,Sanity check,finalized?,Reviewer,comments,Immutability,Correct Dynamism,Spatio-Temporal Continuity,Phenomenon Congruency,Prompt Consistency,Unique ID
"{hailuo2.3: 3, kling2.5: 3, luma2: 1, seedance1: 1, sora2: 4, veo3: 3, wan2.5: 3}",,,,,,,,Not started,,,,,,,,
"glass bottle, water, and hammer",Physics,"Impulse, Pressure, Wave Propagration",A glass bottle is filled completely with water. The top of the bottle is struck straight down with a hammer.,https://youtu.be/IPO6fX4ZTnM?si=5v-8Y4yRXFueABjq&t=494,"The sudden impact sends a pressure wave through the water. Because the liquid is nearly incompressible, the force transmits downward and reflects off the bottom, causing the base of the bottle to crack or shatter and water to pour out.",Daniel Zhao,Wan2.5,Makeup,,DZ: CHANGED,see above attachment,,,,,20
Lime juice dissolves rubber,Physics,"Acid-Base Reaction, Elasticity",A small amount of lime juice is squeezed from a lime onto the surface of an inflated rubber balloon.,https://youtu.be/IPO6fX4ZTnM?si=2b4ho9GBASkNAyEY&t=547,"The acid in the lime juice reacts with the rubber, breaking down its polymer structure. The weakened area loses elasticity, causing the balloon to pop where the juice touches it.",Daniel Zhao,Wan2.5,Makeup,,DZ: CHANGED,see above attachment,,,,,19
Oil and food coloring,Physics,"Density, Solubility","A small amount of food coloring is mixed with oil in a cup, then poured slowly into a clear glass filled with water.",https://youtu.be/IPO6fX4ZTnM?si=uGp0D0qnRZdD2MxR&t=406,"The oil remains floating on top of the water, while drops of food coloring fall through the oil layer and spread into the water, creating thin colorful strands.",Daniel Zhao,Wan2.5,Makeup,,DZ: CHANGED,see above attachment,,,,,18
Candle seesaw,Physics,"Equlibrium/Stability, Gravity, Heat Transfer","A long two-ended candle is balanced horizontally on a needle pushed through its midpoint, resting between two glass cups so it can pivot freely. The left end of the candle is lit first, and after a short time, the right end is also lit.",https://youtu.be/_u7bNsuZCcQ?si=NOcGq7QTynp2Mr8Y&t=249,"As both ends burn, melted wax drips unevenly, causing one side to become lighter and rise while the other lowers. This alternates as wax melts and refreezes, making the candle slowly rock up and down like a seesaw.",Daniel Zhao,Wan2.5,Makeup,,DZ: CHANGED,see above attachment,,,,,14
Tilting match,Physics,"Combustion / flammability, Equlibrium/Stability, Heat Transfer","One wooden match is fixed upright on a flat surface so that it stands vertically. A second match is placed leaning diagonally against it, with their match heads touching at the top. The middle of the tilting match is then ignited.",https://www.youtube.com/watch?v=6kn7kwHAmAA&t=1s,"The tilting match should start “levitating” after the match is lit. The tilted match appears to levitate because rising hot air from the burning matches produces an upward convection current that temporarily supports the lightweight, partially burned match after it detaches.",Daniel Zhao,Wan2.5,Done,"Lanxiang Hu, Yixin Huang",lx: very interesting. would be good to add explanation in expected phenomenon.,see above attachment,,,,,17
Newton’s cradle,Physics,"Elastic Collision, Energy Transfer, Momentum Conservation, Pendulum","Five identical metal balls are suspended in a straight line by thin strings so that they hang just touching each other at rest. One ball on the end is pulled back and released, allowing it to swing and strike the others.",https://www.youtube.com/shorts/PmNOBb-16-A,"When the lifted ball strikes the row, the ball on the opposite end swings outward while the others remain nearly stationary, demonstrating conservation of momentum and energy.",Daniel Zhao,Wan2.5,Done,"Lanxiang Hu, Yixin Huang",lx: good,see above attachment,,,,,16
Cloud in a bottle,Physics,"Condensation, Phase transitions, Pressure","A small amount of water is added to an empty plastic bottle, which is sealed with a cap. A person squeezes and twists the bottom of the bottle several times to increase internal pressure, then the cap is suddenly released.",https://www.youtube.com/watch?v=wJ-Tp8bQC4M,"When the pressure is released, the air inside expands and cools rapidly, causing the water vapor to condense into tiny droplets that form a visible cloud.",Daniel Zhao,Wan2.5,Makeup,,DZ: CHANGED,see above attachment,,,,,15
Water stream and sound,Physics,"Fluid Dynamics, Resonance, Sound, Sound Waves, Vibration","A flexible transparent tube carrying a steady stream of water is taped to the front of a speaker so that the open end extends outward, and water pours out of the tube. Camera view from 10 feet away, looking towards the speaker. The speaker begins to play a low-frequency sound while water continues to flow from the tube.",https://youtu.be/rYrdiQckGhw?si=oI8n-oeKmX0FVQfa&t=277,"As the sound plays, pressure oscillations from the speaker cause the water stream to vibrate at the same frequency, forming visible spirals or standing-wave patterns that seem to move, freeze, or reverse depending on the playback frequency.",Daniel Zhao,Wan2.5,Makeup,,DZ: CHANGED,see above attachment,,,,,13
Candle and water,Physics,"Combustion / flammability, Pressure, Vacuum","A lit candle is placed upright in the center of a shallow bowl filled with a small amount of water. A clear glass bottle is then lowered upside-down over the candle, covering it while its mouth rests in the water.",https://www.youtube.com/shorts/mUthYZr5sco,Water should slowly fill into the bottle with the candle in it.,Daniel Zhao,Wan2.5,Done,"Lanxiang Hu, Yixin Huang",lx: lgtm,see above attachment,,,,,8
============================================,,,=============================================================================,,============================================,,,Not started,,,,,,,,127
Straw Wrapper Worm,Physics,"Capillary Action, Surface Tension","A straw wrapper paper tissue is crumpled into an accordion shape on a table. A drop of water is placed near one end of the crumpled paper, touching the paper.",https://www.youtube.com/watch?v=7yh_6t_20NM,"The crumpled wrapper immediately begins expanding and crawling like a worm as water is absorbed through capillary action, causing the paper fibers to swell and straighten.",Abhilash,Sora-2,Done,"Daniel Zhao, Murray Kang",mk: good dz: good,,,,,,106
Water Bridge Experiment,Physics,"Electrostatics, Surface Tension","Two beakers filled to the brim with deionized water are placed side by side, touching each other. High voltage electrodes are inserted into each beaker, and gradually the beakers are moved apart while voltage is applied.",https://www.youtube.com/watch?v=6ZzuFGw4XCg,"A bridge of water forms and floats between the two beakers, defying gravity as electrostatic forces hold the water column together.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang",mk: cool example dz: good,,,,,,105
Curie Point Demonstration,Physics,"Heat, Magnetism","A strong neodymium magnet (approximately 2-3 cm in diameter) is mounted horizontally on a rigid stand at a height of about 15 cm above a table surface. A small, thin strip or piece of pure nickel metal (approximately 1 cm x 3 cm, and less than 3 mm thick) is suspended by a thin cotton thread or fishing line from a horizontal support rod. A lit candle is positioned on the table with its flame below the nickel piece.",https://www.youtube.com/watch?v=haVX24hOwQI,"Initially, the hanging nickel piece is strongly attracted by the magnetic field and pulls toward the magnet, hanging at an angle rather than straight down. The nickel remains suspended in this tilted position, held by magnetic attraction. As the candle flame heats the air below, the nickel piece warms. When the nickel reaches its Curie temperature, it suddenly loses its ferromagnetic properties and becomes paramagnetic (only weakly magnetic). At this moment, the magnetic attraction abruptly disappears, and the nickel drops away from the magnet, swinging downward like a pendulum under gravity alone.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang","mk: prompt and expected phenomena are not consistent with the GT video. No “thread”, “dropping” in the GT video. [fixed]",,,,,,104
Chain Fountain,Physics,"Gravity, Inertia","A glass beaker (approximately 10 cm tall) is filled with a loosely coiled metal ball chain (the type with small spherical beads connected by short rods, commonly used for key chains or lamp pulls). The beaker is positioned at the very edge of a table so that its rim is flush with or slightly overhanging the table edge. The chain is coiled in the beaker with no particular order, forming a loose pile that fills most of the beaker's volume. A person grasps one free end of the chain that extends above the pile and drapes it over the rim of the beaker, letting about 10-15 cm hang down toward the floor. The person then releases this hanging end.",https://www.youtube.com/watch?v=xHsKJJvcFLQ&t=160s,"Once released, the hanging portion of chain accelerates downward under gravity, pulling more chain from the beaker. However, instead of simply sliding over the rim and falling straight down, the chain exhibits a dramatic and counterintuitive behavior: it rises up out of the beaker in an elegant upward arc or ""fountain"" that extends 10-20 cm above the rim before curving down toward the floor. The chain continuously flows up and out of the beaker in this graceful parabolic arc, resembling a fountain of metal beads suspended in mid-air. As the chain depletes from the beaker, the fountain remains stable and consistent until nearly all the chain has been pulled out. ",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang",mk: the prompt doesn’t look right to describe the GT video. [fixed],,,,,,103
Sympathetic Pendulums,Physics,"Energy Transfer, Resonance",Two identical pendulums hang from the same horizontal string or rod. One pendulum is set swinging while the other hangs still.,https://youtu.be/32FMEo_igEQ?si=Fjaw3xMTXLbWhhZH,"Within seconds, the moving pendulum begins to slow while the stationary one starts swinging, as energy transfers back and forth through the shared support via resonance.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang",mk: good! dz: good,,,,,,102
Tea Bag Rocket,Physics,"Buoyancy, Phase Change, Thermal convection","An empty tea bag is unfolded into a cylinder, stood upright on a plate, and lit at the top edge with a match. The cylinder burns from top to bottom.",https://www.youtube.com/watch?v=_6EdGOOeK5Y,"Just as the last bit finishes burning, the remaining ash lifts off and floats upward several feet because it becomes light enough for the hot air current to carry it as a glowing ember.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang",mk: good! dz: good,,,,,,101
Coin and Card Inertia,Physics,"Friction, Inertia","A playing card is placed on top of a glass, and a coin is balanced on the card directly over the glass opening. The card is flicked horizontally away from the glass with a quick motion.",https://www.youtube.com/watch?v=3ujSiDPrAPI,"The coin drops straight down into the glass rather than following the card, demonstrating inertia as the coin tends to remain at rest while the card is removed quickly.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang",mk: might be too easy? dz: i think its good,,,,,,100
Dropping Slinky,Physics,"Gravity, Wave Propagration","A metal slinky is held vertically by its top end, fully extended and hanging. The top end is suddenly released and the slinky is allowed to fall freely.",https://youtu.be/uiyMuHuCFo4?si=JGP4JZ81DebZQsCt,"The bottom of the slinky remains stationary in mid-air for a moment while the top collapses downward, until the tension release information propagates down and the whole slinky falls together.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang",mk: good! dz:  good,,,,,,99
Cartesian Diver,Physics,"Buoyancy, Gas Laws, Pressure",A sealed plastic bottle is filled with water containing a floating eyedropper with an air bubble inside. A person squeezes the sides of the bottle.,https://www.youtube.com/watch?v=aYNpTomZeGM,"The eyedropper immediately sinks when the bottle is squeezed, then rises again when released, as increased pressure compresses the air bubble, reducing buoyancy.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang",mk: good! dz: good,,,,,,98
Crushing Can with Vacuum,Physics,"Phase Change, Pressure",An empty aluminum soda can containing a small amount of boiling water is quickly inverted and plunged open-end-down into a bowl of ice water.,https://www.youtube.com/watch?v=_eaUBopwmA0,"The can instantly crumples and collapses with a loud bang as the steam inside rapidly condenses, creating a vacuum, and atmospheric pressure crushes the can.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang","mk: good! dz: wan2.5 doesnt really follow the GT that well with this prompt on the setup. maybe make it more specific? 
abhi: my sora and Wan GT video looks good",,,,,,97
Resonance Collapse,Physics,"Fracture, Resonance, Vibration","A tall, narrow wine glass is mounted to a sturdy base. A speaker placed nearby emits a loud pure tone matching the glass's resonant frequency (pre-measured and set).",https://www.youtube.com/watch?v=ntSCRNhQ06Y,"Within several seconds of loud sound exposure, the glass begins vibrating visibly and suddenly shatters as resonant amplification exceeds the material's strength.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang",mk: good! dz: good,,,,,,96
Prince Rupert's Drop Tail Break,Physics,"Fracture, Impact Mechanics, stress‐concentration",A teardrop-shaped piece of tempered glass (Prince Rupert's Drop) is held at its bulbous head. Small pliers gently snip the thin tail end.,https://www.youtube.com/watch?v=xe-f4gokRBs,The entire drop explosively shatters into powder in a fraction of a second as the release of internal tension propagates through the glass at high speed.,Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang",mk: good! dz: good,,,,,,94
Breaking Spaghetti,Physics,"Energy Storage & Release, Fracture, stress‐concentration",A dry spaghetti stick is held at both ends and slowly bent until it breaks.,https://www.youtube.com/watch?v=RwtXVW0IWEk,"The spaghetti breaks into three or more pieces rather than two, because stress waves from the first fracture cause additional breaks before the fragments separate.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang","mk: good! dz: not sure if this is too simple or not. but i think should be fine
abhi: in the generated videos spagetti breaks down only into two parts. https://news.mit.edu/2018/mit-mathematicians-solve-age-old-spaghetti-mystery-0813",,,,,,95
" Capillary Action Race",Physics,"Gravity, Surface Tension","Three strips of different materials (paper towel, cotton cloth, and plastic film) are placed with their bottom edges touching colored water in a shallow dish, standing vertically.",https://www.reddit.com/r/explainlikeimfive/comments/m340ny/eli5_why_can_cloth_absorbsoak_up_water_but/?utm_source=share&utm_medium=web3x&utm_name=web3xcss&utm_term=1&utm_content=share_button,"The water climbs up the paper towel fastest, the cotton cloth slower, and barely rises on the plastic, demonstrating different capillary action based on material properties.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang","mk: the GT video is achieved, maybe change it? dz: good abhi: I don’t see a clear difference in climbed water height (paper vs cloth) in Wan and Sora GT video even plastic has capillary action ",,,,,,92
Leidenfrost Effect,Physics,"Heat, Heat Transfer",A drop of water is carefully placed onto a metal pan heated to 250°C.,https://www.youtube.com/watch?v=9tlIWlGvkRc,"The water drop forms a perfect sphere and glides across the surface without boiling, hovering on a cushion of its own vapor that insulates it from the hot metal.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang",mk: good! dz: good,,,,,,91
Electromagnetic Induction Ring Jump,Physics,"Eddy Currents, Electromagnetism",A metal ring rests horizontally on top of an iron-core electromagnet coil. The coil is suddenly connected to a high-current DC power supply.,https://youtu.be/T9PflsLZqY8?si=2NWnFc8ieawX8uXl,"The ring rapidly jumps several feet into the air as the suddenly changing magnetic field induces a current in the ring that creates an opposing magnetic field, causing strong repulsion.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang",mk: good! dz: good,,,,,,93
3 soda cans and tablecloth,Physics,"Equlibrium/Stability, Friction, Impulse, Inertia",Three empty soda cans are stacked on top of each other on a table covered with a tablecloth. The tablecloth is pulled rapidly off the table from beneath the cans.,https://www.youtube.com/shorts/7MaOWBgHXsE,The caps should stay on the table in the same formation while the sheet gets pulled off,Daniel Zhao,Wan2.5,In progress,"Lanxiang Hu, Yixin Huang",lx: I think this case requires some deliberate practice and it’s not deterministic/reproducible every time. let’s rewrite,see above attachment,,,,,7
Rice and sound,Physics,"Energy Conversion, Sound, Sound Waves, Vibration",A bowl is covered tightly with a thin plastic sheet so that the surface is smooth and stretched evenly across the rim. A small handful of uncooked rice grains lies evenly across the plastic surface. A metal gong is then struck once a short distance away from the setup while the bowl remains stationary on a flat table.,https://www.youtube.com/shorts/HX8ESrMGfvk,The rice and plastic sheet should bounce up and down each time the gong is hit. The sound waves should cause the plastic sheet to vibrate,Daniel Zhao,Wan2.5,Done,"Lanxiang Hu, Yixin Huang",lx: sound wave —> air pressure? could specify scientific concepts in expected phenomenon. [FIXED],see above attachment,,,,,6
Apple and hammer,Physics,"Friction, Impulse, Inertia, Momentum Conservation","An apple has a long, thin wooden pole inserted through its center, with the apple sitting partway up the stick. It is held upright by a person. The person uses a hammer to deliver a few quick tap on the top end of the stick while the stick is kept straight.",https://www.youtube.com/shorts/9dMFxnpEkKc,The apple is expected to rise higher  on the stick with each hit of the hammer.,Daniel Zhao,Wan2.5,Done,"Lanxiang Hu, Yixin Huang",lx: lgtm,see above attachment,,,,,12
Blade and water - surface tension (sink),Physics,"Buoyancy, Surface Tension","A thin metal razor blade is held vertically with tweezers above a glass of still water. The tweezers then let go of the blade, dropping it edge-first into the still water.",https://www.youtube.com/shorts/j8qkUOASUBk,The blade is expected to sink to the bottom of the water.,Daniel Zhao,Wan2.5,Done,"Lanxiang Hu, Yixin Huang",lx: lgtm,see above attachment,,,,,11
Blade and water - surface tension (float),Physics,"Buoyancy, Surface Tension","Using tweezers, a thin metal blade is gently placed flat and horizontally on the surface of still water in a glass. The blade is carefully lowered until it just touches the water surface without breaking it and then it is let go.",https://www.youtube.com/shorts/j8qkUOASUBk,The blade is expected to float on the water.,Daniel Zhao,Wan2.5,Done,"Lanxiang Hu, Yixin Huang",lx: lgtm,see above attachment,,,,,10
Speakers and rotating bottles,Physics,"Resonance, Rotational Dynamics, Sound, Sound Waves, Wave Propagration",Two empty plastic bottles are attached to the ends of a horizontal wooden rod using string loops. The bottles are horizontal to the ground. The rod is balanced at its center on a pointed support so it can spin freely. A speaker is placed beneath each bottle and they produce tones at the bottles' resonant frequencies.,https://youtu.be/rYrdiQckGhw?si=lFjOrx1Mjw7j_nk8&t=151,"When the speakers emit sound at the bottles’ resonant frequency, the air inside them vibrates strongly, creating pressure differences that cause the bottles to rotate around the central support.",Daniel Zhao,Wan2.5,Makeup,,DZ: CHANGED,see above attachment,,,,,9
Spinning coin,Physics,"Gravity, Rotational Dynamics","A metal coin rests flat on a smooth tabletop. Using two fingers, the coin is turned onto its edge and is given a firm spin so that it rotates rapidly on its edge on the table.",https://www.youtube.com/shorts/AUHAHXL9pZk,The hand should spin the coin and the coin’s rotation should slowly start getting wider and wider due to gravity until it stops.,Daniel Zhao,Wan2.5,Done,"Lanxiang Hu, Yixin Huang",lx: lgtm,see above attachment,,,,,5
Active Metalens Switch,Physics,"Interference, Refraction",A smart lens made of phase‑change material is switched electrically while a white‑light beam passes through and hits the white screen behind it.,https://www.youtube.com/watch?v=tvKbNRtJP6U,"The active metalens changes its refractive phase profile electronically; as it switches, the beam refraction pattern and interfering wavefronts shift, causing the focus to move/blur in real‑time.
",Yixin Huang,Wan2.5,Not started,,,,,,,,210
Meta‑Surface Beam Shaper,Physics,"Diffraction, Dispersion","A laser pointer shines through a flat metasurface plate and projects onto a screen. ",https://www.youtube.com/watch?v=1u6hkGSv384,"The metasurface, composed of sub‑wavelength structures, diffracts incoming coherent light into a designed pattern; different wavelengths exit at slightly different angles (dispersion), so the beam shape and color separation shift with rotation.
",Yixin Huang,Wan2.5,Not started,,,,,,,,209
Metasurface Negative Refraction Demo,Physics,"Dispersion, Refraction",A narrow beam of visible light is directed through a metasurface or metamaterial slab and filmed entering and exiting.,https://www.youtube.com/watch?v=SKp3QiaH1a0,"In negative‑index metamaterials or metasurfaces, light can refract on the “wrong” side of the normal (negative refraction); strong dispersion leads to wavelength dependent bending, so visible color separation may appear in the output beam.",Yixin Huang,Wan2.5,Not started,,,,,,,,208
"
Diamond “Fire” Sparkle
",Physics,"Dispersion, Reflection, Refraction","
A faceted diamond ring is rotated under white light.",https://www.youtube.com/shorts/auvkUkgQ640,"A diamond’s famous sparkle comes from an interplay of reflection, refraction, and dispersion of light . Thanks to a very high refractive index, light entering the diamond is strongly refracted (bent) and then internally reflected multiple times by the cut facets. As those light rays finally exit, they are dispersed (split into spectral colors like a prism) – a property gemologists call fire . A well-cut diamond maximizes this effect, sending back concentrated flashes of colored light and white brilliance. In short, each facet acts like a tiny mirror and prism, creating the diamond’s multicolor scintillation.
",Yixin Huang,Wan2.5,Not started,,,,,,,,207
"
Sunset Green Flash
",Physics,"Dispersion, Refraction","
At the very last moment of a tropical ocean sunset, the sun’s orange disk appear at the upper edge of the horizon.
",https://www.youtube.com/watch?v=axOmIu71pTo,"
The green flash is a brief optical phenomenon at sunset caused by atmospheric dispersion and refraction of sunlight. As the sun sets, its light is bent through Earth’s atmosphere like a prism; shorter wavelengths (green/blue) are refracted slightly more and thus remain visible for an instant after the red light is obscured. Although blue light bends even more, it’s mostly scattered out, so the final burst of light appears green. This results in a split-second green glint just as the sun’s upper rim disappears.
",Yixin Huang,Wan2.5,Not started,,,,,,,,205
"
Pilot’s Glory
",Physics,"Interference, Refraction","
Viewed from an airplane window, the plane’s own shadow on a cloud bank. ",https://www.youtube.com/watch?v=8Aq2bRQxSTc,"
A glory is a series of concentric, rainbow-colored rings that appear around the observer’s shadow (often from a plane or mountain) due to sunlight interacting with tiny cloud droplets. It arises from wave interference of light that is internally refracted and reflected within the mist droplets. The overlapping of internally refracted wavefronts produces constructive interference at certain angles, forming halo-like rings (reddish on the outer edge, bluish toward the center). This differs from a large rainbow in size and mechanism, creating a personal “mini-rainbow” around the shadow of the observer.
",Yixin Huang,Wan2.5,Not started,,,,,,,,204
"
Iridescent Cloud
",Physics,"Diffraction, Interference","
High in the sky near the sun, a thin patch of cloud ripples along its edges.
",https://www.youtube.com/shorts/FGOibJ7s0QM,"
Cloud iridescence occurs when sunlight diffracts through uniformly tiny water droplets or ice crystals in the cloud, causing wave interference that produces vivid color bands. The diffracted light’s wavelengths reinforce at slightly different angles, creating the patch of delicate rainbow colors (similar to oil on water) . This optical effect is seen in “pileus” or nacreous clouds and is distinct from a regular rain-rainbow because it arises from micro-scale scattering.
",Yixin Huang,Wan2.5,Not started,,,,,,,,203
"
Moonlit Waterfall Rainbow
",Physics,"Dispersion, Reflection, Refraction","
A night-time waterfall scene in the mist, illuminated by the full moon.
",https://www.youtube.com/shorts/_pdVjgqwUX4,"
A moonbow is a rare lunar rainbow produced by the reflection, refraction, and dispersion of moonlight in airborne water droplets . Because moonlight is much dimmer than sunlight, the resulting spectrum is faint – often appearing almost white to the naked eye – but long-exposure footage reveals the full rainbow of colors .
",Yixin Huang,Wan2.5,Not started,,,,,,,,202
Speckle on Water Surface,Physics,"Diffraction, Interference",A laser pointer shines on the rough edged surface of a piece of glass.,https://www.youtube.com/shorts/y5yk4JWY1Zw,"The coherent laser light scattering off the rough edge glass results in diffraction and interference, creating a dynamic speckle pattern.
",Yixin Huang,Wan2.5,Not started,,,,,,,,201
Magneto‑optic Rotation,Physics,"Magnetics, Polarization",A transparent glass sample is placed between two polarizers and a coil produces a magnetic field through the glass; you film the sample as the magnetic field is turned on/off.,https://www.youtube.com/watch?v=UFEVvsbvlkA,The magnetic field induces the Faraday effect in the glass — causing the plane of polarization of light to rotate as it passes through. Between the polarizers this appears as a changing color or brightness pattern that depends on field strength.,Yixin Huang,Wan2.5,Not started,,,,,,,,200
Polarized Stress Fringes,Physics,"Interference, Polarization",A clear plastic sheet is illuminated by white light between two crossed polarizing filters; the camera films as the sheet is gently bent and twisted.,https://www.youtube.com/watch?v=agXimK-NzGQ,"The stressed plastic becomes birefringent, causing different polarization components of light to travel at different speeds. Between crossed polarizers, these components interfere and show colorful fringe patterns that shift as the plastic is distorted.",Yixin Huang,Wan2.5,Not started,,,,,,,,199
Optics Kit Beam Path,Physics,"Dispersion, Refraction","A laser beam is directed through an educational optics kit with multiple acrylic pieces. ",https://www.youtube.com/shorts/b-Joj9d4aBI,"As the laser passes through each acrylic element, the light is refracted at each interface and because each wavelength bends slightly differently, the beam can split into subtle color components and shift direction.",Yixin Huang,Wan2.5,Not started,,,,,,,,198
Flask Rainbow Ring,Physics,"Dispersion, Refraction",A round‑bottom glass flask filled with water is illuminated through a small hole and filmed.,https://www.youtube.com/shorts/tQ-kdHwc4kQ,"The curved flask acts like a spherical prism: light entering and exiting bends (refraction), and because different wavelengths refract by different amounts (dispersion), a colored ring appears around the projected beam.",Yixin Huang,Wan2.5,Not started,,,,,,,,197
Conical Refraction Crystal,Physics,"Dispersion, Refraction",A laser beam shines through a small biaxial crystal and the camera films.,https://www.youtube.com/watch?v=S3KKEZUemjo,"When a beam enters a biaxial crystal along a special axis, it undergoes conical refraction: the light inside splits into a hollow cone, exiting as a ring. Because different wavelengths refract differently, the ring can show color variation (dispersion).  ",Yixin Huang,Wan2.5,Not started,,,,,,,,196
Aureole Water Rays,Physics,"Diffraction, Refraction",A person stands at the edge of a calm pond in sunlight; the camera films rays of light.,https://www.youtube.com/watch?v=iMNS-Qv_H-I,"The rippling water surface acts like many small lenses, focusing and defocusing sunlight so that light appears to radiate from the antisolar point (the viewer’s shadow). Diffractive effects from suspended particles enhance the rays’ visibility, forming the “aureole effect”.",Yixin Huang,Wan2.5,Not started,,,,,,,,195
Sylvanshine Glow,Physics,"Diffraction, Reflection","A dark forest scene after rain: sunlights shine onto dew‑covered leaves and you film the tree foliage.
",https://www.youtube.com/watch?v=Ft0QwUOJmK4,Tiny dew‐droplets on wax‑coated leaves act as lenses and retroreflect light back toward the source; the halo glow is enhanced by diffraction of light around those droplets.,Yixin Huang,Wan2.5,Not started,,,,,,,,194
Invisible Rod,Physics,"Density, Refraction","A clear acrylic rod is immersed in a container of oil , and the scene is filmed from the side.",https://www.youtube.com/watch?v=5RBsm0r_EaU,"When the refractive index of the rod matches that of the surrounding oil, light passes through with minimal refraction or reflection, making the rod nearly invisible.",Yixin Huang,Wan2.5,Not started,,,,,,,,193
Mirage Road Oasis,Physics,"Fluid Dynamics, Refraction",A camera films a hot asphalt road at noon while a car drives toward it.,https://www.youtube.com/shorts/iLdcQXp_WCg,"Layers of hot air above the asphalt create a refractive‐index gradient; light rays from the sky curve upward as they pass through these layers, forming an inferior mirage that looks like a water pool but vanishes on approach.",Yixin Huang,Wan2.5,Not started,,,,,,,,192
Goos–Hänchen Shift,Physics,"Interference, Reflection",A laser beam glances off a glass plate at near‑critical angle and you film the reflected spot.,https://www.youtube.com/watch?v=DEtLHN0oILs," At total internal reflection (or near it), the reflect­ed beam undergoes a small lateral shift (the Goos–Hänchen effect) due to interference of evanescent and reflected waves, causing the reflected spot to appear displaced. ",Yixin Huang,Wan2.5,Not started,,,,,,,,191
UV liquid nitrogen,Physics,"Low-Temperature Quenching, Phosphorescence, Quantum Mechanics","A substance is cooled to liquid nitrogen temperatures, and then a UV light is shone onto it.",https://www.youtube.com/watch?v=PpiE157tpUQ,"The extreme cold suppresses thermal energy loss, causing the substance to trap excitation energy and glow intensely for a long period (phosphorescence).",Murray,Wan2.5,Not started,,,,,,,,22
copper projectile,Physics,"Electromagnetism, Lorentz Force","A small, lightweight copper projectile is placed between two parallel copper rails, and a high current is momentarily discharged through the rails.",https://www.youtube.com/watch?v=9myr32FgCWQ,"The massive current creates an enormous magnetic field that exerts a powerful Lorentz Force on the projectile, propelling it forward at high speed.",Murray,Wan2.5,Not started,,,,,,,,23
Rod,Physics,"Acoustics, Helmholtz Resonance, Resonance","A glass rod is placed over the mouth of a long vertical tube, and a small amount of liquid is added inside.",https://www.youtube.com/watch?v=bHdHaYNX4Tk,"Tapping the rod will excite the air column, causing the tube to emit a specific, sustained tone as the air column resonates at its natural frequency.",Murray,Wan2.5,Not started,,,,,,,,24
Ruben’s Tube Standing Waves,Physics,"Acoustics, Combustion / flammability, Fluid Dynamics","Cinematic shot of a Ruben's tube in a dark studio. A 400 Hz sine wave input causes high-pressure antinodes to modulate the methane flames, creating parabolic peaks and low-flame nodal points. The flames oscillate rapidly. 4K, precise flame height rendering.",https://www.youtube.com/watch?v=sIopZnMLeQo,Visualization of acoustic standing wave pressure profile via flame height variation.,Murray,Wan2.5,Not started,,,,,,,,25
Chladni Plate Acoustic Patterns,Physics,"Acoustics, Granular Mechanics, Mechanical Resonance, Vibration","Extreme close-up of fine white sand on a polished circular metal plate vibrating at its second natural frequency (e.g., 800 Hz). The sand dynamically shifts from random distribution to a perfectly symmetrical geometric pattern (nodal lines) upon resonance. High contrast, 4K, slow motion focus pull.",https://www.youtube.com/watch?v=tFAcYruShow,"Formation of complex, stable nodal patterns induced by specific acoustic frequencies.",Murray,Wan2.5,Not started,,dz: duplicate,,,,,,26
Reactive Leidenfrost Effect,Physics,"Fluid Dynamics, Heat Transfer, Phase Change, Thermodynamics","High-speed macro footage of small cellulose particles dropped onto a metal surface heated above $750^\circ C$. Observe the particles levitate on a vapor cushion, skittering erratically due to asymmetric gas release during thermal decomposition. Shallow depth of field.",https://www.youtube.com/watch?v=-PJndBr9IpY,Levitation and erratic motion of solid particles driven by thermal decomposition and vapor formation.,Murray,Wan2.5,Not started,,,,,,,,27
Rayleigh-Taylor Instability,Physics,"Density Stratification, Fluid Dynamics, Gravity","Dynamic simulation visualization of a heavy, dark blue fluid accelerating downward into a lighter, clear fluid. Focus on the boundary layer forming fractal ""spikes"" and ""bubbles"" as the interface mixes due to unstable density stratification. High resolution, scientific visualization style.",https://www.youtube.com/watch?v=bW4526vHnY0,Interfacial instability and dynamic mixing of fluids with contrasting densities under acceleration.,Murray,Wan2.5,Not started,,,,,,,,28
Non-Newtonian Impact Dynamics,Physics,"Fluid Dynamics, Impact Mechanics, Shear Thickening, Viscoelasticity","High-speed camera footage capturing a dense metal sphere impacting a vat of cornstarch (oobleck) at high velocity. The fluid surface momentarily solidifies upon impact due to shear thickening, generating a large splash of non-liquid fragments.",https://www.youtube.com/watch?v=BCn1Qyay1YY,Deceleration of an object due to rapidly increasing apparent viscosity under high shear rate.,Murray,Wan2.5,Not started,,,,,,,,29
Viscosity Flow Cascade,Physics,"Fluid Dynamics, Gravity, Kinematics","Side-by-side slow-motion race of three materials (honey, olive oil, dish soap) flowing down a steep, inclined surface under gravity. Focus on the differential flow rates and the smooth, laminar profile of the higher viscosity liquids. Studio lighting, clear differentiation.",https://www.youtube.com/watch?v=wPk7_wm4uMs,Comparative demonstration of varying internal fluid resistance (viscosity) affecting flow rate under gravity.,Murray,Wan2.5,Not started,,,,,,,,30
Light Refraction Arrow Reversal,Physics,"Interface Physics, Optics","A piece of white paper with a large black arrow pointing right is slowly lowered behind a cylindrical glass beaker filled with water. View the arrow through the water, clearly capturing the light path bending and causing the arrow to instantaneously appear to point left. Steady camera pull-back shot.",https://www.youtube.com/watch?v=9n362snGUdw,Apparent reversal of an image caused by the change in the path of light (refraction) through media of different densities.,Murray,Wan2.5,Not started,,,,,,,,31
Coca-Cola vs Milk Reaction,Chemistry,"Acid-Base Reaction, Precipitation reaction, Protein Denaturation",A person pours milk into a bottle of Coca-Cola and lets the bottle rest.,https://youtu.be/pVDqiYIxvdA?si=ISpkzhDk4cHvuarl&t=349,"Milk changes colour, precipitates form, fizzing as acid meets proteins.",Murray,Wan2.5,Done,Daniel Zhao,dz: good,"{hailuo2.3: [4, 1, 4], klingv2.5: [4, 4, 4], ray-2: [1, 1, 1], seed-dance: [4, 1, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [3, 1, 2], klingv2.5: [3, 2, 4], ray-2: [2, 4, 2], seed-dance: [4, 1, 4], sora-2: [4, 4, 4], veo3: [1], wan2.5: [1, 4, 4]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [3, 4, 4], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [1], wan2.5: [4, 4, 4]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [1, 1, 1], ray-2: [1, 2, 3], seed-dance: [1, 1, 1], sora-2: [3, 4, 2], veo3: [3], wan2.5: [2, 3, 2]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 3, 3], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [2, 4, 4]}
",45
Make Hot-Ice with Sodium Acetate,Physics,"Phase transitions, Super-cooling","A mixture of sodium acetate and water is heated in a beaker until the solid fully dissolves. The clear solution is then poured into a clean glass container and left to cool undisturbed at room temperature. After cooling, a long thin stick is inserted vertically into the solution and held in place.",https://youtu.be/pVDqiYIxvdA?si=Q9Urw_8z-k96BUTl&t=297,"Instant solidification releases heat, forming clear crystals inside the water that spike around the stick.",Murray,Wan2.5,Done,Daniel Zhao,dz: completely rewrote prompt / scenario to match video. added timestamp to ref vid,"{hailuo2.3: [4, 4, 2], klingv2.5: [4, 4, 3], ray-2: [2, 1, 1], seed-dance: [4, 1, 4], sora-2: [4, 4, 2], veo3: [4, 4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [4, 1, 3], klingv2.5: [4, 4, 3], ray-2: [2, 1, 1], seed-dance: [4, 1, 4], sora-2: [4, 4, 4], veo3: [2, 4], wan2.5: [3, 1, 1]}
","{hailuo2.3: [4, 4, 3], klingv2.5: [4, 4, 4], ray-2: [1, 1, 1], seed-dance: [4, 4, 4], sora-2: [4, 4, 1], veo3: [4, 4], wan2.5: [4, 4, 2]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [1, 1, 1], ray-2: [1, 1, 1], seed-dance: [1, 1, 1], sora-2: [4, 4, 3], veo3: [3, 2], wan2.5: [1, 1, 1]}
","{hailuo2.3: [2, 1, 3], klingv2.5: [3, 3, 4], ray-2: [1, 1, 1], seed-dance: [4, 3, 4], sora-2: [4, 3, 4], veo3: [3, 3], wan2.5: [3, 4, 4]}
",44
Aluminum Can & Drain-Cleaner Reaction,Chemistry,"Exothermic Reaction, Thermodynamics","A small piece of aluminium foil dropped into a container of drain-cleaner (strong base) in a safe lab-style setup; bubbles erupt rapidly, camera captures reaction and heat glow.",https://www.youtube.com/watch?v=pVDqiYIxvdA,"Vigorous bubbling, aluminium dissolves or reacts with heat and gas produced.",Murray,Wan2.5,Not started,,,,,,,,43
Where is the Water? Magic Trick,Physics,"Optics, Refraction, Surface Tension",A glass of water hidden under a card; as the card is slid away the water seems to vanish; multiple camera angles including top view reveal the trick effect.,https://www.youtube.com/watch?v=pVDqiYIxvdA,Water seemingly disappears abruptly when card is removed.,Murray,Wan2.5,Not started,,,,,,,,42
Invisible Flame Illusion,Chemistry,"Combustion chemistry, Photochemistry, black-body radiation","A flame that appears nearly invisible (ultra-blue or UV) in a dark room, with the surroundings lit only by its faint glow, camera rotates around the flame.",https://www.youtube.com/watch?v=pVDqiYIxvdA,"Flame appears faint or invisible under visible light, but is there.",Murray,Wan2.5,Not started,,,,,,,,41
Dry Ice Bubble Trick,Physics,"Heat Transfer, Phase transitions, Sublimation","A large soap bubble inflated over a piece of dry ice (solid CO₂) inside a dish, fog spills out and the bubble slowly deflates with mist emerging.",https://www.youtube.com/watch?v=pVDqiYIxvdA,"Bubble forms, fog flows, bubble shrinks and collapses with dramatic effect.",Murray,Wan2.5,Not started,,,,,,,,40
Colorful Rain – Rainbow Experiment,Physics,"Diffusion, Fluid Dynamics, Surface Tension","Simulate droplets of colored water falling through air, merging into layered colorful patterns on a surface, slow-motion and top-down view.",https://www.youtube.com/watch?v=pVDqiYIxvdA,Multi-colored water drips form a rainbow-like pattern and layering.,Murray,Wan2.5,Not started,,,,,,,,39
Balloon & Sharpening Nails Trick,Physics,"Pressure Distribution, stress‐concentration",A bed of nails is arranged evenly with their pointed ends facing upward. A fully inflated balloon is gently pressed down onto the bed of nails.,https://youtu.be/pVDqiYIxvdA?si=-3rTg8mzafzstYpq&t=86,Balloon doesn’t pop despite many nails.,Murray,Wan2.5,Done,Daniel Zhao,dz: completely rewrote prompt / scenario to match video. added timestamp to ref vid,"{hailuo2.3: [4, 4, 1], klingv2.5: [4, 4, 2], ray-2: [3, 3, 1], seed-dance: [2, 2, 2], sora-2: [4, 4, 4], veo3: [4, 3], wan2.5: [4, 4, 4]}
","{hailuo2.3: [2, 2, 1], klingv2.5: [2, 2, 1], ray-2: [2, 1, 1], seed-dance: [1, 1, 1], sora-2: [4, 4, 4], veo3: [4, 2], wan2.5: [4, 3, 3]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 1, 2], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4, 3], wan2.5: [4, 4, 4]}
","{hailuo2.3: [3, 4, 1], klingv2.5: [4, 4, 2], ray-2: [4, 1, 2], seed-dance: [3, 4, 3], sora-2: [4, 4, 4], veo3: [4, 2], wan2.5: [4, 4, 4]}
","{hailuo2.3: [3, 4, 2], klingv2.5: [4, 2, 2], ray-2: [1, 1, 1], seed-dance: [2, 2, 2], sora-2: [4, 3, 4], veo3: [2, 2], wan2.5: [4, 4, 4]}
",38
Ferrofluid & Neodymium Magnet Magic,Physics,"Magnetism, Surface Tension, field‐lines visualization","A pool of black ferrofluid being manipulated with a strong neodymium magnet: spikes form and dance, camera pans around showing reflections.",https://www.youtube.com/watch?v=pVDqiYIxvdA,Ferrofluid spikes align with magnetic field lines and move as magnet moves.,Murray,Wan2.5,Not started,,,,,,,,37
Freeze a Strawberry in super-cooled water,Physics,"Heat Transfer, Nucleation, Phase transitions, latent heat release",A bottle of purified water that has been super-cooled below its freezing point is poured carefully into a clear glass. A whole strawberry is then dipped fully into the super-cooled water and lifted back out.,https://youtu.be/pVDqiYIxvdA?si=iwFA2KPdfYW6xZPt&t=14,"Strawberry becomes encased in ice rapidly, and is visible when taken back out",Murray,Wan2.5,Done,Daniel Zhao,dz: completely rewrote prompt / scenario to match video. added timestamp to ref vid,"{hailuo2.3: [4, 1, 1], klingv2.5: [2, 4, 3], ray-2: [4, 3, 4], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4, 4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [1, 3, 1], ray-2: [3, 2, 2], seed-dance: [2, 3, 3], sora-2: [4, 4, 2], veo3: [4, 4], wan2.5: [4, 4, 3]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [2, 4, 4], ray-2: [4, 4, 4], seed-dance: [4, 4, 4], sora-2: [3, 4, 4], veo3: [4, 3], wan2.5: [3, 4, 4]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [1, 1, 2], ray-2: [1, 1, 1], seed-dance: [1, 1, 1], sora-2: [2, 3, 2], veo3: [3, 4], wan2.5: [2, 1, 1]}
","{hailuo2.3: [2, 2, 2], klingv2.5: [2, 4, 2], ray-2: [1, 1, 1], seed-dance: [3, 4, 4], sora-2: [4, 3, 4], veo3: [4, 4], wan2.5: [4, 4, 4]}
",36
Instant Ice Freeze Trick,Physics,"Nucleation, Phase transitions, Super-cooling","Show a water bottle filled with super-cooled water being tapped and instantly freezing into clear ice crystals around a frozen strawberry, with slow-motion camera from multiple angles.",https://www.youtube.com/watch?v=pVDqiYIxvdA,The water instantly crystallises around the strawberry when triggered.,Murray,Wan2.5,Not started,,dz: direct duplicate of one underneath,,,,,,35
Magneto-Ferrofluid Spiking,Physics,"Fluid Dynamics, Magnetism, Surface Tension","Extreme close-up, high-definition video of a black ferrofluid surface exposed to a powerful, hidden neodymium magnet underneath. The fluid surface forms sharp, dynamic ""spikes"" aligned along the magnetic field lines. Focus on the contrast between liquid and magnetic mechanical behavior.",https://www.youtube.com/watch?v=pVDqiYIxvdA,Fluid reorganization and shape distortion driven by strong magnetic fields interacting with magnetic nanoparticles.,Murray,Wan2.5,Not started,,,,,,,,34
Combustion CFD Flow Analysis,Physics,"Fluid Flow, Thermodynamics","Visualization of a computational fluid dynamics (CFD) simulation of a gas turbine combustion chamber. Overlay streamlines (Fluid Dynamics) representing velocity vectors onto thermal contours (Thermodynamics) showing extreme heat pockets, including modeled NOx and Soot formation regions (Kinetics). Scientific graphic aesthetic.",https://www.youtube.com/watch?v=3S2QNpVju1s,"Modeling the complex interaction of gas flow, heat release, and chemical species generation in a reaction environment.",Murray,Wan2.5,Not started,,,,,,,,33
Quantum Double Slit Experiment,Physics,"Photoelectric Effect, Quantum Mechanics, Wave Interference","Stylized, deep-blue and white visualization of single photons passing through a double-slit aperture. Initially, the photons hit the screen as discrete particles, but when unobserved, the accumulated pattern demonstrates characteristic wave interference (fringes). Animated quantum effects.",https://www.youtube.com/watch?v=QqY8fY0TqaQ,Demonstration of wave-particle duality and the role of observation in quantum mechanics.,Murray,Wan2.5,Not started,,,,,,,,32
Superheat Boiling Water,Physics,"Superheating, Thermodynamics",Superheated liquid water that has been heated far above its boiling point is added to a glass pitcher. A metal fork is then carefully inserted into the hot water.,https://www.youtube.com/watch?v=hm6IfpndHAg,"When the fork touches the superheated water, its rough surface and cooler temperature provide nucleation sites, triggering sudden and rapid boiling. Steam and bubbles form explosively throughout the liquid.",Murray,Wan2.5,Done,Daniel Zhao,dz: completely rewrote prompt / scenario to match video. added timestamp to ref vid,"{hailuo2.3: [3, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 2, 2], seed-dance: [4, 4, 2], sora-2: [4, 4, 4], veo3: [4, 4], wan2.5: [4, 4, 2]}
","{hailuo2.3: [2, 3, 4], klingv2.5: [4, 4, 4], ray-2: [4, 2, 1], seed-dance: [2, 4, 1], sora-2: [4, 2, 4], veo3: [4, 2], wan2.5: [4, 3, 1]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [1, 4, 4], seed-dance: [4, 4, 4], sora-2: [4, 4, 3], veo3: [3, 3], wan2.5: [4, 4, 4]}
","{hailuo2.3: [1, 3, 1], klingv2.5: [1, 1, 1], ray-2: [1, 1, 1], seed-dance: [1, 1, 1], sora-2: [3, 2, 2], veo3: [4, 4], wan2.5: [1, 1, 1]}
","{hailuo2.3: [2, 4, 3], klingv2.5: [4, 4, 4], ray-2: [1, 1, 1], seed-dance: [3, 4, 4], sora-2: [3, 3, 4], veo3: [4, 4], wan2.5: [4, 4, 4]}
",21
Spinning top,Physics,"Angular Momentum, Gravity, Gyroscopic Precession","A metal spinning top is placed at the center of a smooth tabletop. It is set in rapid rotation by hand using a twist of the fingers, with the tip in contact with the surface.",https://www.youtube.com/shorts/Jw0Tg8_OlUM,The top should start making larger and larger rotations due to the torque gravity.,Daniel Zhao,Wan2.5,Done,"Lanxiang Hu, Yixin Huang",lx: lgtm,see above attachment,,,,,4
Salt on vibration generator,Physics,"Resonance, Sound, Sound Waves","From a top-down view, a flat metal plate is attached horizontally to a vibration generator. A small amount of table salt is sprinkled evenly across the surface of the plate. The vibration frequency is gradually increased using a signal generator or connected smartphone.",https://youtu.be/rYrdiQckGhw?si=wSrWtrO7WheWKCTy&t=71,"As the frequency changes, the salt grains move and settle into distinct geometric patterns where the plate does not vibrate — the nodal lines of standing waves. Each frequency produces a unique pattern.",Daniel Zhao,Wan2.5,Makeup,,DZ: CHANGED,see above attachment,,,,,3
Tuning forks,Physics,"Resonance, Sound, Sound Waves","Two identical tuning forks are mounted upright on separate wooden bases placed side by side on a flat table. A light pendulum made of a small rubber ball suspended by a thin string hangs so that the ball  one prong of the second tuning fork. The first tuning fork is struck gently with a rubber mallet and held near the second one, both facing each other.",https://www.youtube.com/shorts/coDTlinuF2k,The tuning fork that is not hit should vibrate and cause the ball to start moving.,Daniel Zhao,Wan2.5,Done,"Lanxiang Hu, Yixin Huang",lx: lgtm,see above attachment,,,,,2
Acetone pour,Chemistry,"Heat, Solubility","A white styrofoam ball (approximately 5-8 cm in diameter) sits in a clear glass dish on a table.  A person holds a bottle of acetone and pours a steady stream directly onto the top of the styrofoam ball. ",https://youtu.be/U7fVDnc4mkE?si=_7yK66xcmF1_wYgR,"When acetone is poured onto the styrofoam ball, the ball will rapidly shrink, collapse, and appear to vanish, leaving behind only a small amount of a gooey, viscous substance in the clear glass dish. As the polystyrene dissolves, the large amount of trapped air is released, often visibly as small bubbles or a fizzing effect.",Abhilash,Sora-2,Done,"Daniel Zhao, Murray Kang",mk: good! dz: expected phenom more descriptive [fixed],,,,,,90
Electrostatic Shielding with Cup and Foil,Physics,"Electrostatics, Reflection",Wrap the outside of a paper cup with aluminum foil connected to ground and place a small electroscope leaf inside the cup opening.,https://www.youtube.com/watch?v=SFhHs8F4OfI,"External charged objects brought near the cup produce little response inside, showing field shielding by the conductor.",Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",Forrest: need 1 more keyword. Maybe Electrostatics?,"{'hailuo2.3': [4, 3, 4], 'seedance1pro': [4, 4, 3], 'sora2': [2, 3, 2], 'veo3.1': [3], 'wan2.5': [4, 4, 4], 'kling2.5turbo': [4, 4, 3], 'ray2': [1, 2, 1]}","{'hailuo2.3': [3, 2, 3], 'seedance1pro': [1, 2, 1], 'sora2': [2, 1, 2], 'veo3.1': [2], 'wan2.5': [2, 3, 2], 'kling2.5turbo': [4, 3, 4], 'ray2': [1, 1, 2]}","{'hailuo2.3': [4, 4, 3], 'seedance1pro': [4, 4, 4], 'sora2': [4, 4, 4], 'veo3.1': [4], 'wan2.5': [4, 4, 3], 'kling2.5turbo': [4, 4, 4], 'ray2': [1, 2, 1]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 1, 2], 'sora2': [1, 1, 1], 'veo3.1': [2], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [1, 1, 2], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [2, 1, 2], 'sora2': [2, 2, 1], 'veo3.1': [2], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [2, 2, 1], 'ray2': [1, 1, 1]}
",157
Compass Deflection by Simple Wire Loop,Physics,"Electrolysis, Magnetics",Place a small compass at the center of a single-turn wire loop and briefly connect the loop to a coin cell.,https://www.youtube.com/watch?v=FPoqvuWiHck,"The compass needle swings away from north while the current flows, indicating the magnetic field around the loop.",Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",Forrest: missing keywords. Probably Electric current and Magnetics?,"{'hailuo2.3': [4, 4, 3], 'seedance1pro': [3, 2, 3], 'sora2': [2, 3, 2], 'veo3.1': [4], 'wan2.5': [2, 2, 3], 'kling2.5turbo': [3, 3, 2], 'ray2': [4, 3, 4]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [3, 3, 2], 'sora2': [2, 1, 2], 'veo3.1': [4], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [2, 3, 2], 'ray2': [3, 3, 2]}","{'hailuo2.3': [4, 4, 3], 'seedance1pro': [4, 4, 4], 'sora2': [4, 3, 4], 'veo3.1': [4], 'wan2.5': [1, 2, 1], 'kling2.5turbo': [4, 4, 4], 'ray2': [4, 4, 3]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [4, 3, 4], 'sora2': [3, 4, 2], 'veo3.1': [4], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [2, 2, 3], 'ray2': [1, 1, 2]}","{'hailuo2.3': [2, 3, 2], 'seedance1pro': [2, 2, 3], 'sora2': [4, 4, 3], 'veo3.1': [3], 'wan2.5': [3, 3, 2], 'kling2.5turbo': [2, 1, 2], 'ray2': [1, 2, 1]}",158
Raw vs Cooked Egg Spin Test,Physics,"Friction, Inertia",Spin a raw egg and a cooked egg on a smooth surface; lightly stop each with a fingertip and then release.,https://www.youtube.com/watch?v=Y4JyV94y2_A,"The raw egg starts spinning again due to the fluid interior continuing to move, while the cooked egg remains at rest.",Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",,"{'hailuo2.3': [2, 3, 2], 'seedance1pro': [4, 4, 3], 'sora2': [4, 3, 4], 'veo3.1': [1], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [1, 2, 1], 'ray2': [2, 2, 3]}","{'hailuo2.3': [2, 3, 2], 'seedance1pro': [2, 2, 3], 'sora2': [3, 3, 2], 'veo3.1': [2], 'wan2.5': [2, 1, 2], 'kling2.5turbo': [1, 1, 2], 'ray2': [3, 2, 3]}","{'hailuo2.3': [2, 3, 2], 'seedance1pro': [4, 3, 4], 'sora2': [3, 3, 2], 'veo3.1': [2], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [4, 4, 3], 'ray2': [2, 2, 3]}","{'hailuo2.3': [1, 1, 2], 'seedance1pro': [1, 2, 1], 'sora2': [1, 1, 1], 'veo3.1': [4], 'wan2.5': [2, 2, 3], 'kling2.5turbo': [2, 1, 2], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [2, 3, 2], 'sora2': [4, 4, 3], 'veo3.1': [4], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [3, 2, 3], 'ray2': [1, 1, 2]}",159
Double Cone ‘Climbs’ Up V-Rails,Physics,"Friction, Gravity, Inertia","Front-on Medium Shot (looking up the incline). On a lab bench, show two straight metal rails forming a V-shape. The wide end of the ""V"" rests on a small block, making the entire track clearly incline upward from its narrow end. A hand places a wooden double cone (two cones joined at their bases) at the narrow, lowest point of the V-rails. 2. The hand gives the cone a gentle push.",https://www.youtube.com/watch?v=iTNsuP2aakk,The cone appears to roll uphill while its center of mass actually moves downward along the widening rails.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu","Forrest: the prompt may be too complicated, but overall LG. Haoyang:  No need to change the camera? a bit complicated. yujie: @Forrest Dai @Haoyang Yu will it be better now? I think this scene is a little complex so might need a longer context
Forrest: LG!","{'hailuo2.3': [2, 3, 1], 'seedance1pro': [1, 2, 1], 'sora2': [4, 4, 3], 'veo3.1': [3], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [4, 4, 3], 'ray2': [1, 1, 2]}
","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [2, 1, 1], 'sora2': [1, 2, 2], 'veo3.1': [2], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [1, 1, 2], 'ray2': [1, 2, 1]}
","{'hailuo2.3': [3, 3, 4], 'seedance1pro': [4, 4, 4], 'sora2': [4, 4, 3], 'veo3.1': [4], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [4, 4, 4], 'ray2': [3, 4, 3]}
","{'hailuo2.3': [1, 2, 2], 'seedance1pro': [2, 2, 1], 'sora2': [1, 2, 1], 'veo3.1': [1], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [1, 1, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 2], 'seedance1pro': [2, 2, 1], 'sora2': [2, 1, 2], 'veo3.1': [1], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [1, 1, 2], 'ray2': [1, 1, 1]}
",160
Ice–Salt Refraction Mirage,Physics,"Thermal Expansion, thermochemistry",Place ice cubes and a spoonful of salt in a clear glass of water and observe through the side as the mixture is gently stirred once.,https://www.instagram.com/reels/DP7p38KEryK/,The cup is covered in a layer of frost.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",,"{'hailuo2.3': [4, 4, 3], 'seedance1pro': [4, 3, 4], 'sora2': [4, 4, 4], 'veo3.1': [3], 'wan2.5': [3, 3, 2], 'kling2.5turbo': [2, 2, 3], 'ray2': [4, 4, 3]}","{'hailuo2.3': [3, 4, 3], 'seedance1pro': [3, 3, 2], 'sora2': [4, 4, 4], 'veo3.1': [3], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [2, 2, 3], 'ray2': [3, 3, 4]}
","{'hailuo2.3': [2, 3, 1], 'seedance1pro': [4, 4, 3], 'sora2': [1, 2, 1], 'veo3.1': [4], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [2, 2, 3], 'ray2': [4, 4, 3]}","{'hailuo2.3': [1, 1, 2], 'seedance1pro': [1, 2, 1], 'sora2': [1, 1, 1], 'veo3.1': [2], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [1, 1, 2], 'ray2': [2, 1, 2]}","{'hailuo2.3': [2, 3, 2], 'seedance1pro': [3, 3, 4], 'sora2': [3, 2, 3], 'veo3.1': [3], 'wan2.5': [4, 4, 3], 'kling2.5turbo': [3, 2, 3], 'ray2': [2, 2, 3]}",161
Mirror-Backed Thin-Film Colors,Physics,"Dispersion, Interference, Reflection",Spray a very thin soap film onto a small mirror and illuminate with white light at a shallow angle.,https://www.bilibili.com/video/BV1Pf4y1K7mt/?spm_id_from=333.337.search-card.all.click,Moving bands of vivid color appear as thickness gradients cause wavelength-dependent constructive and destructive interference with mirror reflections.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",,"{'hailuo2.3': [4, 4, 4], 'seedance1pro': [4, 3, 4], 'sora2': [2, 2, 2], 'veo3.1': [3], 'wan2.5': [4, 4, 3], 'kling2.5turbo': [3, 3, 3], 'ray2': [3, 2, 3]}","{'hailuo2.3': [4, 4, 3], 'seedance1pro': [3, 3, 3], 'sora2': [3, 2, 3], 'veo3.1': [3], 'wan2.5': [3, 3, 3], 'kling2.5turbo': [3, 3, 2], 'ray2': [3, 3, 3]}","{'hailuo2.3': [4, 4, 3], 'seedance1pro': [4, 4, 4], 'sora2': [2, 2, 3], 'veo3.1': [2], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [4, 4, 4], 'ray2': [3, 3, 2]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [4, 3, 4], 'sora2': [3, 3, 2], 'veo3.1': [1], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [2, 2, 3], 'ray2': [1, 1, 1]}","{'hailuo2.3': [2, 3, 2], 'seedance1pro': [4, 4, 3], 'sora2': [3, 3, 3], 'veo3.1': [3], 'wan2.5': [2, 2, 3], 'kling2.5turbo': [3, 2, 3], 'ray2': [1, 1, 2]}",162
Vortex Drain Accelerates Bottle Flow,Physics,"Bernoulli Effect, Gravity","Fill a plastic bottle with water, puncture a vent hole near the top, and swirl the bottle while uncapping to let water drain.",https://www.youtube.com/shorts/rP65s-Pay_M,A stable vortex forms and the water drains faster and smoothly because the rotating core lowers central pressure and keeps an air passage.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu","Forrest: keywords seem inaccurate. Centripetal force + Fluid Dynamics + Air pressure yujie @Forrest Dai I add Bernoulli Effect which I think is more suitable?
Forrest: LG!","{'hailuo2.3': [2, 3, 1], 'seedance1pro': [2, 1, 3], 'sora2': [4, 3, 4], 'veo3.1': [2], 'wan2.5': [2, 2, 3], 'kling2.5turbo': [4, 2, 3], 'ray2': [1, 2, 1]}","{'hailuo2.3': [2, 3, 1], 'seedance1pro': [1, 2, 1], 'sora2': [4, 3, 4], 'veo3.1': [2], 'wan2.5': [2, 1, 3], 'kling2.5turbo': [3, 2, 3], 'ray2': [1, 3, 2]}","{'hailuo2.3': [4, 3, 4], 'seedance1pro': [2, 1, 3], 'sora2': [4, 4, 3], 'veo3.1': [2], 'wan2.5': [3, 2, 4], 'kling2.5turbo': [3, 3, 2], 'ray2': [1, 2, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [1, 1, 2], 'sora2': [4, 3, 4], 'veo3.1': [1], 'wan2.5': [1, 2, 1], 'kling2.5turbo': [2, 3, 2], 'ray2': [1, 1, 2]}","{'hailuo2.3': [2, 3, 3], 'seedance1pro': [2, 1, 3], 'sora2': [4, 3, 4], 'veo3.1': [2], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [3, 3, 2], 'ray2': [1, 2, 2]}",163
Hot-and-Cold Bending Laser in Air,Physics,"Dispersion, Refraction",Create a warm air plume from a candle beside a cool background and pass a laser pointer’s beam just above the flame.,"https://www.youtube.com/watch?v=sft3QYZjNCU, https://www.reddit.com/r/aphextwin/comments/1jml9v7/cool_reflection_on_my_homemade_aphex_laser_lamp/",The beam shimmers and bends due to temperature-dependent index variations that act like moving lenses in the air.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",,"{'hailuo2.3': [2, 3, 4], 'seedance1pro': [3, 2, 4], 'sora2': [4, 3, 3], 'veo3.1': [3], 'wan2.5': [2, 4, 3], 'kling2.5turbo': [3, 3, 2], 'ray2': [4, 2, 3]}","{'hailuo2.3': [3, 2, 4], 'seedance1pro': [4, 3, 2], 'sora2': [4, 4, 3], 'veo3.1': [4], 'wan2.5': [3, 4, 3], 'kling2.5turbo': [2, 3, 4], 'ray2': [4, 2, 3]}","{'hailuo2.3': [1, 2, 3], 'seedance1pro': [4, 3, 4], 'sora2': [4, 2, 3], 'veo3.1': [3], 'wan2.5': [3, 2, 4], 'kling2.5turbo': [4, 4, 3], 'ray2': [4, 3, 2]}","{'hailuo2.3': [2, 1, 3], 'seedance1pro': [1, 2, 1], 'sora2': [2, 3, 1], 'veo3.1': [1], 'wan2.5': [1, 2, 2], 'kling2.5turbo': [2, 1, 2], 'ray2': [1, 3, 2]}","{'hailuo2.3': [3, 4, 2], 'seedance1pro': [4, 3, 4], 'sora2': [4, 4, 3], 'veo3.1': [4], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [3, 2, 4], 'ray2': [3, 4, 3]}",164
Magnet Slide with Nonuniform Damping,Physics,"Electromagnetism, Inertia, Magnetics",Construct a metal ramp with alternating copper and plastic strips and slide a strong magnet from the top.,https://m.youtube.com/shorts/3Dz55RBI8rU,"The magnet slows dramatically over copper sections yet speeds up over plastic, tracing a stop–go motion from eddy-current drag changes.",Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu","Forrest: keywords are not correct. More like Electromagnetic + eddy currents + Lenz's Law.  yujie: @Forrest Dai I think Electromagnetic and Magnetics, since eddy currents + Lenz's Law is part of them?
Forrest: LG!","{'hailuo2.3': [1, 2, 2], 'seedance1pro': [1, 1, 1], 'sora2': [4, 4, 3], 'veo3.1': [1], 'wan2.5': [1, 2, 1], 'kling2.5turbo': [3, 2, 4], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [1, 1, 2], 'sora2': [4, 4, 3], 'veo3.1': [1], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [2, 2, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 1, 2], 'sora2': [4, 3, 4], 'veo3.1': [2], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [2, 1, 3], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 1, 3], 'seedance1pro': [1, 2, 1], 'sora2': [3, 3, 2], 'veo3.1': [1], 'wan2.5': [1, 2, 1], 'kling2.5turbo': [1, 1, 1], 'ray2': [1, 3, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [2, 2, 1], 'sora2': [4, 2, 3], 'veo3.1': [1], 'wan2.5': [2, 1, 3], 'kling2.5turbo': [3, 2, 2], 'ray2': [1, 1, 2]}",165
Standing Wave Jump on String,Physics,"Hooke’s law, Interference",Drive a taut string with a small motor at a fixed frequency and slide a movable support to change the effective length.,https://www.youtube.com/shorts/VbIRVhObpjE,The pattern suddenly jumps from one mode shape to another as the length tunes through resonance conditions set by tension and elasticity.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",,"{'hailuo2.3': [1, 1, 2], 'seedance1pro': [1, 2, 3], 'sora2': [4, 4, 3], 'veo3.1': [1], 'wan2.5': [4, 3, 2], 'kling2.5turbo': [2, 3, 3], 'ray2': [4, 4, 2]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [3, 4, 2], 'sora2': [4, 4, 4], 'veo3.1': [1], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [2, 2, 1], 'ray2': [2, 2, 2]}","{'hailuo2.3': [4, 4, 3], 'seedance1pro': [2, 2, 2], 'sora2': [4, 4, 4], 'veo3.1': [1], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [2, 1, 3], 'ray2': [4, 4, 3]}","{'hailuo2.3': [1, 1, 2], 'seedance1pro': [1, 2, 1], 'sora2': [3, 4, 2], 'veo3.1': [1], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [2, 1, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [2, 2, 2], 'sora2': [4, 3, 4], 'veo3.1': [4], 'wan2.5': [1, 2, 1], 'kling2.5turbo': [1, 1, 1], 'ray2': [4, 3, 1]}",166
Dual-Spring Period Surprise,Physics,"Gravity, Hooke’s law, Simple harmonic motion",Mount a mass from one vertical spring and compare its oscillation to the same mass hung from two Identical springs connected end-to-end,https://www.youtube.com/watch?v=wYkmoZUyAAs,The series-spring system oscillates with a noticeably longer period because the effective spring constant is reduced.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",Haoyang: Maybe rephrase this part to make it clearer “two identical springs in series.” yujie: @Haoyang Yu is it better now? haoyang: LGTM mark as done,,,,,,167
Angular Momentum Surprise with Collapsing Props,Physics,"Angular Momentum, Friction, Inertia",Spin a turntable with two sliding masses near the rim and move the masses inward along radial tracks.,https://www.youtube.com/shorts/urOzHmzfpSk,The rotation speeds up and the platform resists external twists because the moment of inertia decreases while angular momentum stays constant.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu","Forrest: +“Angular momentum conservation“ for keyword yujie: @Forrest Dai just added. thx!
Forrest: LG!",,,,,,168
Polarization ‘Black Mirror’ on Phone,Physics,"Polarization, Reflection, Refraction","1. A smartphone on a table displays a solid white screen. 2. A hand holds a linear polarizer sheet just above the screen, showing both the screen and a glossy reflection of an overhead lamp on the sheet's surface. 3. The hand slowly rotates the polarizer. ","https://www.youtube.com/shorts/heQb31BaFoI, https://www.youtube.com/watch?v=r-9uMxmj-HQ",The screen brightness and the reflected glare extinguish at different angles because emitted polarization and reflected polarization do not match.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",,"{'hailuo2.3': [4, 3, 4], 'seedance1pro': [4, 3, 3], 'sora2': [4, 4, 4], 'veo3.1': [1], 'wan2.5': [4, 3, 2], 'kling2.5turbo': [4, 3, 4], 'ray2': [1, 4, 2]}","{'hailuo2.3': [4, 2, 3], 'seedance1pro': [2, 4, 3], 'sora2': [4,1,3], 'veo3.1': [3], 'wan2.5': [4, 4, 3], 'kling2.5turbo': [4, 3, 3], 'ray2': [2, 2, 3]}","{'hailuo2.3': [4, 3, 4], 'seedance1pro': [4, 4, 4], 'sora2': [4, 4, 4], 'veo3.1': [2], 'wan2.5': [3, 3, 2], 'kling2.5turbo': [4, 4, 1], 'ray2': [1, 2, 1]}","{'hailuo2.3': [2, 3, 2], 'seedance1pro': [4, 2, 3], 'sora2': [2, 2, 4], 'veo3.1': [2], 'wan2.5': [3, 3, 2], 'kling2.5turbo': [2, 1, 3], 'ray2': [1, 3, 1]}","{'hailuo2.3': [4, 4, 4], 'seedance1pro': [4, 4, 3], 'sora2': [4, 4, 4], 'veo3.1': [4], 'wan2.5': [4, 3, 2], 'kling2.5turbo': [4, 4, 4], 'ray2': [2, 2, 3]}",169
Water Jet Deflected Near Charged Comb with Laser Sheet,Physics,"Gravity, Reflection","Create a thin water jet from a bottle nozzle, then illuminate it with a laser sheet, later bring a charged plastic comb close to the stream.",https://www.youtube.com/shorts/7iQ9_X9sy10,"The lit jet bows toward the comb while still descending, making the curved path obvious as charge polarizes the water.",Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu","haoyang: Overall looks good! Maybe just add a note to bring the comb close to the stream, but not touch it. yujie: @Haoyang Yu is it ok now?  haoyang: LGTM","{'hailuo2.3': [2, 3, 2], 'seedance1pro': [2, 2, 3], 'sora2': [4, 4, 3], 'veo3.1': [4], 'wan2.5': [2, 3, 2], 'kling2.5turbo': [4, 4, 4], 'ray2': [4, 3, 4]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [2, 3, 2], 'sora2': [2, 2, 3], 'veo3.1': [3], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [2, 1, 2], 'ray2': [4, 3, 4]}","{'hailuo2.3': [2, 3, 2], 'seedance1pro': [4, 4, 3], 'sora2': [4, 4, 4], 'veo3.1': [4], 'wan2.5': [2, 2, 3], 'kling2.5turbo': [4, 4, 3], 'ray2': [4, 4, 3]}","{'hailuo2.3': [1, 1, 2], 'seedance1pro': [1, 2, 1], 'sora2': [2, 1, 2], 'veo3.1': [2], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [1, 1, 2], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [1, 1, 2], 'sora2': [4, 3, 4], 'veo3.1': [3], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [2, 1, 2], 'ray2': [1, 1, 2]}",148
Mirrored Tank Corner Beam Trap,Physics,"Interference, Reflection, Refraction",Send a thin laser sheet into the edge of a clear acrylic block and adjust entry angle along the long face.,https://www.youtube.com/watch?v=YQ4SnBa7bj4,The beam becomes trapped by total internal reflection and forms bright nodes along the path where partial scattering interferes.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",,"{'hailuo2.3': [4, 4, 3], 'seedance1pro': [4, 4, 4], 'sora2': [4, 3, 4], 'veo3.1': [4], 'wan2.5': [4, 4, 3], 'kling2.5turbo': [1, 2, 1], 'ray2': [3, 3, 4]}","{'hailuo2.3': [4, 4, 4], 'seedance1pro': [4, 3, 4], 'sora2': [4, 4, 3], 'veo3.1': [4], 'wan2.5': [4, 4, 4], 'kling2.5turbo': [3, 3, 2], 'ray2': [3, 3, 4]}","{'hailuo2.3': [4, 4, 4], 'seedance1pro': [4, 4, 3], 'sora2': [4, 4, 4], 'veo3.1': [4], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [4, 4, 4], 'ray2': [2, 3, 2]}","{'hailuo2.3': [1, 1, 2], 'seedance1pro': [1, 2, 1], 'sora2': [1, 1, 1], 'veo3.1': [3], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [2, 1, 2], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [4, 3, 4], 'sora2': [4, 4, 3], 'veo3.1': [4], 'wan2.5': [3, 3, 2], 'kling2.5turbo': [4, 4, 4], 'ray2': [1, 1, 2]}",149
Thin-Film Colors Between Plates,Physics,"Dispersion, Interference, Refraction",Top-down macro shot on a dark lab bench. 1. A hand places a water droplet on a flat glass plate. 2. A second plate is pressed on top. 3. A white light illuminates.,https://www.bilibili.com/video/BV1YM411u7ao/?spm_id_from=333.337.search-card.all.click,Concentric colored fringes emerge as a Newton’s ring pattern from path‑length differences.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",,"{'hailuo2.3': [4, 3, 4], 'seedance1pro': [2, 3, 2], 'sora2': [4, 4, 3], 'veo3.1': [3], 'wan2.5': [4, 4, 3], 'kling2.5turbo': [3, 2, 3], 'ray2': [1, 2, 1]}","{'hailuo2.3': [2, 2, 3], 'seedance1pro': [3, 2, 3], 'sora2': [2, 1, 2], 'veo3.1': [2], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [3, 3, 2], 'ray2': [1, 2, 1]}","{'hailuo2.3': [2, 3, 1], 'seedance1pro': [4, 4, 3], 'sora2': [1, 2, 1], 'veo3.1': [4], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [4, 4, 3], 'ray2': [1, 1, 2]}","{'hailuo2.3': [2, 1, 2], 'seedance1pro': [1, 2, 1], 'sora2': [2, 2, 1], 'veo3.1': [2], 'wan2.5': [2, 2, 3], 'kling2.5turbo': [2, 1, 2], 'ray2': [1, 1, 2]}","{'hailuo2.3': [4, 3, 4], 'seedance1pro': [2, 3, 2], 'sora2': [3, 3, 2], 'veo3.1': [3], 'wan2.5': [3, 4, 3], 'kling2.5turbo': [4, 4, 3], 'ray2': [1, 1, 1]}
",150
Magnet Slow Slide on Aluminum Ramp,Physics,"Friction, Inertia, Magnetics",Compare a strong magnet and a steel block sliding down the same aluminum ramp.,https://m.youtube.com/shorts/3Dz55RBI8rU,The magnet creeps slowly due to eddy-current drag while the steel block slides freely.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",,"{'hailuo2.3': [4, 4, 3], 'seedance1pro': [4, 4, 4], 'sora2': [4, 3, 4], 'veo3.1': [4], 'wan2.5': [3, 4, 3], 'kling2.5turbo': [4, 4, 3], 'ray2': [1, 2, 1]}","{'hailuo2.3': [4, 3, 4], 'seedance1pro': [2, 3, 2], 'sora2': [4, 4, 3], 'veo3.1': [2], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [3, 3, 2], 'ray2': [1, 2, 1]}","{'hailuo2.3': [4, 4, 3], 'seedance1pro': [2, 3, 2], 'sora2': [4, 4, 4], 'veo3.1': [4], 'wan2.5': [2, 2, 3], 'kling2.5turbo': [4, 3, 4], 'ray2': [4, 4, 3]}","{'hailuo2.3': [2, 1, 2], 'seedance1pro': [1, 2, 1], 'sora2': [2, 2, 1], 'veo3.1': [1], 'wan2.5': [2, 1, 2], 'kling2.5turbo': [2, 2, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 1, 2], 'seedance1pro': [1, 2, 1], 'sora2': [2, 1, 2], 'veo3.1': [1], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [2, 1, 2], 'ray2': [1, 1, 1]}",151
Laser Speckle with Moving Screen,Physics,"Interference, Reflection",Extreme close-up (macro) on a diffuse white card in a dim room. 1. A laser pointer illuminates a single spot. 2. The card is slowly slid laterally,https://www.youtube.com/watch?v=xuzuFPl8rh0,The speckle texture appears to drift opposite to the card motion because of phase interference.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",,"{'hailuo2.3': [3, 3, 4], 'seedance1pro': [3, 4, 3], 'sora2': [3, 3, 3], 'veo3.1': [4], 'wan2.5': [4, 4, 3], 'kling2.5turbo': [4, 3, 4], 'ray2': [3, 3, 4]}","{'hailuo2.3': [2, 3, 1], 'seedance1pro': [4, 4, 3], 'sora2': [1, 3, 2], 'veo3.1': [4], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [2, 2, 3], 'ray2': [1, 2, 1]}","{'hailuo2.3': [4, 4, 3], 'seedance1pro': [4, 4, 4], 'sora2': [4, 3, 4], 'veo3.1': [4], 'wan2.5': [4, 4, 4], 'kling2.5turbo': [4, 4, 3], 'ray2': [1, 2, 1]}","{'hailuo2.3': [1, 1, 2], 'seedance1pro': [1, 2, 1], 'sora2': [1, 3, 3], 'veo3.1': [3], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [1, 1, 2], 'ray2': [2, 1, 2]}","{'hailuo2.3': [2, 3, 2], 'seedance1pro': [2, 2, 3], 'sora2': [1, 2, 4], 'veo3.1': [3], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [2, 2, 1], 'ray2': [2, 1, 2]}",152
Photoelastic Plastic Fork,Physics,"Dispersion, Polarization, Refraction",Static close-up looking through two crossed polarizers (field is dark) on a light table. 1. A clear plastic fork is placed between the polarizers. 2. The fork is rotated slowly.,https://www.youtube.com/watch?v=jFwm3TIC750,Colorful stress fringes appear and change with rotation as polarization components shift.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",,"{'hailuo2.3': [1, 2, 1], 'seedance1pro': [4, 3, 4], 'sora2': [2, 3, 2], 'veo3.1': [4], 'wan2.5': [2, 3, 2], 'kling2.5turbo': [4, 4, 3], 'ray2': [1, 1, 2]}
","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [4, 4, 3], 'sora2': [3, 2, 4], 'veo3.1': [4], 'wan2.5': [1, 2, 1], 'kling2.5turbo': [2, 3, 2], 'ray2': [1, 1, 2]}","{'hailuo2.3': [4, 4, 3], 'seedance1pro': [4, 4, 4], 'sora2': [4, 3, 4], 'veo3.1': [4], 'wan2.5': [1, 2, 1], 'kling2.5turbo': [1, 1, 2], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [1, 1, 2], 'sora2': [3, 2, 3], 'veo3.1': [4], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [1, 2, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [1, 1, 2], 'sora2': [1, 3, 1], 'veo3.1': [2], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [1, 1, 2], 'ray2': [1, 1, 1]}
",153
Loop-the-Loop Release Test,Physics,"Gravity, Projectile Motion"," Static side-view medium shot framing an entire vertical loop track on a table. 1. (First attempt) A marble is released from a low ramp height  2. (Second attempt) The marble is released from a high ramp height and successfully",https://www.youtube.com/shorts/GoAN6oLkaiQ,1. (First attempt) A marble is released from a low ramp height and falls from the top of the loop. 2. (Second attempt) The marble is released from a high ramp height and successfully completes the loop.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",,"{'hailuo2.3': [4, 3, 4], 'seedance1pro': [1, 2, 1], 'sora2': [4, 4, 3], 'veo3.1': [1], 'wan2.5': [1, 2, 1], 'kling2.5turbo': [4, 4, 3], 'ray2': [1, 1, 2]}","{'hailuo2.3': [3, 2, 3], 'seedance1pro': [1, 2, 1], 'sora2': [4, 3, 4], 'veo3.1': [1], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [1, 2, 1], 'ray2': [2, 1, 2]}","{'hailuo2.3': [2, 3, 2], 'seedance1pro': [2, 1, 2], 'sora2': [4, 3, 4], 'veo3.1': [1], 'wan2.5': [1, 2, 1], 'kling2.5turbo': [4, 4, 3], 'ray2': [2, 2, 1]}","{'hailuo2.3': [1, 1, 2], 'seedance1pro': [1, 2, 1], 'sora2': [2, 1, 2], 'veo3.1': [1], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [2, 1, 2], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [2, 3, 2], 'sora2': [4, 4, 3], 'veo3.1': [2], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [4, 3, 4], 'ray2': [1, 1, 2]}",154
Breath Fog on Cold Spoon,Physics,"Dispersion, Phase Change, Reflection","Chill a metal spoon, breathe onto the surface, and hold it under a bright lamp.",https://www.facebook.com/utwente/videos/enhancing-breath-figureswhenever-you-breathe-on-a-cold-surface-you-will-see-drop/1966142683417115/,"Condensation forms then clears as the film evaporates, restoring a sharp reflection with subtle color tints.",Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu","Forrest: can add “phase change” for keywords yujie: @Forrest Dai is it ok now?
Forrest: LG!","{'hailuo2.3': [4, 4, 3], 'seedance1pro': [4, 4, 4], 'sora2': [4, 3, 4], 'veo3.1': [3], 'wan2.5': [4, 4, 4], 'kling2.5turbo': [4, 3, 4], 'ray2': [1, 2, 1]}","{'hailuo2.3': [2, 1, 2], 'seedance1pro': [1, 2, 1], 'sora2': [2, 2, 3], 'veo3.1': [2], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [1, 1, 2], 'ray2': [1, 1, 1]}","{'hailuo2.3': [4, 3, 4], 'seedance1pro': [4, 4, 3], 'sora2': [4, 4, 4], 'veo3.1': [2], 'wan2.5': [4, 4, 3], 'kling2.5turbo': [3, 2, 3], 'ray2': [1, 2, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [1, 1, 2], 'sora2': [2, 2, 3], 'veo3.1': [2], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [2, 1, 2], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [1, 1, 2], 'sora2': [3, 2, 3], 'veo3.1': [2], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [3, 3, 2], 'ray2': [1, 1, 2]}",155
Balloon on Wall then Fall,Physics,"Electrostatics, Gravity","After quickly rubbing a latex balloon against a wool cloth, the hand presses it firmly to the wall. The hand is then pulled away",https://www.bilibili.com/video/BV1Wm4y157P7/?spm_id_from=333.337.search-card.all.click,The balloon sticks by electrostatic attraction and later falls as charge dissipates.,Yujie Zhao,Wan2.5,Not started,"Forrest Dai, Haoyang Yu",Haoyang: Maybe add a short intro like “The scene happens in the following order.” Right now it feels like all the actions happen at the same time.,,,,,,170
Laser Vanishes Between Crossed Polarizers with Tape,Physics,"Interference, Polarization, Reflection","Arrange two linear polarizers orthogonal to each other and shine a small laser spot through them, then insert a piece of transparent tape between the sheets.",https://www.instagram.com/reel/Cu1hRwFomkG/,The dark field brightens where the tape sits because the film rotates polarization and creates constructive transmission patterns.,Yujie Zhao,Wan2.5,Done,"Forrest Dai, Haoyang Yu",,"{'hailuo2.3': [1, 2, 1], 'seedance1pro': [3, 2, 3], 'sora2': [1, 3, 2], 'veo3.1': [4], 'wan2.5': [1, 2, 1], 'kling2.5turbo': [4, 3, 4], 'ray2': [1, 1, 2]}","{'hailuo2.3': [1, 2, 3], 'seedance1pro': [2, 1, 2], 'sora2': [1, 2, 2], 'veo3.1': [1], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [3, 2, 3], 'ray2': [1, 1, 1]}","{'hailuo2.3': [2, 3, 2], 'seedance1pro': [3, 4, 3], 'sora2': [4, 3, 4], 'veo3.1': [3], 'wan2.5': [1, 2, 1], 'kling2.5turbo': [4, 4, 3], 'ray2': [2, 2, 3]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 1, 3], 'sora2': [1, 2, 1], 'veo3.1': [1], 'wan2.5': [1, 1, 3], 'kling2.5turbo': [1, 1, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [2, 1, 2], 'sora2': [1, 1, 1], 'veo3.1': [2], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [1, 1, 1], 'ray2': [1, 1, 1]}",156
Head-On Magnetic Collision Between Two Identical Carts,Physics,"Elastic Collision, Magnetics, Momentum Conservation","Two identical carts sit on a frictionless track. Each cart carries a magnet, and they have magnets that oppose each other. The carts are released at the same time and move toward each other at equal speed.",https://www.youtube.com/watch?v=jRliH0jVilM&t=90s,"As the two carts approach, magnetic repulsion decelerates both equally until they momentarily stop near the center. Then, they reverse direction and move away with the same speed in opposite directions.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai","Forrest: “opposite poles” in prompt should be “same poles”; or use what the prof said in video, “they have magnets that oppose each other” （ ✅ fixed）

Abhilash: The video looks slow-mo, can we mention we have very strong magnets attached in the prompt. And also I don’t think we should mention about speed in the prompt.","{'hailuo2.3': [4, 2, 2], 'seedance1pro': [2, 4, 3], 'sora2': [3, 4, 4], 'veo3.1': [3, 1], 'wan2.5': [2, 4, 3], 'kling2.5turbo': [4, 4, 4], 'ray2': [4, 4, 1]}","{'hailuo2.3': [4, 2, 2], 'seedance1pro': [1, 2, 2], 'sora2': [3, 3, 3], 'veo3.1': [3, 2], 'wan2.5': [2, 2, 2], 'kling2.5turbo': [4, 4, 4], 'ray2': [4, 4, 1]}","{'hailuo2.3': [4, 3, 3], 'seedance1pro': [3, 4, 3], 'sora2': [3, 4, 3], 'veo3.1': [3, 3], 'wan2.5': [3, 3, 2], 'kling2.5turbo': [4, 4, 4], 'ray2': [4, 4, 1]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 1, 2], 'sora2': [3, 3, 3], 'veo3.1': [3, 3], 'wan2.5': [3, 2, 1], 'kling2.5turbo': [4, 1, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 3, 3], 'seedance1pro': [4, 3, 3], 'sora2': [4, 3, 3], 'veo3.1': [4, 3], 'wan2.5': [4, 4, 2], 'kling2.5turbo': [4, 1, 1], 'ray2': [1, 1, 1]}",134
Holding and Releasing a Ball on a Spinning Turntable,Physics,"Centripetal Force, Friction, Inertia","From a top-down view, a small ball is held at a fixed position on a spinning turntable. After the turntable reaches a steady speed, the ball is held until it rotates at the same speed as the turntable, and then it is gently released without any push.",https://www.youtube.com/watch?v=3oM7hX3UUEU&t=10s,"After being released, the ball stays in its position relative to the spinning surface, it continues rotating with the same angular speed and does not slide outward.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai","Forrest: In the prompt, we need to emphasize that “the ball reaches the same rotational speed as the turntable” when released （ ✅ fixed）","{'hailuo2.3': [1, 2, 3], 'seedance1pro': [4, 1, 4], 'sora2': [4, 4, 4], 'veo3.1': [4, 1], 'wan2.5': [4, 3, 3], 'kling2.5turbo': [4, 3, 3], 'ray2': [2, 1, 3]}","{'hailuo2.3': [1, 2, 2], 'seedance1pro': [3, 2, 3], 'sora2': [4, 4, 2], 'veo3.1': [4, 1], 'wan2.5': [3, 2, 2], 'kling2.5turbo': [2, 2, 2], 'ray2': [2, 2, 3]}","{'hailuo2.3': [4, 4, 2], 'seedance1pro': [4, 3, 3], 'sora2': [4, 4, 3], 'veo3.1': [4, 2], 'wan2.5': [4, 3, 3], 'kling2.5turbo': [3, 2, 2], 'ray2': [3, 3, 4]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 1, 3], 'sora2': [2, 1, 1], 'veo3.1': [1, 1], 'wan2.5': [2, 1, 1], 'kling2.5turbo': [3, 1, 1], 'ray2': [3, 1, 2]}","{'hailuo2.3': [1, 2, 3], 'seedance1pro': [2, 3, 4], 'sora2': [4, 3, 4], 'veo3.1': [3, 2], 'wan2.5': [2, 2, 2], 'kling2.5turbo': [3, 2, 2], 'ray2': [2, 2, 2]}",131
A Ball Dropped Off-Center on a Spinning Turntable,Physics,"Centripetal Force, Friction, Inertia","From a top-down view, a small ball is dropped onto a spinning turntable near its outer edge rather than at the center.",https://www.youtube.com/watch?v=3oM7hX3UUEU&t=10s,"When the ball touches the spinning surface off-center, it immediately flies outward.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",,"{'hailuo2.3': [4, 4, 4], 'seedance1pro': [4, 4, 1], 'sora2': [4, 4, 4], 'veo3.1': [4, 4], 'wan2.5': [1, 4, 4], 'kling2.5turbo': [4, 4, 4], 'ray2': [4, 1, 2]}","{'hailuo2.3': [2, 2, 2], 'seedance1pro': [2, 2, 1], 'sora2': [3, 4, 2], 'veo3.1': [2, 2], 'wan2.5': [2, 2, 2], 'kling2.5turbo': [3, 2, 4], 'ray2': [2, 1, 1]}","{'hailuo2.3': [2, 3, 3], 'seedance1pro': [1, 3, 2], 'sora2': [4, 4, 4], 'veo3.1': [4, 2], 'wan2.5': [2, 2, 4], 'kling2.5turbo': [4, 2, 4], 'ray2': [1, 1, 3]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 1, 1], 'sora2': [1, 1, 1], 'veo3.1': [2, 1], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [1, 1, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [3, 3, 3], 'seedance1pro': [3, 3, 2], 'sora2': [3, 3, 3], 'veo3.1': [3, 2], 'wan2.5': [3, 3, 3], 'kling2.5turbo': [4, 3, 4], 'ray2': [4, 1, 2]}",130
Place A Penny on a Turntable,Physics,"Centripetal Force, Friction, Inertia","From a top-down view, a penny lies flat near the center of a turntable, which is then set spinning.",https://www.youtube.com/watch?v=3oM7hX3UUEU&t=10s,"At first, friction keeps the penny still on the turntable. Over time, it directly slips out of the turntable.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",,"{'hailuo2.3': [2, 4, 4], 'seedance1pro': [4, 3, 2], 'sora2': [4, 4, 4], 'veo3.1': [4, 4], 'wan2.5': [3, 4, 3], 'kling2.5turbo': [2, 4, 4], 'ray2': [4, 3, 3]}","{'hailuo2.3': [2, 2, 4], 'seedance1pro': [4, 4, 2], 'sora2': [2, 2, 4], 'veo3.1': [4, 4], 'wan2.5': [2, 1, 3], 'kling2.5turbo': [2, 2, 4], 'ray2': [4, 2, 1]}","{'hailuo2.3': [2, 4, 3], 'seedance1pro': [4, 3, 2], 'sora2': [2, 4, 3], 'veo3.1': [4, 4], 'wan2.5': [2, 4, 3], 'kling2.5turbo': [3, 2, 4], 'ray2': [4, 4, 3]}","{'hailuo2.3': [1, 1, 2], 'seedance1pro': [3, 2, 1], 'sora2': [2, 2, 2], 'veo3.1': [3, 1], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [2, 2, 2], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 3], 'seedance1pro': [3, 4, 3], 'sora2': [3, 4, 2], 'veo3.1': [4, 2], 'wan2.5': [3, 4, 4], 'kling2.5turbo': [2, 2, 2], 'ray2': [2, 3, 1]}",129
Two Balls Released from the Same Height,Physics,"Gravity, Projectile Motion","From a side view, two identical balls start at the same height. One is pushed horizontally off the edge of a table, while the other is released from rest at the same instant directly above the floor.",https://www.youtube.com/watch?v=aY8z2qO44WA,"Both balls hit the ground at the same time because their vertical motions are identical. The ball that rolled off the table lands farther horizontally since it has a non-zero horizontal velocity, while the dropped ball lands directly below its release point.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",,"{'hailuo2.3': [1, 4, 4], 'seedance1pro': [3, 1, 1], 'sora2': [4, 2, 4], 'veo3.1': [1, 1], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [2, 4, 4], 'ray2': [4, 1, 1]}","{'hailuo2.3': [3, 3, 2], 'seedance1pro': [3, 1, 1], 'sora2': [2, 3, 2], 'veo3.1': [2, 2], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [3, 2, 2], 'ray2': [2, 2, 1]}","{'hailuo2.3': [3, 3, 2], 'seedance1pro': [2, 1, 1], 'sora2': [3, 2, 2], 'veo3.1': [2, 2], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [3, 3, 2], 'ray2': [2, 1, 1]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 1, 1], 'sora2': [1, 1, 1], 'veo3.1': [1, 1], 'wan2.5': [3, 1, 1], 'kling2.5turbo': [1, 1, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 2, 2], 'seedance1pro': [1, 1, 2], 'sora2': [2, 1, 2], 'veo3.1': [1, 1], 'wan2.5': [3, 1, 2], 'kling2.5turbo': [1, 1, 1], 'ray2': [1, 1, 1]}",147
A Ball Launched Upward at an Angle from a Table Edge,Physics,"Gravity, Projectile Motion","From the edge of a table, a small rubber ball is launched upward at an angle using a slanted ramp.",https://www.youtube.com/watch?v=aY8z2qO44WA,"The ball first rises and then falls along a curved parabolic path, traveling forward before hitting the ground.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",Abhilash: I don’t think we should describe the expected motion in the prompt (fixed),"{'hailuo2.3': [2, 2, 4], 'seedance1pro': [1, 1, 4], 'sora2': [3, 4, 3], 'veo3.1': [3, 3], 'wan2.5': [2, 3, 3], 'kling2.5turbo': [4, 4, 4], 'ray2': [2, 1, 1]}","{'hailuo2.3': [2, 2, 3], 'seedance1pro': [1, 1, 1], 'sora2': [2, 3, 1], 'veo3.1': [3, 3], 'wan2.5': [2, 1, 2], 'kling2.5turbo': [4, 3, 2], 'ray2': [2, 1, 1]}","{'hailuo2.3': [2, 2, 3], 'seedance1pro': [1, 1, 3], 'sora2': [2, 2, 2], 'veo3.1': [2, 3], 'wan2.5': [2, 2, 3], 'kling2.5turbo': [3, 2, 3], 'ray2': [1, 1, 1]}","{'hailuo2.3': [3, 1, 4], 'seedance1pro': [1, 1, 1], 'sora2': [2, 1, 1], 'veo3.1': [3, 1], 'wan2.5': [1, 2, 2], 'kling2.5turbo': [3, 1, 3], 'ray2': [1, 1, 1]}","{'hailuo2.3': [3, 1, 4], 'seedance1pro': [1, 1, 1], 'sora2': [2, 2, 3], 'veo3.1': [2, 1], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [3, 2, 4], 'ray2': [1, 1, 1]}",146
Turmeric Indicator Reaction with Detergent,Chemistry,"Acid-Base Reaction, Indicator color change","A glass of water is prepared, and a small amount of turmeric powder is added and stirred until the solution turns yellow. Then, a spoonful of detergent powder is added and mixed.",https://www.youtube.com/shorts/TK3Rsbg2Uco,"After adding the powder, the yellow turmeric solution turns reddish-brown.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",Abhilash: Replace “surf excel” with “detergent powder”. Surf excel is a detergent brand I don’t know if model knows it.  (fixed),"{'hailuo2.3': [4, 4, 4], 'seedance1pro': [2, 2, 2], 'sora2': [4, 4, 4], 'veo3.1': [4, 4], 'wan2.5': [3, 3, 4], 'kling2.5turbo': [1, 4, 4], 'ray2': [3, 2, 3]}","{'hailuo2.3': [4, 2, 3], 'seedance1pro': [2, 2, 3], 'sora2': [4, 4, 3], 'veo3.1': [4, 4], 'wan2.5': [2, 2, 2], 'kling2.5turbo': [2, 2, 2], 'ray2': [3, 1, 2]}","{'hailuo2.3': [3, 3, 3], 'seedance1pro': [3, 2, 3], 'sora2': [2, 3, 2], 'veo3.1': [3, 3], 'wan2.5': [3, 3, 3], 'kling2.5turbo': [4, 3, 4], 'ray2': [3, 2, 3]}","{'hailuo2.3': [2, 1, 4], 'seedance1pro': [1, 1, 1], 'sora2': [2, 1, 4], 'veo3.1': [4, 1], 'wan2.5': [2, 1, 1], 'kling2.5turbo': [1, 1, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [4, 3, 4], 'seedance1pro': [4, 3, 2], 'sora2': [4, 4, 4], 'veo3.1': [4, 4], 'wan2.5': [4, 4, 4], 'kling2.5turbo': [4, 4, 4], 'ray2': [2, 2, 2]}",145
A Billiard Ball Rolling Inside a Ring,Physics,"Centripetal Force, Inertia","A billiard ball is placed inside a circular ring and rolled along the inner wall so that it moves continuously in a circular path. While the ball is rolling, the ring is suddenly lifted upward, removing the circular constraint.",https://www.youtube.com/watch?v=yAfg_8OLjvs,The ball no longer experiences the inward centripetal force and moves straight along the tangent direction from the point where it lost contact with the ring.,Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",,"{'hailuo2.3': [2, 1, 3], 'seedance1pro': [3, 2, 2], 'sora2': [4, 4, 4], 'veo3.1': [4, 2], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [4, 4, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 1, 2], 'seedance1pro': [2, 1, 1], 'sora2': [3, 2, 3], 'veo3.1': [2, 1], 'wan2.5': [3, 1, 2], 'kling2.5turbo': [3, 2, 1], 'ray2': [1, 1, 2]}","{'hailuo2.3': [2, 2, 3], 'seedance1pro': [3, 2, 3], 'sora2': [2, 2, 4], 'veo3.1': [3, 2], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [4, 4, 3], 'ray2': [1, 3, 3]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [2, 1, 1], 'sora2': [1, 1, 2], 'veo3.1': [2, 1], 'wan2.5': [1, 1, 3], 'kling2.5turbo': [2, 1, 2], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [2, 2, 2], 'sora2': [2, 3, 3], 'veo3.1': [3, 3], 'wan2.5': [1, 1, 4], 'kling2.5turbo': [2, 3, 2], 'ray2': [1, 1, 1]}",144
Head-On Velcro Collision Between Two Identical Carts,Physics,"Inelastic Collision, Kinetic Energy Loss, Momentum Conservation",Two identical-mass carts sit on a low-friction track. Both carts have Velcro pads facing each other. Both carts are pushed toward each other at the same speed.,https://www.youtube.com/watch?v=jRliH0jVilM&t=90s,"The two carts approach, collide, and stick together at the center. Because their momenta are equal and opposite, the combined object remains at rest after collision.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",,"{'hailuo2.3': [4, 2, 4], 'seedance1pro': [4, 1, 4], 'sora2': [4, 4, 4], 'veo3.1': [4, 4], 'wan2.5': [4, 4, 4], 'kling2.5turbo': [4, 4, 4], 'ray2': [4, 4, 3]}","{'hailuo2.3': [3, 2, 2], 'seedance1pro': [3, 1, 2], 'sora2':[4, 4, 4], 'veo3.1': [3, 2], 'wan2.5': [3, 2, 4], 'kling2.5turbo': [2, 3, 3], 'ray2': [3, 3, 2]}","{'hailuo2.3': [2, 3, 3], 'seedance1pro': [4, 2, 3], 'sora2': [4, 4, 4], 'veo3.1': [3, 4], 'wan2.5': [3, 3, 4], 'kling2.5turbo': [4, 4, 3], 'ray2': [4, 4, 3]}","{'hailuo2.3': [3, 1, 3], 'seedance1pro': [1, 1, 1], 'sora2': [4, 4, 4], 'veo3.1': [3, 2], 'wan2.5': [3, 1, 4], 'kling2.5turbo': [1, 4, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [4, 2, 4], 'seedance1pro': [4, 2, 1], 'sora2': [4, 2, 4], 'veo3.1': [4, 3], 'wan2.5': [3, 1, 4], 'kling2.5turbo': [4, 4, 1], 'ray2': [1, 1, 1]}",136
Velcro-Coupled Collision Between Two Identical Carts,Physics,"Inelastic Collision, Kinetic Energy Loss, Momentum Conservation",Two identical-mass carts sit on a low-friction track. Both carts have Velcro pads facing each other. The right cart is pushed toward it with an initial speed.,https://www.youtube.com/watch?v=jRliH0jVilM&t=90s,"After impact, the two carts stick and move together in the original direction at a slower speed. ",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",,"{'hailuo2.3': [4, 2, 3], 'seedance1pro': [4, 3, 3], 'sora2': [4, 4, 4], 'veo3.1': [4, 4], 'wan2.5': [4, 3, 4], 'kling2.5turbo': [4, 2, 4], 'ray2': [4, 2, 1]}","{'hailuo2.3': [4, 1, 2], 'seedance1pro': [2, 3, 2], 'sora2': [2, 2, 3], 'veo3.1': [2, 2], 'wan2.5': [4, 2, 3], 'kling2.5turbo': [3, 2, 2], 'ray2': [4, 3, 1]}","{'hailuo2.3': [3, 3, 3], 'seedance1pro': [3, 3, 3], 'sora2': [3, 2, 3], 'veo3.1': [3, 2], 'wan2.5': [4, 2, 3], 'kling2.5turbo': [4, 3, 3], 'ray2': [4, 3, 2]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 1, 2], 'sora2': [1, 2, 1], 'veo3.1': [1, 2], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [4, 2, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 3, 1], 'sora2': [2, 4, 3], 'veo3.1': [2, 3], 'wan2.5': [3, 2, 4], 'kling2.5turbo': [4, 4, 1], 'ray2': [1, 1, 1]}",135
Hand-crank Lightbulb,Physics,"Energy Conversion, Rotational Dynamics, Simple circuit lighting",A person is standing next to a brown table with a hand-crank that is connected to a generator and a light bulb. He begins continuously turning the hand-crank.,https://www.youtube.com/watch?v=8_zee2rRVkM,The light starts lighting up and flashing after the person turns the handle. The lightbulb should also pulse with respect to when the hand is doing the most motion.,Daniel Zhao,Wan2.5,Done,"Lanxiang Hu, Yixin Huang",lx: lgtm,see above attachment,,,,,1
never spilling bag,Physics,"Polymers, Statistical equilibrium","Pierce a pencil through the water-filled section of a plastic bag filled with water and out the other side, while keeping the pencil in place.",https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,The water doesn’t not leak.,Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: looks good yujie: LGTM,"{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 4, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [3, 2, 4], ‘kling2.5turbo’: [4, 4, 3], ‘ray2’: [4, 4, 3]}","{’hailuo2.3’: [4, 3, 4], ‘seedance1pro’: [4,4, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [3, 4, 4], ‘kling2.5turbo’: [4, 3, 2], ‘ray2’: [3, 3, 1]}","{'hailuo2.3': [4, 3, 3], 'seedance1pro': [4, 4, 4], 'sora2': [4, 4, 4], 'veo3.1': [3], 'wan2.5': [2, 3, 4], 'kling2.5turbo': [4, 4, 2], 'ray2': [2, 4, 2]}","{'hailuo2.3': [1, 2, 3], 'seedance1pro': [3, 4, 4], 'sora2': [1, 3, 4], 'veo3.1': [3], 'wan2.5': [3, 4, 4], 'kling2.5turbo': [3, 4, 1], 'ray2': [1, 2, 1]}","{'hailuo2.3': [1, 2, 3], 'seedance1pro': [4, 4, 4], 'sora2': [2, 2, 4], 'veo3.1': [3], 'wan2.5': [3, 3, 4], 'kling2.5turbo': [3 , 4, 2], 'ray2': [2, 2, 1]}",230
magnetic damping,Physics,"Electromagnetism, Simple harmonic motion","Tie a neodymium magnet to a string so it can swing freely like a pendulum. Place aluminum plates beneath it, leaving a small gap at the lowest point of the swing. Pull the magnet to about a 45 degree angle, then release it.",https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"The magnet swings toward the aluminum plates but slows down quickly and does not complete as many oscillations as expected, showing significant damping of motion.",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: looks good yujie: 1.Could you specify where the small gap is? ( 2. Would a comparison without the aluminum plates be informative?,"{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 4, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [4, 4, 4], ‘kling2.5turbo’: [4, 4, 3], ‘ray2’: [4, 3, 3]}","{’hailuo2.3’: [4, 3, 4], ‘seedance1pro’: [4, 4, 3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [3, 3, 3], ‘kling2.5turbo’: [4, 3,3], ‘ray2’: [ 2,4, 3]}","{'hailuo2.3': [4, 3, 4], 'seedance1pro': [4, 4, 3], 'sora2': [4, 4, 4], 'veo3.1': [3], 'wan2.5': [3, 3, 3], 'kling2.5turbo': [4, 3, 2], 'ray2': [2, 3, 2]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [4, 4, 2], 'sora2': [3, 4, 4], 'veo3.1': [2], 'wan2.5': [2, 3, 2], 'kling2.5turbo': [2, 2, 2], 'ray2': [1, 1, 1]}","{'hailuo2.3': [2, 2, 2], 'seedance1pro': [4, 4, 2], 'sora2': [3, 4, 4], 'veo3.1': [2], 'wan2.5': [2, 3, 3], 'kling2.5turbo': [2, 2, 2], 'ray2': [1, 1, 1]}",229
magnetic field visualization,Physics,"Fluid Flow, Magnetics",Prepare a bottle filled with water containing suspended iron filings. Bring two magnets close to opposite sides of the bottle.,https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"The iron filings move and align along invisible lines between the two magnets, forming clear patterns that connect the magnetic poles.",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: missing a keyword yujie: LGTM,"{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 4, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [4, 4, 3], ‘kling2.5turbo’: [4, 2, 4], ‘ray2’: [4, 3, 2]}","{’hailuo2.3’: [3, 3, 3], ‘seedance1pro’: [4, 3, 4], ‘sora2’: [4, 3, 4], ‘veo3.1’: [4], ‘wan2.5’: [4, 3, 4], ‘kling2.5turbo’: [3, 2, 3], ‘ray2’: [4, 3, 2]}","{’hailuo2.3’: [3, 3, 2], ‘seedance1pro’: [4, 3, 3], ‘sora2’: [4, 3, 4], ‘veo3.1’: [4], ‘wan2.5’: [4,3, 3], ‘kling2.5turbo’: [3, 3, 3], ‘ray2’: [2, 2, 2]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [4, 3, 3], 'sora2': [3, 2, 3], 'veo3.1': [4], 'wan2.5': [4, 2, 3], 'kling2.5turbo': [2, 2, 2], 'ray2': [1, 2, 1]}","{'hailuo2.3': [2, 2, 2], 'seedance1pro': [4, 3, 3], 'sora2': [3, 2, 4], 'veo3.1': [4], 'wan2.5': [4, 3, 3], 'kling2.5turbo': [2, 3, 2], 'ray2': [1, 2, 2]}",228
water seperation,Physics,"Density and Buoyancy, Statistical equilibrium, Thermal convection","Add red food coloring to a glass of hot water and blue food coloring to a glass of cold water. Cover the hot water glass with a thin plastic sheet. Carefully invert the glass of hot water, gently position it mouth-to-mouth on top of the glass of cold water and slowly remove the plastic sheet.",https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"The red (hot) water remains above the blue (cold) water with minimal mixing, forming a stable boundary between the two layers.",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: looks good yujie: LGTM,"{’hailuo2.3’: [4, 2, 3], ‘seedance1pro’: [3, 3, 3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [3, 4, 2], ‘kling2.5turbo’: [4, 4, 4], ‘ray2’: [4, 3, 3]}","{’hailuo2.3’: [3, 2, 2], ‘seedance1pro’: [2, 3, 3], ‘sora2’: [4, 3, 4], ‘veo3.1’: [3], ‘wan2.5’: [2, 3, 2], ‘kling2.5turbo’: [4, 4, 2], ‘ray2’: [2, 2, 2]}","{’hailuo2.3’: [2, 2, 2], ‘seedance1pro’: [1, 3, 3], ‘sora2’: [4,3, 4], ‘veo3.1’: [3], ‘wan2.5’: [2, 3, 2], ‘kling2.5turbo’: [2, 2, 2], ‘ray2’: [2, 2, 2]},","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 2, 2], 'sora2': [1, 2, 3], 'veo3.1': [2], 'wan2.5': [1, 2, 1], 'kling2.5turbo': [4,2, 1], 'ray2': [1, 2, 1]}","{'hailuo2.3': [1, 2, 1], 'seedance1pro': [1, 3, 2], 'sora2': [3, 3, 3], 'veo3.1': [3], 'wan2.5': [2, 2, 1], 'kling2.5turbo': [4, 2, 1], 'ray2': [1, 2, 2]}",227
homopolar motor,Physics,"Electromagnetism, Kinematics",Position a battery vertically on top of the three neodymium magnets so that the magnets contact the battery’s negative terminal. Place a heart-shaped copper wire so that it can touch both the top of the battery (positive terminal) and the sides of the magnets simultaneously.,https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"When the copper wire touches both ends of the circuit, it begins to spin or move continuously, creating a small, self-turning “heart motor.”",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: missing a keyword yujie: LGTM,"{’hailuo2.3’: [4, 4, 2], ‘seedance1pro’: [4, 4, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [4,3, 4], ‘kling2.5turbo’: [4, 4, 3], ‘ray2’: [4, 4, 4]}","{’hailuo2.3’: [4, 4, 2], ‘seedance1pro’: [4, 3,  4], ‘sora2’: [2, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [3,3, 4], ‘kling2.5turbo’: [4, 4, 3], ‘ray2’: [4, 3, 2]}","{’hailuo2.3’: [4, 4, 2], ‘seedance1pro’: [4, 3, 4], ‘sora2’: [2, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [3, 3, 4], ‘kling2.5turbo’: [4, 4, 2], ‘ray2’: [4, 4, 1]}","{'hailuo2.3': [3, 1, 1], 'seedance1pro': [2, 2, 2], 'sora2': [2, 4, 4], 'veo3.1': [2], 'wan2.5': [2, 2, 2], 'kling2.5turbo': [1, 1, 2], 'ray2': [1,1, 1]}","{'hailuo2.3': [4, 3, 2], 'seedance1pro': [2, 2, 2], 'sora2': [2, 4, 4], 'veo3.1': [2], 'wan2.5': [1, 2, 2], 'kling2.5turbo': [1, 2, 2], 'ray2': [1,2, 1]}",226
Polarized Plastic Fringes,Physics,"Interference, Polarization","A clear plastic ruler is placed between two crossed polarizing filters and illuminated by a bright white light.
",https://www.youtube.com/watch?v=28F6d_5ix1I,"The stressed plastic causes rotation of the light’s polarization plane in a wavelength-dependent way. Between the crossed polarizers, this yields colored interference fringes that change as the plastic is twisted or bent.
",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [1, 4, 1], seedance1: [4, 2, 4], sora2: [3, 4, 3], veo3: [3, 4, 2], wan2.5: [1, 3, 3]}","{hailuo2.3: [2, 2, 2], kling2.5: [4, 4, 4], luma2: [1, 2, 1], seedance1: [1, 1, 4], sora2: [4, 4, 3], veo3: [4, 4, 2], wan2.5: [1, 1, 4]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [1, 4, 1], seedance1: [2, 2, 4], sora2: [3, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 2]}","{hailuo2.3: [1, 1, 1], kling2.5: [1, 1, 1], luma2: [1, 1, 1], seedance1: [1, 1, 1], sora2: [3, 3, 3], veo3: [3, 3, 2], wan2.5: [1, 1, 1]}","{hailuo2.3: [1, 1, 1], kling2.5: [1, 1, 1], luma2: [1, 1, 1], seedance1: [1, 1, 1], sora2: [2, 2, 2], veo3: [2, 2, 1], wan2.5: [1, 1, 1]}",177
Laser Diffraction Rings,Physics,"Diffraction, Interference","A laser pointer shines through a circular pinhole cut in aluminum foil and projects a pattern onto a distant white wall.
",https://www.youtube.com/watch?v=71Rp-jG6Eek,"The pinhole causes the coherent laser beam to diffract and the overlapping wavefronts interfere to form concentric ring patterns (Airy-disk style) whose spacing depends on wavelength and aperture size.
",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{hailuo2.3: [1, 4, 1], kling2.5: [4, 4, 2], luma2: [1, 2, 2], seedance1: [1, 1, 1], sora2: [4, 4, 2], veo3: [4, 4, 1], wan2.5: [4, 4, 2]}","{hailuo2.3: [1, 2, 1], kling2.5: [1, 1, 2], luma2: [1, 1, 1], seedance1: [1, 1, 1], sora2: [3, 3, 4], veo3: [1, 2, 1], wan2.5: [1, 1, 2]}","{hailuo2.3: [1, 4, 1], kling2.5: [4, 4, 3], luma2: [1, 4, 4], seedance1: [1, 1, 4], sora2: [4, 3, 3], veo3: [4, 4, 4], wan2.5: [2, 4, 4]}","{hailuo2.3: [1, 1, 1], kling2.5: [1, 3, 4], luma2: [1, 1, 1], seedance1: [1, 1, 1], sora2: [3, 3, 3], veo3: [2, 2, 2], wan2.5: [1, 1, 1]}","{hailuo2.3: [1, 2, 1], kling2.5: [1, 2, 3], luma2: [1, 1, 1], seedance1: [1, 1, 1], sora2: [3, 3, 4], veo3: [1, 1, 1], wan2.5: [2, 4, 1]}",178
"A thin soap film is formed across a circular wire loop and illuminated by white light while a camera films the film as it thins.
",Physics,"Dispersion, Interference","A thin soap film is formed across a circular wire loop and illuminated by white light while a camera films the film as it thins.
",https://www.youtube.com/watch?v=WTxDyYHaYAI,"Light reflected from the front and back surfaces of the soap film interfere; as the film thickness changes, different wavelengths (colors) undergo constructive vs. destructive interference, producing shifting iridescent bands.
",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{hailuo2.3: [1, 1, 1], kling2.5: [4, 4, 4], luma2: [1, 1, 1], seedance1: [4, 3, 3], sora2: [4, 4, 3], veo3: [2, 2, 2], wan2.5: [4, 4, 4]}","{hailuo2.3: [1, 1, 1], kling2.5: [2, 2, 2], luma2: [1, 1, 1], seedance1: [2, 1, 1], sora2: [4, 2, 1], veo3: [1, 1, 1], wan2.5: [1, 3, 4]}","{hailuo2.3: [1, 3, 3], kling2.5: [4, 4, 4], luma2: [4, 4, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [1, 1, 1], kling2.5: [3, 3, 3], luma2: [1, 1, 1], seedance1: [2, 1, 1], sora2: [3, 3, 2], veo3: [1, 1, 2], wan2.5: [3, 3, 3]}","{hailuo2.3: [1, 1, 1], kling2.5: [3, 3, 3], luma2: [1, 1, 1], seedance1: [3, 1, 1], sora2: [2, 2, 2], veo3: [2, 2, 2], wan2.5: [3, 3, 3]}",179
Arago Spot Surprise,Physics,"Diffraction, Interference",A green laser pointer shines on a small circular disk suspended in mid-air.,https://www.youtube.com/watch?v=y9c8oZ49pFc&t=293s,"Although geometrical optics predicts darkness in the disk’s shadow, wave diffraction around the disk’s edge causes secondary wavelets that interfere constructively at the center, producing a bright “Arago spot”. ",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: I think the projection screen behind shows a bright dot inside the disk’s shadow should be phenonmenon.,"{hailuo2.3: [3, 4, 2], kling2.5: [4, 4, 4], luma2: [4, 3, 1], seedance1: [4, 4, 3], sora2: [4, 4, 4], veo3: [4, 4, 2], wan2.5: [4, 4, 4]}","{hailuo2.3: [1, 1, 1], kling2.5: [3, 3, 2], luma2: [1, 3, 1], seedance1: [1, 1, 2], sora2: [2, 4, 2], veo3: [1, 3, 1], wan2.5: [2, 2, 2]}","{hailuo2.3: [4, 4, 3], kling2.5: [4, 4, 4], luma2: [1, 4, 4], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 3, 4]}","{hailuo2.3: [1, 1, 1], kling2.5: [2, 2, 1], luma2: [2, 1, 1], seedance1: [2, 4, 1], sora2: [2, 2, 1], veo3: [2, 1, 2], wan2.5: [2, 2, 2]}","{hailuo2.3: [2, 2, 1], kling2.5: [3, 3, 3], luma2: [2, 1, 1], seedance1: [2, 3, 2], sora2: [3, 3, 3], veo3: [2, 1, 2], wan2.5: [1, 3, 3]}",180
Laser Speckle Pattern,Physics,"Diffraction, Interference"," A green laser pointer is shone onto a rough-metal surface and the scattered light is filmed on a nearby wall.",https://www.youtube.com/watch?v=5FsQOblLVyY,"The coherent laser light scatters from microscopic irregularities on the surface, and the many secondary wavefronts interfere with each other to form a random granular speckle pattern.",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [2, 4, 4], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [4, 4, 4], kling2.5: [2, 2, 4], luma2: [3, 2, 2], seedance1: [4, 2, 4], sora2: [2, 3, 4], veo3: [2, 3, 1], wan2.5: [3, 4, 4]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 3], luma2: [4, 4, 2], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [2, 2, 2], kling2.5: [2, 2, 4], luma2: [3, 2, 2], seedance1: [3, 2, 3], sora2: [3, 3, 3], veo3: [2, 2, 2], wan2.5: [2, 2, 3]}","{hailuo2.3: [2, 2, 2], kling2.5: [2, 2, 4], luma2: [2, 1, 1], seedance1: [2, 2, 2], sora2: [2, 3, 3], veo3: [2, 2, 2], wan2.5: [2, 4, 2]}",181
Negative Refraction Metamaterial,Physics,"Dispersion, Refraction","A sample of artificial metamaterial (a negative-refractive-index medium) is used, and a laser beam passes through the transparent slab of this metamaterial.",https://www.youtube.com/watch?v=fxVuytEq6W8,"In the metamaterial slab the refractive index is engineered to be negative; incoming light is bent opposite the usual direction, and different wavelengths refract differently, producing a reversed-spectrum spread on the screen.",Yixin Huang,Wan2.5,Makeup,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{hailuo2.3: [4, 1, 4], kling2.5: [4, 3, 1], luma2: [4, 1, 4], seedance1: [4, 1, 4], sora2: [4, 3, 4], veo3: [4, 4, 1], wan2.5: [4, 2, 4]}","{hailuo2.3: [1, 1, 1], kling2.5: [2, 1, 1], luma2: [2, 1, 1], seedance1: [2, 1, 1], sora2: [3, 2, 4], veo3: [4, 1, 1], wan2.5: [2, 1, 1]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 4, 4], seedance1: [4, 4, 4], sora2: [3, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [1, 1, 1], kling2.5: [1, 1, 1], luma2: [2, 1, 1], seedance1: [2, 1, 1], sora2: [3, 4, 4], veo3: [4, 4, 1], wan2.5: [1, 1, 1]}","{hailuo2.3: [1, 1, 1], kling2.5: [3, 1, 2], luma2: [1, 1, 3], seedance1: [2, 1, 2], sora2: [4, 4, 4], veo3: [4, 4, 3], wan2.5: [4, 1, 3]}",182
Lloyd’s Mirror Interference,Physics,"Interference, Reflection",Several flat mirrors are arranged in an indoor studio with a fixed laser source，and a small amount of smoke or mist is used.,https://www.youtube.com/shorts/iUu16y45V3Y,The direct beam and the beam reflected from the mirror act like two coherent sources; their path difference creates interference fringes. Adjusting the mirror changes fringe spacing and pattern because of both reflection and interference.,Yixin Huang,Wan2.5,Makeup,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{hailuo2.3: [4, 2, 4], kling2.5: [4, 4, 4], luma2: [3, 4, 4], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [4, 1, 4], kling2.5: [3, 1, 1], luma2: [1, 1, 1], seedance1: [4, 4, 1], sora2: [2, 1, 4], veo3: [3, 1, 1], wan2.5: [3, 3, 2]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 4, 4], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [2, 1, 1], kling2.5: [3, 2, 1], luma2: [1, 1, 1], seedance1: [3, 1, 1], sora2: [2, 2, 3], veo3: [2, 2, 2], wan2.5: [2, 2, 3]}","{hailuo2.3: [3, 1, 3], kling2.5: [4, 3, 3], luma2: [1, 1, 1], seedance1: [4, 1, 2], sora2: [2, 4, 3], veo3: [2, 4, 4], wan2.5: [4, 4, 3]}",183
Halo-Water Glass,Physics,"Dispersion, Refraction","A cylindrical glass nearly filled with water is placed at the edge of a table under diffuse sunlight. 
",https://www.youtube.com/watch?v=kbXoEKPYees,"The cylindrical water volume acts like a horizontal prism: sunlight entering and exiting the glass–water–air boundaries is refracted and different wavelengths spread, forming a visible arc (artificial circumzenithal halo).",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: projecting a colored arc on the floor. should be phenonmenon?,"{hailuo2.3: [4, 2, 4], kling2.5: [4, 2, 2], luma2: [4, 2, 2], seedance1: [2, 4, 2], sora2: [4, 4, 4], veo3: [4, 2, 4], wan2.5: [2, 2, 2]}","{hailuo2.3: [4, 1, 4], kling2.5: [2, 2, 3], luma2: [1, 2, 2], seedance1: [2, 4, 2], sora2: [4, 4, 4], veo3: [4, 2, 3], wan2.5: [2, 3, 2]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 4, 4], seedance1: [4, 4, 4], sora2: [4, 4, 3], veo3: [4, 4, 4], wan2.5: [4, 2, 4]}","{hailuo2.3: [2, 1, 2], kling2.5: [3, 3, 2], luma2: [1, 1, 2], seedance1: [3, 4, 3], sora2: [3, 2, 2], veo3: [2, 2, 2], wan2.5: [3, 3, 2]}","{hailuo2.3: [2, 1, 2], kling2.5: [4, 4, 4], luma2: [1, 1, 3], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 3, 3], wan2.5: [4, 4, 4]}",184
Quetelet Dust Rings,Physics,"Diffraction, Interference","A bright point-light source illuminates a mirror covered with fine dust particles.
",https://www.youtube.com/watch?v=YwLpATdI1-g,"Light scattered by dust particles and then reflected from the mirror interferes with directly reflected light; the overlapping wavefronts cause colored concentric rings (Quetelet rings) visible around the source image.
",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{hailuo2.3: [4, 2, 4], kling2.5: [4, 4, 4], luma2: [2, 4, 2], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [2, 1, 1], kling2.5: [2, 2, 1], luma2: [1, 1, 1], seedance1: [4, 1, 1], sora2: [4, 4, 4], veo3: [2, 1, 1], wan2.5: [2, 4, 1]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 4, 4], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [1, 1, 1], kling2.5: [1, 2, 1], luma2: [1, 1, 1], seedance1: [1, 1, 1], sora2: [3, 2, 2], veo3: [3, 3, 1], wan2.5: [3, 1, 1]}","{hailuo2.3: [3, 1, 1], kling2.5: [2, 4, 3], luma2: [1, 1, 2], seedance1: [1, 2, 3], sora2: [4, 4, 3], veo3: [4, 4, 2], wan2.5: [3, 4, 3]}",185
Snell’s Window Underwater,Physics,"Buoyancy, Refraction","A diver looks upwards from beneath the water’s surface and films the circular “window” of light above.
",https://www.youtube.com/watch?v=yceZdR9c1no,"Light entering water from above is refracted according to Snell’s law; from below the surface you see a compressed 180° hemisphere of above‑water view (≈ 97° cone) known as Snell’s window.
",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 3], luma2: [1, 3, 4], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 2], luma2: [2, 4, 1], seedance1: [4, 4, 3], sora2: [4, 4, 2], veo3: [4, 2, 2], wan2.5: [2, 4, 2]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 3], luma2: [3, 4, 4], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 2]}","{hailuo2.3: [2, 2, 3], kling2.5: [2, 3, 1], luma2: [1, 3, 2], seedance1: [3, 4, 4], sora2: [3, 4, 2], veo3: [1, 4, 2], wan2.5: [1, 2, 2]}","{hailuo2.3: [1, 2, 4], kling2.5: [4, 3, 4], luma2: [1, 3, 3], seedance1: [4, 4, 3], sora2: [2, 3, 3], veo3: [2, 3, 3], wan2.5: [1, 2, 2]}",186
A car windshield under midday sunlight is filmed through a rotating polarizing filter held in front of the camera.,Physics,"Polarization, Refraction",A car windshield under midday sunlight is filmed through a rotating polarizing filter held in front of the camera.,https://www.youtube.com/watch?v=qr0USkfbUoo,"At the angle known as Brewster’s angle, reflected light from the glass becomes highly polarized. Rotating the analyzer reduces glare significantly when its axis aligns perpendicular to the reflected polarization component.",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{hailuo2.3: [4, 4, 4], kling2.5: [2, 4, 4], luma2: [1, 4, 4], seedance1: [2, 4, 3], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [4, 4, 4], kling2.5: [3, 4, 2], luma2: [1, 3, 4], seedance1: [3, 4, 4], sora2: [4, 4, 4], veo3: [4, 1, 1], wan2.5: [4, 3, 2]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 4, 4], seedance1: [4, 4, 3], sora2: [4, 3, 3], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [2, 2, 2], kling2.5: [2, 2, 2], luma2: [1, 2, 1], seedance1: [3, 2, 2], sora2: [2, 3, 3], veo3: [2, 2, 1], wan2.5: [2, 3, 2]}","{hailuo2.3: [2, 2, 2], kling2.5: [1, 1, 2], luma2: [1, 2, 1], seedance1: [3, 3, 2], sora2: [3, 4, 4], veo3: [3, 4, 4], wan2.5: [3, 3, 4]}",187
A glass aquarium filled with water has a laser beam entering from the side; film as the beam angle increases and the internal glow at the boundary suddenly lights up.,Physics,"Reflection, Refraction",A glass aquarium filled with water has a laser beam entering from the side film as the beam angle increases,https://www.youtube.com/watch?v=NAaHPRsveJk,"As the laser beam’s incident angle at the water–air interface increases past the critical angle, the beam no longer leaves the water and instead is completely reflected internally, producing a bright internal glow along the interface.",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie:  I think the internal glow at the boundary suddenly lights up should be phenonmenon,"{hailuo2.3: [4, 4, 4], kling2.5: [4, 3, 4], luma2: [4, 4, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [2, 4, 4], kling2.5: [3, 2, 3], luma2: [2, 1, 1], seedance1: [1, 1, 1], sora2: [4, 4, 4], veo3: [4, 1, 4], wan2.5: [4, 2, 4]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 4, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [2, 1, 1], kling2.5: [1, 1, 2], luma2: [1, 1, 1], seedance1: [1, 1, 1], sora2: [3, 2, 2], veo3: [2, 1, 2], wan2.5: [2, 3, 4]}","{hailuo2.3: [2, 1, 1], kling2.5: [4, 4, 2], luma2: [1, 2, 2], seedance1: [2, 2, 2], sora2: [3, 2, 2], veo3: [2, 2, 2], wan2.5: [2, 4, 3]}",188
Floating Bubble Caustics,Physics,"Dispersion, Refraction","A soap bubble hovers in the sun near a window, and the camera films the light patterns onto a nearby wall.",https://www.youtube.com/watch?v=eGJvcBFkHzg,"Light enters the thin soap bubble, refracts through the curved film, reflects internally, then exits; because the film thickness varies and refractive index differs for each wavelength, the light is bent and separated into colours. The result is shimmering caustic light patterns with subtle rainbow fringes on the wall as the bubble moves.",Yixin Huang,Wan2.5,Makeup,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{hailuo2.3: [4, 4, 4], kling2.5: [4, 3, 4], luma2: [4, 4, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [2, 4, 4], kling2.5: [3, 2, 3], luma2: [2, 1, 1], seedance1: [1, 1, 1], sora2: [4, 4, 4], veo3: [4, 1, 4], wan2.5: [4, 2, 4]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 4, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [2, 1, 1], kling2.5: [1, 1, 2], luma2: [1, 1, 1], seedance1: [1, 1, 1], sora2: [3, 2, 2], veo3: [2, 1, 2], wan2.5: [2, 3, 4]}","{hailuo2.3: [2, 1, 1], kling2.5: [4, 4, 2], luma2: [1, 2, 2], seedance1: [2, 2, 2], sora2: [3, 2, 2], veo3: [2, 2, 2], wan2.5: [2, 4, 3]}",189
Talbot Self‑Image Carpet,Physics,"Diffraction, Interference",A beam of white light shines through a transparent periodic grid (such as a fine mesh or diffraction grating) and the camera films successive self‑images of the grid projected onto a screen as distance changes.,https://www.youtube.com/watch?v=DjiiL0-VANE,"When coherent light passes through a periodic grating, at certain distances the pattern of the grating is reproduced (“self‑images”) due to near‑field diffraction and interference (the Talbot effect). The projected grid appears, then disappears, then re‑appears at integer fractions of the Talbot length. ",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{hailuo2.3: [2, 2, 2], kling2.5: [2, 2, 1], luma2: [1, 2, 1], seedance1: [2, 4, 1], sora2: [4, 4, 3], veo3: [4, 4, 2], wan2.5: [4, 4, 4]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 4, 3], seedance1: [4, 4, 3], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [1, 1, 1], kling2.5: [1, 1, 1], luma2: [1, 1, 1], seedance1: [1, 1, 1], sora2: [3, 3, 2], veo3: [1, 1, 1], wan2.5: [2, 2, 2]}","{hailuo2.3: [1, 1, 1], kling2.5: [1, 1, 1], luma2: [1, 2, 1], seedance1: [2, 1, 1], sora2: [4, 3, 2], veo3: [3, 4, 3], wan2.5: [3, 3, 2]}","{hailuo2.3: [1, 1, 1], kling2.5: [1, 1, 1], luma2: [1, 2, 1], seedance1: [2, 1, 1], sora2: [4, 3, 2], veo3: [3, 4, 3], wan2.5: [3, 3, 2]}",190
Lead ball drop,Physics,"Deformation, Inelastic Collision",A solid spherical lead musket ball approximately 3 cm in diameter is held steady in a person's hand at a height of 15m directly above a thick concrete floor. The ball is released from rest.,https://www.youtube.com/watch?v=CG3sl0CDeEY,"Upon impact, permanently deform/flatten (plastic deformation) due to lead's softness. Balls don't bounce significantly",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang",mk: maybe change this one since the GT video is not real-world video. dz: make the prompt more descriptive if not changed (fixed),,,,,,89
Chromatic Aberration,Physics,"Chromatic Aberration, Dispersion, Refraction",A bright light box illuminates a transparency sheet with a high-contrast black-and-white geometric pattern of squares. A single simple convex lens is held in front of the light to project the image onto a white screen or wall 1-2 meters away. The lens is positioned to create a slightly out-of-focus but visible projection.,https://www.youtube.com/watch?v=MMp87Iw-WoI&t=85s,The projected image on the screen shows the black shapes with vivid color fringing around all edges—blue/violet halos on inner edges and red/orange halos on outer edges. The chromatic aberration is dramatically visible on the projection screen because the uncorrected simple lens cannot focus all wavelengths to the same point on the screen.,Abhilash,Wan2.5,In progress,"Daniel Zhao, Murray Kang","mk: the GT video is more like a lecture and no real experiment dz: i think we can rewrite this too, or the video generated doesnt seem to match prompt maybe because prompt doesnt really have an action
abhi: wrote a new prompt with the same concept",,,,,,88
Mirror Ripple Reflections,Physics,"Interference, Reflection",A shallow metal tray of water sits under a lamp as you gently tap the edge.,https://www.youtube.com/watch?v=DiSJspAVFh0,"Each point on the water acts as a small moving mirror. The ripples create a dynamic interference pattern that distorts and shifts the reflected light. The resulting reflection forms a wavy, shimmering pattern consistent with overlapping surface waves altering the reflection geometry.
",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao","yujie: I think “ripples move across the surface, distorting the reflection of the lamp above.” should be phenonmenon","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 2, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 2, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 5]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 2, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 6]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 2, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 7]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 2, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 8]}",176
Curved Refraction Gradient,Physics,"Density, Refraction",A transparent water tank is filled with sugar water of layered concentrations and placed in a dark room. A laser beam enters from the side.,https://www.youtube.com/watch?v=Ld_lvcZna7s,"The different densities of the two layers create distinct refractive indices. As the beam passes between them, it bends sharply (Snell’s law). Because the boundary is diffuse, the beam curves smoothly through the gradient, illustrating how refractive index changes with density.
",Yixin Huang,Wan2.5,Makeup,"Haoyang Yu, Yujie Zhao",yujie: “the beam bends and curves as it travels through.” should be phenomenon,"{hailuo2.3: [4, 4, 4], kling2.5: [2, 2, 4], luma2: [1, 1, 4], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 2, 4]}","{hailuo2.3: [1, 1, 1], kling2.5: [1, 1, 1], luma2: [1, 1, 1], seedance1: [2, 1, 1], sora2: [4, 2, 3], veo3: [3, 1, 2], wan2.5: [1, 1, 4]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [2, 4, 4], seedance1: [2, 4, 4], sora2: [3, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [1, 1, 1], kling2.5: [1, 1, 1], luma2: [1, 1, 1], seedance1: [1, 1, 1], sora2: [3, 1, 3], veo3: [3, 1, 2], wan2.5: [1, 1, 2]}","{hailuo2.3: [2, 1, 2], kling2.5: [2, 2, 2], luma2: [1, 1, 2], seedance1: [2, 1, 1], sora2: [4, 3, 3], veo3: [3, 3, 3], wan2.5: [3, 3, 2]}",175
Double-Slit Interference,Physics,"Diffraction, Interference","A laser pointer shines through two narrow slits cut in cardboard onto a white screen in a dark room.
",https://www.youtube.com/shorts/mjeA6WrrxHM,"The two slits produce diffracted waves that interfere constructively and destructively, forming a regular interference pattern. Changing slit spacing alters the fringe spacing. 
",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 1, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 4]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 1, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 5]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 1, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 6]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 1, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 7]}","{hailuo2.3: [4, 4, 4], kling2.5: [4, 4, 4], luma2: [4, 1, 1], seedance1: [4, 4, 4], sora2: [4, 4, 4], veo3: [4, 4, 4], wan2.5: [4, 4, 8]}",174
Polarized Film Colors,Physics,"Interference, Polarization",A plastic film is placed between two crossed polarizing filters and illuminated by a white flashlight; the film is slowly twisted while being recorded.,https://www.youtube.com/watch?v=jdmUsUfkrfg,"The film’s birefringence splits light into components that interfere after passing through the analyzer. Rotation changes retardation, producing colored interference fringes dependent on polarization angle.
",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{'hailuo2.3': [4,4,4], 'kling2.5turbo': [4,4,4], 'seedance1pro': [1,4,4], 'sora2': [2,3,2], 'veo3.1': [3,3,3], 'wan2.5': [1,2,3], 'ray2': [3,1,1]}","{'hailuo2.3': [1,4,4], 'kling2.5turbo': [4,4,4]', seedance1pro': [1, 4,4], 'sora2': [2, 2,2], 'veo3.1': [1, 1,4], 'wan2.5': [1,1, 1], 'kling2.5turbo': [4, 3], 'ray2': [3, 2,2]}","{'hailuo2.3': [4,4,4], 'kling2.5turbo': [4,4,4]', seedance1pro': [2,4,4], 'sora2': [2,2,4], 'veo3.1': [1,1,1], 'wan2.5': [2,2,1], , 'ray2': [3,2,3]}","{'hailuo2.3': [1,1,1], 'kling2.5turbo': [1,3,2], 'seedance1pro': [1,1,1], 'sora2': [1,1,1], 'veo3.1': [1,1,1], 'wan2.5': [1,1,1], 'ray2': [1,1,1]}","{'hailuo2.3': [1, 1 ,1], 'kling2.5turbo': [1,4,2],'seedance1pro': [1, 1,1], 'sora2': [1, 1,1], 'veo3.1': [1, 1,1], 'wan2.5': [1, 1,1],  'ray2': [1, 1,1]}",173
CD Rainbow Diffraction,Physics,"Diffraction, Dispersion, Interference",A phone flashlight shines onto a CD lying flat on a table in a dim room as the disc rotates. ,https://www.youtube.com/watch?v=0yNAbHKF8pY,Rainbow-colored bands appear and move as the disc rotates.,Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: I think “as the disc rotates” should also been in prompt?,"{'hailuo2.3': [4,4,4], 'kling2.5turbo': [4,4,4], 'seedance1pro': [4,4,3], 'sora2': [3,3,3], 'veo3.1': [3,3,2], 'wan2.5': [3,3,3], 'ray2': [2,1,2]}","{'hailuo2.3': [4,4, 4], 'kling2.5turbo': [4,4,3]', seedance1pro': [3, 3,2], 'sora2': [4, 4,4], 'veo3.1': [4,3, 2], 'wan2.5': [4, 4,4], 'kling2.5turbo': [4, 3,3], 'ray2': [3, 3,2]}","{'hailuo2.3': [4,4,4], 'kling2.5turbo': [4,4,3]', seedance1pro': [3,3,2], 'sora2': [4,4,4], 'veo3.1': [4,3,4], 'wan2.5': [4,4,4], , 'ray2': [2,3,2]}","{'hailuo2.3': [1,1,1], 'kling2.5turbo': [2,2,2], 'seedance1pro': [2,2,2], 'sora2': [2,2,2], 'veo3.1': [2,2,2], 'wan2.5': [2,2,2], 'ray2': [2,2,2]}","{'hailuo2.3': [2, 1, 2], 'kling2.5turbo': [4,3,3],'seedance1pro': [3, 3,3], 'sora2': [3, 3,3], 'veo3.1': [3, 3,3], 'wan2.5': [4, 3,4],  'ray2': [2, 1,2]}",172
Rotating Prism Spectrum,Physics,"Dispersion, Refraction",A prism is placed under a white LED on a rotating platform; the outgoing beam falls onto white paper as the prism is slowly rotated.,https://www.youtube.com/watch?v=uucYGK_Ymp0,"The prism refracts and disperses white light: each wavelength exits at a different angle, forming a spectrum. Rotation changes the geometry, altering the spread and orientation of the colored band.",Yixin Huang,Wan2.5,Done,"Haoyang Yu, Yujie Zhao",yujie: LGTM,"{'hailuo2.3': [4,4,4], 'kling2.5turbo': [4,4,4], 'seedance1pro': [4,1,3], 'sora2': [4,4,4], 'veo3.1': [3,4,4], 'wan2.5': [4,4,4], 'ray2': [4,2,1]}","{'hailuo2.3': [4,4, 3], 'kling2.5turbo': [4,4,4]', seedance1pro': [4, 4,4], 'sora2': [4,4,4], 'veo3.1': [4, 4,4], 'wan2.5': [4, 2,2], 'kling2.5turbo': [4, 2], 'ray2': [4, 2,2]}","{'hailuo2.3': [4,4,4], 'kling2.5turbo': [4,4,4]', seedance1pro': [4,4,4], 'sora2': [4,4,4], 'veo3.1': [4,4,4], 'wan2.5': [4,2,4], , 'ray2': [2,3,4]}","{'hailuo2.3': [1,2,1], 'kling2.5turbo': [4,4,3], 'seedance1pro': [4,3,3], 'sora2': [4,4,3], 'veo3.1': [1,1,1], 'wan2.5': [4,2,4], 'ray2': [3,1,1]}","{'hailuo2.3': [2, 4, 2], 'kling2.5turbo': [4,4,4],'seedance1pro': [4,4, 4], 'sora2': [2, 2, 2], 'veo3.1': [3, 3,3], 'wan2.5': [4,2, 3],  'ray2': [3, 2,1]}",171
,,,,,,Murray,,Not started,,,,,,,,66
Carbon Sugar Snake Experiment,Chemistry,"Dehydration, carbonisation, thermochemistry",A shallow metal baking tray is filled with dry sand. A small mound of the sand is made in the centre and soaked with lighter fluid. A mixture of powdered sugar and baking soda is then poured into the top of the mound. A flame is held to the base of the mound to ignite the mixture.,https://youtu.be/pVDqiYIxvdA?si=6HXqf20kWFF4i8Y5&t=585,A black ‘snake’ of carbon grows out of sugar-acid or sugar-flame reaction.,Murray,Wan2.5,Not started,"Daniel Zhao, Lanxiang Hu",dz: duplicate,,,,,,65
,Physics,"Gas Ionization, Plasma Physics, Simple circuit",A simple circuit is connected to a high-voltage transformer and two electrodes sealed inside a tube containing low-pressure Neon gas. The voltage is slowly increased to the gas's breakdown potential.,https://www.youtube.com/watch?v=VD-6DKsicMQ,"The voltage from the simple circuit will ionize the low-pressure gas, causing electrons to jump and emit photons, transitioning the gas into a fourth state of matter (Plasma Physics) that glows through Gas Ionization.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu",lx: lgtm dz: good,"{hailuo2.3: [1, 2, 1], klingv2.5: [4, 4, 4], ray-2: [3, 3, 1], seed-dance: [2, 3, 3], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 3]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [4, 2, 2], ray-2: [3, 1, 1], seed-dance: [2, 1, 1], sora-2: [4, 4, 4], veo3: [3], wan2.5: [4, 1, 2]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 4, 1], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [1, 2, 3], ray-2: [1, 1, 1], seed-dance: [1, 3, 2], sora-2: [3, 3, 3], veo3: [4], wan2.5: [2, 2, 2]}
","{hailuo2.3: [1, 2, 1], klingv2.5: [3, 3, 4], ray-2: [2, 1, 1], seed-dance: [1, 4, 3], sora-2: [4, 4, 4], veo3: [4], wan2.5: [3, 2, 3]}",64
,Physics,"Fluid Dynamics, Standing waves","Water droplets are set to fall from a nozzle at 60.0 Hz. A strobe light is flashed at 60.1 Hz, and a speaker vibrates the water surface.",https://www.youtube.com/watch?v=uENITui5_jU,"When the light frequency is slightly mis-tuned, the water drops appear to move in slow motion, and the acoustic vibration reveals a visible standing wave pattern on the surface of the Fluid Dynamics current.",Murray,Wan2.5,Not started,"Daniel Zhao, Lanxiang Hu",dz: duplicate,,,,,,63
,Physics,"Electromagnetism, Friction","In slow motion, a shiny, cylindrical neodymium magnet is released to fall into a thick, vertically mounted polished copper pipe. Use a close-up shot against a dark background to highlight the motion.",https://www.youtube.com/watch?v=2j-K2P5mSPA,"The expected phenomenon is Eddy Current Braking (also known as Magnetic Damping or Lenz's Law). When a strong magnet moves relative to a non-ferromagnetic conductive material (like copper or aluminum), the moving magnetic field induces circulating electric currents (eddy currents) within the conductor. According to Lenz's Law, these induced currents create their own magnetic field that opposes the motion of the original magnet, resulting in a powerful and visibly smooth braking effect.",Murray,Wan2.5,Not started,"Daniel Zhao, Lanxiang Hu",dz: i just dont think this is a good prompt / phenomenon to do. it’s hard to portray and i think it looks a bit “obvious” even though it is not,,,,,,62
,Chemistry,"Catalysis, Exothermic Reaction",A potassium iodide is added to a large volume of concentrated hydrogen peroxide and soap.,https://www.youtube.com/watch?v=V3kOCT6L_ho,"When the potassium iodide is added, the reaction begins almost instantly — producing a towering column of hot, expanding foam that shoots upward and spills over the container. The rapid decomposition of hydrogen peroxide releases oxygen gas and heat, vividly demonstrating an exothermic catalytic reaction known as the “elephant’s toothpaste” effect.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu","dz: maybe we should not mention that it is a catalyst in the prompt?
mk: deleted it","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 2, 4], seed-dance: [4, 1, 3], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 3, 2], seed-dance: [3, 1, 2], sora-2: [4, 2, 3], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 4, 4], seed-dance: [2, 4, 4], sora-2: [4, 1, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [3, 3, 3], ray-2: [1, 1, 1], seed-dance: [1, 1, 1], sora-2: [4, 3, 3], veo3: [4], wan2.5: [1, 1, 1]}
","{hailuo2.3: [4, 1, 1], klingv2.5: [4, 4, 4], ray-2: [2, 2, 4], seed-dance: [2, 2, 3], sora-2: [4, 4, 3], veo3: [4], wan2.5: [4, 3, 3]}
",61
,Physics,"Light, Refraction, Total Internal Reflection","In a dark room, a red laser beam is aimed through the side of a clear water bottle. A stream of water is poured from a hole on the opposite side such that the laser beam enters the water stream.",https://www.youtube.com/watch?v=XrWB0KLXpn8,"When the laser passes through the hole and into the flowing water, the beam bends and follows the curve of the stream instead of traveling straight — appearing as if the light is “flowing” with the water. This striking effect occurs due to total internal reflection, where the light continually reflects within the water–air boundary.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu",lx: simplified dz: good,"{hailuo2.3: [3, 4, 3], klingv2.5: [4, 3, 3], ray-2: [1, 1, 1], seed-dance: [1, 3, 3], sora-2: [4, 4, 4], veo3: [4], wan2.5: [3, 4, 3]}
","{hailuo2.3: [3, 4, 2], klingv2.5: [1, 1, 1], ray-2: [1, 1, 3], seed-dance: [1, 2, 1], sora-2: [4, 4, 2], veo3: [4], wan2.5: [3, 1, 1]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 1, 4], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [1, 1, 2], klingv2.5: [1, 1, 1], ray-2: [1, 1, 1], seed-dance: [1, 1, 1], sora-2: [1, 4, 2], veo3: [4], wan2.5: [2, 1, 1]}
","{hailuo2.3: [1, 2, 2], klingv2.5: [2, 1, 3], ray-2: [1, 1, 1], seed-dance: [1, 2, 1], sora-2: [3, 4, 3], veo3: [3], wan2.5: [2, 2, 2}
",60
,Physics,"Density and Buoyancy, Thermodynamics","Inside a glass lamp, a light bulb continuously heats a colorful blob of wax at the bottom",https://www.youtube.com/watch?v=U1B7erHd6Ko,"As the lamp warms, the wax at the bottom melts and expands, rising upward in smooth, glowing blobs. When the wax reaches the cooler top, it contracts and sinks back down, repeating the process — a mesmerizing demonstration of heat transfer, density change, and convection currents in action.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu",lx: simplified to clean up phenonmenon dz: good,"{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [3, 1, 1], seed-dance: [4, 4, 3], sora-2: [4, 4, 4], veo3: [2], wan2.5: [4, 4, 4]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [3, 3, 3], ray-2: [2, 1, 1], seed-dance: [4, 2, 1], sora-2: [3, 3, 4], veo3: [1], wan2.5: [2, 4, 4]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [1, 3, 4], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [2, 2, 2], ray-2: [1, 1, 1], seed-dance: [1, 2, 1], sora-2: [3, 1, 3], veo3: [1], wan2.5: [1, 1, 1]}
","{hailuo2.3: [3, 2, 3], klingv2.5: [3, 3, 3], ray-2: [1, 1, 1], seed-dance: [3, 2, 2], sora-2: [4, 4 ,4], veo3: [2], wan2.5: [4, 3, 3]}
",59
,Physics,"Surface Tension, Surfactants",A shallow dish of water has pepper flakes floating evenly across its surface. A finger with a single drop of soap touches the center.,https://www.youtube.com/watch?v=ho0o7H6dXSU,"When the soapy finger touches the water’s surface, the soap molecules quickly reduce surface tension at the contact point. The surrounding higher-tension water pulls outward, causing the pepper flakes to dart away from the center and collect at the edges — clearly visualizing how surfactants disrupt surface tension.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu","lx: a common rule of thumb: we don’t want to mention physical/scientific concepts in the prompt. i just cleaned them up
mk: you are my hero. dz: good","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 4, 3], seed-dance: [4, 4, 2], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [4, 3, 3], klingv2.5: [2, 4, 4], ray-2: [2, 2, 3], seed-dance: [4, 3, 2], sora-2: [4, 3, 4], veo3: [2], wan2.5: [4, 4, 4]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 1, 4], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [1, 1, 1], ray-2: [1, 1, 1], seed-dance: [1, 1, 1], sora-2: [1, 2, 3], veo3: [3], wan2.5: [1, 1, 1]}
","{hailuo2.3: [3, 3, 2], klingv2.5: [2, 2, 2], ray-2: [2, 2, 1], seed-dance: [3, 2, 2], sora-2: [3, 3, 3], veo3: [4], wan2.5: [3, 3, 2]}",58
,Physics,"Non-Newtonian Fluid, Sound Waves, Viscosity","A colorful, liquid-like substance (oobleck) is spread across the surface of a large speaker cone. When a low-frequency sound wave is played, the vibrations apply a sudden force. Then the sound stops.",https://www.youtube.com/watch?v=3zoTKXXNQIU,"As the speaker vibrates at low frequencies, the oobleck stiffens and leaps into motion, forming solid-like spikes and writhing tendrils in sync with the sound waves. When the vibrations stop, the shear stress vanishes, and the material relaxes back into a smooth, liquid state — vividly showing its Non-Newtonian behavior.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu","lx: speaker cone facing up?
mk: wdym? didn’t get it.","{hailuo2.3: [3, 2, 3], klingv2.5: [4, 4, 4], ray-2: [1, 3, 1], seed-dance: [4, 4, 2], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 1]}
","{hailuo2.3: [1, 1, 2], klingv2.5: [2, 4, 3], ray-2: [1, 3, 1], seed-dance: [3, 2, 2], sora-2: [4, 2, 3], veo3: [3], wan2.5: [4, 4, 2]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 4, 4], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 3]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [2, 1, 1], ray-2: [1, 1, 1], seed-dance: [1, 1, 1], sora-2: [3, 3, 3], veo3: [2], wan2.5: [1, 1, 1]}
","{hailuo2.3: [1, 3, 2], klingv2.5: [4, 4, 2], ray-2: [1, 2, 2], seed-dance: [3, 3, 3], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
",57
,Physics,"Buoyancy, Density, Pressure","A small empty eyedropper floats in a sealed plastic bottle of water. A person squeezes the sides of the bottle. The person then lets go of the bottle. ",https://www.youtube.com/watch?v=aYNpTomZeGM,"When the bottle is squeezed, the diver sinks smoothly to the bottom as the increased pressure compresses the air bubble inside it, raising its density. Once the pressure is released, the air bubble expands again, the diver’s density decreases, and it floats back to the top — demonstrating Pascal’s Principle and buoyancy control.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu","dz: maybe we need to specify that the bottle is squeezed at the bottom
mk: in the youtube video, the speaker doesn’t squeeze at the bottom?","{hailuo2.3: [1, 1, 1], klingv2.5: [1, 2, 4], ray-2: [1, 1, 1], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [2], wan2.5: [4, 4, 4]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [1, 2, 4], ray-2: [2, 1, 2], seed-dance: [3, 4, 3], sora-2: [4, 4, 3], veo3: [3], wan2.5: [3, 4, 3]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [1, 4, 1], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [1, 2, 1], ray-2: [1, 1, 1], seed-dance: [1, 1, 1], sora-2: [1, 4, 4], veo3: [1], wan2.5: [1, 1, 1]}
","{hailuo2.3: [1, 2, 2], klingv2.5: [2, 4, 3], ray-2: [1, 2, 1], seed-dance: [2, 3, 1], sora-2: [3, 2, 3], veo3: [2], wan2.5: [3, 4, 3]}
",56
never burning paper,Physics,"Heat, Thermal conduction","Wrap a sheet of paper firmly around a glass bottle, ensuring it fits snugly without gaps. Hold the bottle near the flame of a lit candle.",https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"The paper does not burn immediately where it contacts the glass, though the exposed edges may char.",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: looks good yujie: LGTM,"{’hailuo2.3’: [4, 2, 4], ‘seedance1pro’: [4, 4, 4], ‘sora2’: [4, 4, 3], ‘veo3.1’: [4], ‘wan2.5’: [4, 2, 4], ‘kling2.5turbo’: [4, 3, 4], ‘ray2’: [4, 2, 3]}","{’hailuo2.3’: [4, 1, 4], ‘seedance1pro’: [2, 4, 4], ‘sora2’: [4, 4, 3], ‘veo3.1’: [4], ‘wan2.5’: [4, 3, 3], ‘kling2.5turbo’: [4, 3, 4], ‘ray2’: [4, 2, 3]}","{’hailuo2.3’: [4, 2, 3], ‘seedance1pro’: [2, 4, 4], ‘sora2’: [4, 4, 3], ‘veo3.1’: [4], ‘wan2.5’: [4, 2, 2], ‘kling2.5turbo’: [4, 2, 4], ‘ray2’: [4, 2, 3]}","{'hailuo2.3': [3, 2, 3], 'seedance1pro': [1, 3, 1], 'sora2': [4, 3, 1], 'veo3.1': [4], 'wan2.5': [3, 3, 1], 'kling2.5turbo': [2, 3, 2], 'ray2': [2, 2,2]}","{'hailuo2.3': [4, 3, 3], 'seedance1pro': [2, 3, 2], 'sora2': [4, 3, 2], 'veo3.1': [4], 'wan2.5': [3, 3, 1], 'kling2.5turbo': [4, 3, 2], 'ray2': [2, 2, 2]}",225
money bridge,Physics,"Deformation, Structural Physics","Fold a money bill several times lengthwise and position it so that it bridges the gap between two glasses placed close together. Then, gently place an empty glass on top of the folded bill at the midpoint between the two supporting glasses.",https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,The paper bill can now better support the third glass.,Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: looks good yujie: will it be better to add more concrete,"{’hailuo2.3’: [4, 4,4], ‘seedance1pro’: [4, 4,3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [4, 4,4], ‘kling2.5turbo’: [4, 4, 4], ‘ray2’: [4, 4,4]}","{’hailuo2.3’: [4,3, 4], ‘seedance1pro’: [4, 4, 3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [3, 4, 4], ‘kling2.5turbo’: [4, 4, 4], ‘ray2’: [4, 4,4]}","{’hailuo2.3’: [4, 3, 4], ‘seedance1pro’: [3, 4, 3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [3, 4, 2], ‘kling2.5turbo’: [4, 4, 4], ‘ray2’: [4, 4, 4]}","{'hailuo2.3': [1, 3, 2], 'seedance1pro': [1, 1, 2], 'sora2': [4, 4, 2], 'veo3.1': [3], 'wan2.5': [2, 4, 2], 'kling2.5turbo': [1, 4, 3], 'ray2': [1, 2, 2]}","{'hailuo2.3': [1, 2, 3], 'seedance1pro': [1, 2, 2], 'sora2': [4, 4, 1], 'veo3.1': [3], 'wan2.5': [2, 3, 3], 'kling2.5turbo': [1, 3, 4], 'ray2': [1, 2, 2]}",224
Floating egg,Physics,"Density and Buoyancy, Gravity",Fill one glass with fresh water and another with salt water (prepared by dissolving about three spoonfuls of salt). Gently place one egg into each glass and observe their positions in the water.,https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"The egg in fresh water sinks to the bottom, while the egg in salt water floats near the surface.",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: looks good,"{’hailuo2.3’: [3, 4, 4], ‘seedance1pro’: [3, 3, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [4, 3, 4], ‘kling2.5turbo’: [4,4, 4], ‘ray2’: [4, 3, 4]}","{’hailuo2.3’: [3, 3, 3], ‘seedance1pro’: [2, 2, 3], ‘sora2’: [4, 4, 2], ‘veo3.1’: [2], ‘wan2.5’: [4, 2, 3], ‘kling2.5turbo’: [4,3, 4], ‘ray2’: [2, 3, 4]}","{’hailuo2.3’: [2, 4, 4], ‘seedance1pro’: [2, 2, 3], ‘sora2’: [4, 4, 2], ‘veo3.1’: [2], ‘wan2.5’: [3, 3, 3], ‘kling2.5turbo’: [3, 4, 4], ‘ray2’: [4, 3, 4]}","{'hailuo2.3': [4, 3, 2], 'seedance1pro': [1, 2, 2], 'sora2': [4, 4, 3], 'veo3.1': [2], 'wan2.5': [3, 3, 2], 'kling2.5turbo': [3, 4, 2], 'ray2': [2, 2, 1]}","{'hailuo2.3': [3, 4, 4], 'seedance1pro': [3, 1, 3], 'sora2': [4, 3, 3], 'veo3.1': [2], 'wan2.5': [2, 3, 3], 'kling2.5turbo': [3, 4, 3], 'ray2': [2, 2, 1]}",223
Ferrofliud effect,Physics,"Magnetics, Nano Science",Bring a magnet close to a Petri dish containing ferrofluid and observe how the fluid reacts to the magnetic field.,https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,The alignment of particles causes the fluid to form spike-like patterns that trace the invisible magnetic field lines around the magnet.,Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: looks good,"{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 3, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [3, 3, 4], ‘kling2.5turbo’: [4, 4, 4], ‘ray2’: [3, 3, 3]}","{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 2, 3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [2, 3, 2], ‘kling2.5turbo’: [4, 4, 3], ‘ray2’: [3, 2, 3]}","{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 2, 3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [2, 2, 2], ‘kling2.5turbo’: [4, 4, 3], ‘ray2’: [2, 2, 2]}","{'hailuo2.3': [4, 3, 3], 'seedance1pro': [3, 2, 3], 'sora2': [4, 4, 4], 'veo3.1': [4], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [3, 4, 3], 'ray2': [2, 3, 1]}","{'hailuo2.3': [4, 3, 2], 'seedance1pro': [4, 2, 3], 'sora2': [4, 3, 4], 'veo3.1': [4], 'wan2.5': [2, 2, 2], 'kling2.5turbo': [4, 4, 3], 'ray2': [2, 3, 1]}",222
Burning volcano,Chemistry,"Chemical Reaction, Heat",Use a lighter to ignite a small pile of a dry mixture of baking soda and sugar (in a 3:2 ratio) and observe the reaction.,https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"After ignition, the mixture begins to smolder and expand, producing a long, black, snake-like column that slowly grows outward from the pile. The structure is lightweight, porous, and carbon-rich.",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao","yixin: the prompt needs to be rephrased; in the video generated by Wan, it did not show as being lit","{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 4, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [4, 3, 4], ‘kling2.5turbo’: [4, 4, 4], ‘ray2’: [4, 2, 4]}","{’hailuo2.3’: [4, 2, 3], ‘seedance1pro’: [4, 3, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [4, 2, 3], ‘kling2.5turbo’: [4, 3, 4], ‘ray2’: [4, 2, 3]}","{’hailuo2.3’: [4, 3, 3], ‘seedance1pro’: [4, 4, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [4, 2, 3], ‘kling2.5turbo’: [3, 3, 3], ‘ray2’: [2, 3, 2]}","{'hailuo2.3': [4, 2, 2], 'seedance1pro': [2, 2, 3], 'sora2': [4, 4, 4], 'veo3.1': [4], 'wan2.5': [4, 2, 3], 'kling2.5turbo': [2, 2, 2], 'ray2': [1, 1, 1]}","{'hailuo2.3': [4, 4, 3], 'seedance1pro': [3, 3, 4], 'sora2': [4, 4, 4], 'veo3.1': [4], 'wan2.5': [4, 2, 3], 'kling2.5turbo': [2, 2, 2], 'ray2': [1, 1, 2]}",221
,Chemistry,"Fluorescence, Phosphorescence, Quantum Mechanics","A close-up shot of several different mineral rocks under normal light. An ultraviolet (UV) light is turned on, and the rocks instantly become luminous, glowing in bright, vivid colors like green, orange, and blue. The UV light is then suddenly switched off.",https://www.youtube.com/watch?v=-vvWrL5dYIw,"When exposed to UV light, several rocks fluoresce brightly in various colors, immediately ceasing to glow once the light is turned off. However, one rock continues to emit light and gradually fades, demonstrating phosphorescence — the delayed release of stored energy after excitation.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu","lx: [modified] what kind of rocks fluoresce? we should specify in the prompt?
mk: fixed it.","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 4, 2], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [4, 3, 4], klingv2.5: [4, 3, 3], ray-2: [4, 4, 2], seed-dance: [4, 2, 2], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 1, 1]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 1, 4], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [3, 1, 1], klingv2.5: [2, 3, 3], ray-2: [1, 1, 1], seed-dance: [1, 2, 1], sora-2: [4, 2, 2], veo3: [1], wan2.5: [2, 2, 2]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 3, 3], ray-2: [2, 2, 2], seed-dance: [2, 3, 2], sora-2: [4, 4, 4], veo3: [4], wan2.5: [3, 2, 2]}
",55
,Chemistry,"Fluorescence, Light Spectrum","In a darkened room, a hand holds a UV (ultraviolet) flashlight over a clear beaker of tonic water. The invisible UV light then shines on the liquid.",https://www.youtube.com/watch?v=xUvLKXHMZqo,The tonic water appears blue in the UV light.,Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu","lx: phenonmenon in the prompt. cleaned up
mk: updated it","{hailuo2.3: [4, 3, 4], klingv2.5: [4, 4, 4], ray-2: [3, 1, 1], seed-dance: [2, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [3, 4, 4], klingv2.5: [2, 3, 2], ray-2: [1, 1, 1], seed-dance: [1, 3, 2], sora-2: [3, 3, 4], veo3: [1], wan2.5: [4, 2, 2]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [3, 3, 3], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [2, 2, 3], klingv2.5: [2, 2, 3], ray-2: [1, 1, 2], seed-dance: [1, 1, 1], sora-2: [3, 2, 4], veo3: [4], wan2.5: [1, 1, 1]}
","{hailuo2.3: [4, 3, 4], klingv2.5: [4, 4, 4], ray-2: [2, 2, 3], seed-dance: [1, 2, 2], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 3, 3]}
",54
,Physics,"Fluorescence, Hydrodynamics",A strip of filter paper is marked with a small black ink spot slightly above the solvent line. The lower end of the paper is submerged in a clear solvent inside a beaker while the ink spot remains above the liquid. Cut to the paper being shown 12 hours later after being left undisturbed.,https://www.youtube.com/watch?v=eInQ4dE6DHk,"After several hours, the ink separates into distinct colored bands as the solvent travels upward — typically blue and green regions near the bottom and red or violet regions farther up.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu",dz: completely rewrote prompt and phenomenon,,,,,,53
Egg and Vinegar Experiment (Bouncing Egg),Chemistry,"Acid-Base Reaction, membrane elasticity","Submerge an egg in vinegar for 24 hours, shell dissolves, then bounce egg gently on surface; camera close-up of elasticity and translucent shell.",https://www.youtube.com/watch?v=pVDqiYIxvdA,Egg becomes “bouncy” and translucent after shell removal.,Murray,Wan2.5,Not started,"Daniel Zhao, Lanxiang Hu",dz: i dont know if this can be shown in 10 mins. also the answer is in the prompt again,,,,,,52
,Physics,"Electrochemistry, Simple circuit","A close-up shot shows a zinc-coated nail and a copper wire being inserted into a lemon. These two electrodes are then connected by wires to a small red LED, completing a simple circuit. ",https://www.youtube.com/shorts/JvYT7cAEf_o,"When the zinc nail and copper wire are inserted into the lemon and connected to the LED, a small voltage generated by the electrochemical reaction between the two metals and the citric acid causes electrons to flow, lighting up the LED and demonstrating a simple lemon battery.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu","dz: changed prompt. had result of experiment inside the prompt
mk: thanks","{hailuo2.3: [3, 1, 3], klingv2.5: [3, 3, 4], ray-2: [1, 1, 1], seed-dance: [4, 1, 2], sora-2: [2, 4, 4], veo3: [4], wan2.5: [4, 4, 2]}
","{hailuo2.3: [2, 1, 4], klingv2.5: [3, 3, 3], ray-2: [1, 1, 1], seed-dance: [3, 1, 1], sora-2: [4, 4, 3], veo3: [4], wan2.5: [3, 3, 1]}
","{hailuo2.3: [4, 3, 4], klingv2.5: [4, 1, 4], ray-2: [4, 4, 1], seed-dance: [4, 1, 4], sora-2: [4, 4, 4], veo3: [3], wan2.5: [4, 4, 3]}
","{hailuo2.3: [2, 1, 1], klingv2.5: [3, 1, 1], ray-2: [1, 1, 1], seed-dance: [3, 3, 2], sora-2: [3, 4, 3], veo3: [2], wan2.5: [1, 3, 3]}
","{hailuo2.3: [1, 2, 1], klingv2.5: [3, 3, 3], ray-2: [1, 1, 1], seed-dance: [4, 3, 2], sora-2: [2, 3, 3], veo3: [4], wan2.5: [3, 3, 3]}
",51
,Physics,"Electrolysis, Simple circuit",A simple circuit powered by a 9V battery is connected to two pencil graphite electrodes dipped into saltwater.,https://www.youtube.com/watch?v=Rs5FMACcKV0,"The current from the simple circuit drives an electrolysis reaction, chemically decomposing the water and salt solution and causing bubbles of hydrogen and oxygen gas to visibly form at the electrodes.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu",lx: lgtm dz: good,"{hailuo2.3: [4, 2, 1], klingv2.5: [4, 4, 2], ray-2: [2, 1, 1], seed-dance: [4, 2, 3], sora-2: [4, 3, 2], veo3: [4], wan2.5: [3, 4, 4]}
","{hailuo2.3: [1, 4, 1], klingv2.5: [3, 1, 1], ray-2: [1, 1, 1], seed-dance: [4, 3, 1], sora-2: [4, 3, 2], veo3: [4], wan2.5: [2, 2, 2]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [4, 4, 3], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 1, 4]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [3, 1, 3], ray-2: [2, 1, 1], seed-dance: [1, 1, 1], sora-2: [4, 2, 4], veo3: [4], wan2.5: [4, 1, 1]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [2, 4, 3], ray-2: [2, 1, 1], seed-dance: [2, 2, 2], sora-2: [4, 4, 4], veo3: [3], wan2.5: [4, 2, 4]}
",50
Keep a Paper Towel Dry Under Water,Physics,"Air pocket, Buoyancy, pressure equilibrium","A scrunched-up paper towel is placed in a glass. The glass is then submerged top first (upside-down) into a glass tank filled with water. The glass is then taken out of the tank, and the paper towel is removed from the glass. The person shows the condition of the paper towel to the camera.",https://youtu.be/pVDqiYIxvdA?si=NT-rGc1iNvdCtrAM&t=769,Paper towel stays dry under inverted glass in water.,Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu","dz: changed, seems good now","{hailuo2.3: [3, 1, 1], klingv2.5: [3, 1, 1], ray-2: [1, 1, 1], seed-dance: [1, 1, 1], sora-2: [4, 4, 4], veo3: [3], wan2.5: [3, 1, 1]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [1, 1, 1], ray-2: [1, 1, 1], seed-dance: [1, 1, 1], sora-2: [4, 3, 4], veo3: [2], wan2.5: [3, 1, 1]}
","{hailuo2.3: [4, 1, 3], klingv2.5: [4, 4, 3], ray-2: [4, 1, 3], seed-dance: [4, 4, 4], sora-2: [4, 3, 3], veo3: [3], wan2.5: [1, 4, 3]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [3, 1, 1], ray-2: [1, 1, 1], seed-dance: [1, 1, 1], sora-2: [2, 3, 2], veo3: [2], wan2.5: [3, 1, 2]}
","{hailuo2.3: [1, 1, 2], klingv2.5: [4, 3, 4], ray-2: [1, 1, 1], seed-dance: [2, 1, 2], sora-2: [3, 4, 2], veo3: [2], wan2.5: [3, 2, 3]}
",49
,Physics,"Friction, Sound","A close-up, slow-motion shot of a violin bow, coated in rosin, being dragged across a violin string.",https://www.youtube.com/watch?v=6JeyiM0YNo4,"The ""stick-slip"" friction of the bow will repeatedly pull and release the string, causing it to vibrate and form a clear standing wave pattern.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu",lx: lgtm dz: good,"{hailuo2.3: [3, 3, 3], klingv2.5: [4, 1, 1], ray-2: [1, 1, 1], seed-dance: [4, 3, 4], sora-2: [3, 3, 4], veo3: [4], wan2.5: [1, 4, 4]}
","{hailuo2.3: [1, 2, 2], klingv2.5: [1, 3, 1], ray-2: [1, 1, 1], seed-dance: [2, 3, 2], sora-2: [4, 1, 4], veo3: [1], wan2.5: [2, 4, 4]}
","{hailuo2.3: [4, 4, 4], klingv2.5: [4, 4, 4], ray-2: [2, 1, 2], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [1, 1, 1], ray-2: [1, 1, 1], seed-dance: [1, 1, 1], sora-2: [1, 1, 1], veo3: [1], wan2.5: [1, 1, 1]}
","{hailuo2.3: [4, 1, 1], klingv2.5: [1, 1, 3], ray-2: [1, 1, 1], seed-dance: [1, 2, 3], sora-2: [4, 3, 4], veo3: [4], wan2.5: [2, 3, 2]}",48
,Physics,"Friction, Static Electricity","A person vigorously rubs a balloon on their hair, showing the transfer of electrons due to friction. The person then brings the balloon next to a neutral wall and lets go of the balloon.",https://www.youtube.com/watch?v=QzprKH1bLJM,"After the person rubs the balloon on their hair, their hair strands stand up and the balloon gains a static charge. When brought near a neutral wall, the charged balloon sticks to it, illustrating how friction transfers electrons and induces opposite charges that attract.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu","dz: CHANGED, prompt had phenomenon in it","{hailuo2.3: [1, 4, 1], klingv2.5: [4, 4, 3], ray-2: [1, 1, 1], seed-dance: [4, 2, 3], sora-2: [4, 4, 2], veo3: [3], wan2.5: [4, 1, 2]}
","{hailuo2.3: [1, 4, 1], klingv2.5: [3, 4, 2], ray-2: [1, 1, 1], seed-dance: [4, 2, 2], sora-2: [4, 3, 3], veo3: [2], wan2.5: [2, 1, 2]}
","{hailuo2.3: [4, 4, 2], klingv2.5: [4, 4, 4], ray-2: [3, 1, 3], seed-dance: [4, 4, 4], sora-2: [2, 4, 4], veo3: [4], wan2.5: [4, 4, 3]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [4, 4, 4], ray-2: [1, 1, 1], seed-dance: [4, 2, 4], sora-2: [3, 4, 4], veo3: [4], wan2.5: [1, 1, 4]}
","{hailuo2.3: [1, 1, 3], klingv2.5: [1, 2, 3], ray-2: [1, 2, 1], seed-dance: [4, 3, 3], sora-2: [3, 4, 3], veo3: [3], wan2.5: [3, 3, 3]}
",47
,Physics,"Friction, Heat","A split-screen shot. On the left, a person's hands are shown in normal light, rubbing together vigorously. On the right, the exact same action is shown through a thermal camera.",https://youtu.be/pVDqiYIxvdA?si=6_H2K-6tE-43D-s3&t=348,"As the person rubs their hands together, the thermal camera view on the right reveals a clear increase in surface temperature — the hands gradually shift from cooler blue tones to warm yellow and red, visually demonstrating the conversion of mechanical energy into heat through friction.",Murray,Wan2.5,Done,"Daniel Zhao, Lanxiang Hu","dz: prompt has expected phenomenon in it
mk: where?
dz: i changed it already, should have mentioned sorry","{hailuo2.3: [4, 3, 2], klingv2.5: [3, 3, 3], ray-2: [1, 1, 1], seed-dance: [2, 2, 2], sora-2: [3, 2, 2], veo3: [4], wan2.5: [4, 4, 3]}
","{hailuo2.3: [4, 3, 2], klingv2.5: [3, 4, 2], ray-2: [2, 1, 1], seed-dance: [3, 2, 1], sora-2: [3, 2, 2], veo3: [4], wan2.5: [4, 3, 2]}
","{hailuo2.3: [4, 4, 3], klingv2.5: [4, 4, 4], ray-2: [4, 4, 4], seed-dance: [4, 4, 4], sora-2: [4, 4, 4], veo3: [4], wan2.5: [4, 4, 4]}
","{hailuo2.3: [1, 1, 1], klingv2.5: [1, 1, 1], ray-2: [1, 1, 1], seed-dance: [2, 1, 2], sora-2: [3, 2, 2], veo3: [4], wan2.5: [2, 2, 4]}
","{hailuo2.3: [3, 2, 2], klingv2.5: [2, 1, 2], ray-2: [1, 1, 1], seed-dance: [2, 2, 2], sora-2: [4, 4, 4], veo3: [3], wan2.5: [4, 3, 4]}
",46
Total Internal Reflection,Physics,"Reflection, Refraction, Total Internal Reflection","A clear plastic water bottle has a small hole in its side, from which a smooth, laminar stream of water is flowing. A red laser pointer is aimed from the other side of the bottle, directly through the water and into the hole.",https://www.youtube.com/watch?v=gUPbysSt7XU&t=2s,"The laser beam enters the stream and becomes ""trapped."" It reflects repeatedly off the inner surface of the water stream, causing the entire parabolic arc of the falling water to glow red as if it were a fiber optic cable.",Abhilash,Wan2.5,Done,"Daniel Zhao, Murray Kang",mk: good! dz: good,,,,,,87
Dancing candle,Physics,"Angular Momentum, Thermal convection","Mount a candle horizontally so that it can pivot freely about its center. Light one end of the candle and allow it to burn for a short while, then light the other end as well.",https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"After both ends are burning, the candle begins to rock, rotating back and forth.",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: looks good,"{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [3, 3, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [4, 4,  3], ‘kling2.5turbo’:[4, 3, 4], ‘ray2’: [4, 4, 3]}","{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [2, 2, 3], ‘sora2’: [4, 4, 3], ‘veo3.1’: [4], ‘wan2.5’: [4, 3, 4], ‘kling2.5turbo’: [4, 2, 4], ‘ray2’: [4, 4, 2]}","{’hailuo2.3’: [2, 4, 4], ‘seedance1pro’: [2, 3, 2], ‘sora2’: [4, 4, 3], ‘veo3.1’: [3], ‘wan2.5’:[3, 3, 4], ‘kling2.5turbo’: [3, 2, 4], ‘ray2’: [4, 4, 3]}","{’hailuo2.3’: [4, 2, 3], ‘seedance1pro’: [1, 2, 1], ‘sora2’: [3, 4, 4], ‘veo3.1’: [2], ‘wan2.5’: [2, 2, 2], ‘kling2.5turbo’: [2, 2, 4], ‘ray2’: [1, 1, 1]}","{’hailuo2.3’: [4, 2, 4], ‘seedance1pro’: [2, 2, 2], ‘sora2’: [3, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [3, 3, 3], ‘kling2.5turbo’: [2, 3, 4], ‘ray2’: [1, 1, 1]}",220
Standing handle,Physics,"Chemical Reaction, Statistical equilibrium","Place a sheet of toilet paper on a glass tray and add a small amount of water to make the paper damp. Position a small candle at the center of the tray on top of the wet paper and light the candle. Quickly cover the candle with an inverted dry glass, ensuring that the rim of the glass rests firmly on the wet paper to form a tight seal. After the flame goes out, carefully lift the tray by holding only the inverted glass.",https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"The candle initially burns brightly but soon goes out. The water-soaked paper and tray remain sealed to the glass, allowing the tray to lift when the glass is raised.",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: looks good,"{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 3, 4], ‘sora2’: [4, 3, 4], ‘veo3.1’:[4] , ‘wan2.5’: [4, 4, 4], ‘kling2.5turbo’: [3, 2, 3], ‘ray2’: [3, 3, 2]}","{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 3, 4], ‘sora2’: [4,3, 3], ‘veo3.1’: [3], ‘wan2.5’: [4, 4, 4], ‘kling2.5turbo’: [4, 2, 4], ‘ray2’: [3, 3, 2]}","{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 3, 4], ‘sora2’: [4, 3, 2], ‘veo3.1’: [3], ‘wan2.5’: [4, 4, 4], ‘kling2.5turbo’: [3, 2, 3] , ‘ray2’: [2, 2, 2]}","{’hailuo2.3’: [2, 3, 2], ‘seedance1pro’: [2, 2, 2], ‘sora2’: [4, 2, 2] , ‘veo3.1’: [2], ‘wan2.5’: [2, 3, 2], ‘kling2.5turbo’: [1, 1, 2] , ‘ray2’: [2, 1, 1]}","{’hailuo2.3’: [3, 3, 3], ‘seedance1pro’: [2, 2, 3], ‘sora2’: [4, 2, 3], ‘veo3.1’: [2], ‘wan2.5’: [2, 3, 3], ‘kling2.5turbo’: [1, 1, 3], ‘ray2’: [1, 1, 1]}",219
Firm Ballon,Physics,"Newton's Laws, Pressure","Firmly anchor a number of nails upright on a wooden plank, spacing them evenly to form a bed of nails. Gently press or lightly smash an inflated balloon against the nail bed and observe that the balloon remains intact.",https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"When in contact with many nails, the balloon does not pop, but when the same force is applied to a single nail, it bursts immediately.",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: looks good,"{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 4, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [4, 4, 4], ‘kling2.5turbo’: [4, 4, 4], ‘ray2’: [4, 4,  4]}","{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 4, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [4, 4, 4], ‘kling2.5turbo’: [4, 4, 4], ‘ray2’: [3, 3, 4]}","{’hailuo2.3’: [4, 4, 4],  ‘seedance1pro’: [4, 4, 4], ‘sora2’: [4, 4,4], ‘veo3.1’: [4], ‘wan2.5’: [4, 4, 4], ‘kling2.5turbo’: [4, 4, 4], ‘ray2’: [4, 4, 4]}","{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 4, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [3], ‘wan2.5’:[4, 4, 4], ‘kling2.5turbo’: [4, 4, 4], ‘ray2’: [2, 1, 1]}","{’hailuo2.3’:[4, 4, 4], ‘seedance1pro’: [4, 4, 4], ‘sora2’: [3, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [4, 4, 4], ‘kling2.5turbo’: [4, 4, 4], ‘ray2’: [1, 2, 1]}",218
“Freezing” Hot water,Physics,"Heat, Phase transitions",Prepare a solution of sodium acetate trihydrate at room temperature. Gently place four fingers into the solution.,https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"The initially clear liquid solidifies almost instantly upon contact, releasing noticeable warmth during crystallization.",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: looks good,"{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [4, 4, 3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [4, 3, 3], ‘kling2.5turbo’: [4, 3, 4], ‘ray2’:[4, 3, 4] }","{’hailuo2.3’: [3, 3, 3], ‘seedance1pro’: [4, 2, 3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [4, 3, 3], ‘kling2.5turbo’: [3, 2, 4], ‘ray2’: [3, 2, 3]}","{’hailuo2.3’:[3, 3, 3] , ‘seedance1pro’: [4, 3, 2], ‘sora2’: [4, 3, 4], ‘veo3.1’: [4], ‘wan2.5’: [4, 3, 2], ‘kling2.5turbo’: [4, 2, 4], ‘ray2’: [2, 2, 2] }","{’hailuo2.3’: [3, 1, 2], ‘seedance1pro’: [1, 1, 1], ‘sora2’: [2, 2, 3], ‘veo3.1’: [4], ‘wan2.5’: [1, 2, 1], ‘kling2.5turbo’: [1, 2, 1], ‘ray2’: [1, 2, 3]}","{’hailuo2.3’: [4, 3, 2], ‘seedance1pro’: [2, 2, 2], ‘sora2’: [3, 3, 4], ‘veo3.1’: [4], ‘wan2.5’: [1, 2, 2], ‘kling2.5turbo’: [3, 2, 3], ‘ray2’: [2, 2, 2]}",217
Vinegar fire distinguisher,Chemistry,"Chemical Reaction, Combustion / flammability","Add a few spoonfuls of baking soda to the vinegar and immediately cover a jar of vinegar with a piece of cardboard. After a few seconds, remove the cardboard and carefully tilt the jar toward a few burning candles.",https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,The flames of the candles go out even though the liquid never touches them.,Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: missing a keyword,"{’hailuo2.3’: [4, 2, 4], ‘seedance1pro’: [4, 2, 3], ‘sora2’: [4, 2, 3], ‘veo3.1’: [3], ‘wan2.5’: [4, 2, 2] , ‘kling2.5turbo’: [2, 4, 4], ‘ray2’: [4, 4, 4]}","{’hailuo2.3’: [4, 2, 4], ‘seedance1pro’: [4, 2, 2], ‘sora2’: [4, 2, 3], ‘veo3.1’: [3], ‘wan2.5’: [2, 2, 2], ‘kling2.5turbo’: [2, 3, 3], ‘ray2’: [4, 3, 4]}","{’hailuo2.3’: [3, 2, 4], ‘seedance1pro’: [3, 2, 2], ‘sora2’: [4, 2, 3], ‘veo3.1’: [3], ‘wan2.5’: [2, 2, 2] , ‘kling2.5turbo’: [2, 3, 3], ‘ray2’: [4, 4, 4]}","{’hailuo2.3’: [2, 2,2], ‘seedance1pro’: [3, 2, 2], ‘sora2’: [2, 2, 2], ‘veo3.1’: [3], ‘wan2.5’: [1, 2, 2] , ‘kling2.5turbo’: [2, 2, 2], ‘ray2’: [1, 1, 1]}","{’hailuo2.3’: [1, 2, 3], ‘seedance1pro’: [3, 2, 2], ‘sora2’: [2, 2, 2], ‘veo3.1’: [3], ‘wan2.5’: [2, 2, 2] , ‘kling2.5turbo’: [2, 2, 2], ‘ray2’: [1, 1, 1]}",216
Dry paper in water,Physics,"Pressure, Statistical equilibrium",Place a piece of dry toilet paper snugly at the bottom of an empty glass. Hold the glass upside down and submerge it vertically and completely into a transparent tank of water.,https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,The water doesn’t enter the glass and the toilet paper remains dry even though the glass is underwater.,Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: looks good,"{’hailuo2.3’: [3, 4, 3], ‘seedance1pro’: [3, 3, 4], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [3, 4, 4], ‘kling2.5turbo’: [3, 4, 4], ‘ray2’: [3, 3, 2]}","{’hailuo2.3’: [3, 3, 2], ‘seedance1pro’: [2, 3, 3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [3, 4, 4], ‘kling2.5turbo’: [3, 3, 3], ‘ray2’: [3, 4, 2]}","{’hailuo2.3’: [3, 3, 2], ‘seedance1pro’: [2, 3, 3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [3, 3, 3], ‘kling2.5turbo’: [3, 3, 2], ‘ray2’: [1, 4, 2]}","{’hailuo2.3’: [2,3, 2], ‘seedance1pro’: [2, 2, 2], ‘sora2’: [3, 4, 4], ‘veo3.1’: [2], ‘wan2.5’: [3, 3, 2], ‘kling2.5turbo’: [2, 2, 2], ‘ray2’: [1, 1,1]}","{’hailuo2.3’: [2, 3, 1], ‘seedance1pro’: [2, 2, 2], ‘sora2’: [3, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [2, 3, 2], ‘kling2.5turbo’: [2, 2, 2], ‘ray2’: [1, 1, 1]}",215
Invisible Extinguisher,Chemistry,"Acid-Base Reaction, Combustion / flammability","A person mixes vinegar and baking soda in a tall cup, and instantly tilt the cup over a burning candle as if pouring, but no liquid leaves the cup.",https://www.youtube.com/watch?v=icCKCQ8pRcU&t=53s,"The mixture foams vigorously, releasing an invisible gas that flows downward. When the cup is tilted toward the candle, the flame is instantly extinguished even though no liquid touches it.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang",mk: changed the link to youtube link; maybe better for downloading later.,,,,,,126
Supersaturated Sodium Acetate,Chemistry,"Phase transitions, Precipitation reaction, Thermal convection","A beaker contains a clear, colorless, supersaturated sodium acetate solution. A small sodium acetate crystal is dropped into the center of the solution.",https://www.youtube.com/watch?v=rsyW4K6ozRE,"The clear solution rapidly solidifies into a mass of white sodium acetate crystals, spreading outward from the seed crystal within seconds. The exothermic crystallization releases heat, producing visible vapor that condenses on the cooler inner walls of the beaker as a thin mist.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang",mk: good,,,,,,125
Chemical Traffic Light,Chemistry,"Indicator color change, Redox Reaction","A flask containing a yellow solution of glucose, sodium hydroxide, and the indicator indigocarmine is shown. The person lifts and gently shakes the flask.",https://www.youtube.com/watch?v=-DCkPN_FgOQ,"The yellow solution rapidly shifts toward green as the flask is shaken, showing the indicator’s partial oxidation by oxygen introduced from the air. Continued shaking drives the oxidation further and the color moves from green to red. When agitation stops, dissolved glucose reduces the indicator and the solution relaxes back to yellow.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang","Abhilash: Is this reaction possible in 5 secs?
Forrest: Will change it to only containing the shaking part (green → red → yellow)",,,,,,124
Baking Soda Volcano,Chemistry,"Acid-Base Reaction, Thermal convection","A small plastic bottle sits in a tray. A mixture of warm vinegar, a few drops of dish soap, and water is already inside. A spoonful of baking soda slurry is quickly poured in through a funnel.",https://www.youtube.com/watch?v=x8--3M7GGCA,"Within seconds, a vigorous foamy eruption bursts upward and overflows the bottle like lava from a volcano. The fizzing continues briefly as bubbles of gas escape through the soapy foam.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang",mk: good,,,,,,123
Dry Ice Bubbles,Physics,"Phase transitions, Statistical equilibrium",Place a small chunk of dry ice into a tall glass filled with clear warm soapy water.,https://www.youtube.com/watch?v=hSizkoEFImc,A large amount of white misty bubbles rapidly forms and overflows the rim of the glass.,Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang",mk: good,,,,,,122
Al + CuSO₄,Chemistry,"Precipitation reaction, Redox Reaction","Immerse a clean strip of aluminum foil into a shallow clear dish containing blue copper sulfate solution.",https://www.youtube.com/shorts/-hV5N-5ION4,"The aluminum foil gradually darkens, then develops a reddish copper coating as the reaction proceeds.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang","Abhilash: Rephrase the prompt, foil is place inside the dish (like on the surface of solution)",,,,,,121
CO₂ into Limewater,Chemistry,"Acid-Base Reaction, Precipitation reaction","Two clear cups are shown side by side. The left cup contains fizzing vinegar and baking soda; the right cup contains clear limewater. A straw connects the two cups, guiding the gas from the left cup into the limewater in the right cup.",https://www.youtube.com/watch?v=bkiJ3xzYnY8,"The limewater quickly turns milky white, and bubbles rise from the bottom.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang","Abhilash: Do we need to mention the gas flow direction in the prompt?
Forrest: fixed ✅

mk: good",,,,,,120
https://knowledge.carolina.com/discipline/physical-science/chemistry/elephant-toothpaste-2/lephant Toothpaste,Chemistry,"Redox Reaction, Thermal conduction",A small beaker with potassium iodide solution pours into a tall narrow flask with dyed soapy hydrogen peroxide.,https://www.youtube.com/watch?v=ezsur0L0L1c,A thick foam jets up immediately and keeps expanding for several seconds.,Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang",mk: good,,,,,,119
Dancing Raisins,Physics,"Buoyancy, Density, Solubility",A few raisins are dropped into a clear tall glass of colorless soda.,https://www.youtube.com/watch?v=ctWsPa0DCoA,"Raisins begin rising within a few seconds as bubbles attach, then sink as bubbles pop.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang","Abhilash: Is this instantaneous?
Forrest: Yes if we start the video from adding raisins. You can check the youtube link",,,,,,118
Comb Near a Faucet,Physics,"Electrostatics, Gravity, Polarization","A plastic comb, freshly rubbed on dry hair, is held close to a thin vertical stream of water from a faucet.",https://www.youtube.com/watch?v=Lvwtrk0wr0Y,"The charged comb attracts the water stream, which bends clearly toward the comb and straightens again when it’s moved away.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang",mk: good,,,,,,117
The Weissenberg Effect,Chemistry,"Viscoelasticity, Viscosity","A vertical metal rod is lowered into the center of a beaker filled with a clear, thick polymer solution (a viscoelastic, non-Newtonian fluid). The rod then begins to rotate quickly.",https://en.wikipedia.org/wiki/Weissenberg_effect,"Instead of forming a vortex and dipping down at the center (like water), the fluid defies gravity and climbs up the rotating rod. A significant column of the fluid gathers and rotates with the rod, well above the liquid's surface.",Abhilash,Wan2.5,Done,Daniel Zhao,dz: good,,,,,,86
Supercool water,Physics,"Heat, Phase transitions",Carefully pour a bottle of supercooled water (approximately –1 degree Celsius) onto an ice cube placed in a dish.,https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"As the supercooled water comes into contact with the ice cube, it instantly begins to freeze, forming a column or stream of ice.",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: looks good,"{’hailuo2.3’:  [4,4, 4], ‘seedance1pro’:  [4, 4, 4], ‘sora2’:  [4, 4, 4 ], ‘veo3.1’:  [4], ‘wan2.5’:  [4, 4, 4], ‘kling2.5turbo’:  [3, 4, 4], ‘ray2’:  [3, 4,4]}","{’hailuo2.3’:  [4, 3, 4], ‘seedance1pro’: [2, 2, 3], ‘sora2’:  [4, 4, 4], ‘veo3.1’:  [4], ‘wan2.5’:  [3, 3, 4], ‘kling2.5turbo’:  [2, 4, 4], ‘ray2’:  [2, 3, 2]}","{’hailuo2.3’:  [4, 2, 4], ‘seedance1pro’:  [2, 2, 3], ‘sora2’:  [4, 4, 4], ‘veo3.1’:  [4], ‘wan2.5’:  [3, 3, 4], ‘kling2.5turbo’:  [3, 4, 4], ‘ray2’:  [3, 3, 2]}","{’hailuo2.3’:  [4, 2, 3], ‘seedance1pro’:  [1, 2, 4], ‘sora2’:  [4, 4, 4], ‘veo3.1’:  [3], ‘wan2.5’:  [3, 2, 1], ‘kling2.5turbo’:  [3, 3, 4], ‘ray2’:  [1, 3, 3]}","{’hailuo2.3’:  [3, 3, 3], ‘seedance1pro’: [1,2, 2] , ‘sora2’:  [4, 4, 4], ‘veo3.1’:  [3 ], ‘wan2.5’:  [3, 2, 3], ‘kling2.5turbo’:  [3, 4, 4], ‘ray2’:  [1, 3, 3]}",214
Dielectric Breakdown,Chemistry,"Plasma, Surface Tension","Two drops of water are placed on a superhydrophobic surface. A high-voltage plasma needle (like a ""plasma pencil"") is brought near the gap between the two drops.",https://pmc.ncbi.nlm.nih.gov/articles/PMC11139917/,"As the plasma needle approaches, a visible electric arc forms. The arc creates an ionized path, and the two separate water drops will instantly stretch out, bridge the gap, and merge into a single larger drop.",Abhilash,Wan2.5,Done,Daniel Zhao,dz: good,,,,,,85
Fire-resisting Ballon,Physics,"Heat Capacity, Thermal convection",Add a small amount of water to a balloon and then inflate it quickly to a moderate size. Bring the inflated balloon close to the flame of a lit candle.,https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"Unlike an empty balloon which bursts almost immediately, the balloon containing water resists popping for a longer time.",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: it might be hard to say how long the balloon would remain before popping,"{’hailuo2.3’: [4, 3, 4], ‘seedance1pro’: [3, 3, 3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [4, 4, 4], ‘kling2.5turbo’: [3, 3, 3], ‘ray2’: [3,4, 4]}","{’hailuo2.3’: [4, 2, 4], ‘seedance1pro’: [2, 2, 3], ‘sora2’: [4, 3, 4], ‘veo3.1’: [3], ‘wan2.5’: [4, 4, 3], ‘kling2.5turbo’: [3,2,  2], ‘ray2’: [3, 3, 3]}","{’hailuo2.3’: [4, 2, 4], ‘seedance1pro’: [2, 2, 3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [2], ‘wan2.5’: [4, 4, 3], ‘kling2.5turbo’: [3,2, 2], ‘ray2’: [3, 4, 3]}","{’hailuo2.3’: [4, 3, 4], ‘seedance1pro’: [3, 2, 4], ‘sora2’: [4, 2, 4], ‘veo3.1’: [2], ‘wan2.5’: [3, 4, 4], ‘kling2.5turbo’: [3, 2, 4], ‘ray2’: [1,1,  1]}","{’hailuo2.3’: [4, 3, 4], ‘seedance1pro’: [3,2, 4], ‘sora2’: [4, 2, 4], ‘veo3.1’: [3], ‘wan2.5’: [2, 4, 3], ‘kling2.5turbo’: [3, 3, 3], ‘ray2’: [2, 1, 1]}",213
Super-absorbant powder,Chemistry,"Chemical Reaction, Gravity","Put Superabsorbent polymer powder into one of the three opaque cups, pour water in them, and flip the three cups one after another.",https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM https://www.youtube.com/watch?v=t8pcKyc3XbM,"Only the cup containing the polymer retains the liquid, demonstrating the strong water-absorbing and gel-forming property of the superabsorbent polymer.",Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: fixed the prompt,"{’hailuo2.3’: [3, 4, 4], ‘seedance1pro’: [4, 4, 2], ‘sora2’: [3, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [3, 2, 3], ‘kling2.5turbo’: [3, 4, 4], ‘ray2’: [3, 4, 3]}","{’hailuo2.3’: [2, 3, 3], ‘seedance1pro’: [3, 4, 2], ‘sora2’: [2, 4, 2], ‘veo3.1’: [3], ‘wan2.5’: [2, 2, 2], ‘kling2.5turbo’: [3, 3, 4], ‘ray2’: [3, 3, 3]}","{’hailuo2.3’: [1, 3, 3], ‘seedance1pro’: [3, 4, 2], ‘sora2’: [2, 4, 3], ‘veo3.1’: [2], ‘wan2.5’: [2,1,  2], ‘kling2.5turbo’: [2, 2, 3], ‘ray2’: [3, 2, 2]}","{’hailuo2.3’: [2, 2, 2], ‘seedance1pro’: [2, 3, 1], ‘sora2’: [2, 3, 2], ‘veo3.1’: [3], ‘wan2.5’: [2, 2, 2], ‘kling2.5turbo’: [3, 2, 2], ‘ray2’: [3, 1, 1]}","{’hailuo2.3’: [2, 1, 2], ‘seedance1pro’: [3, 3, 2], ‘sora2’: [2, 2, 2], ‘veo3.1’: [3], ‘wan2.5’: [3, 1, 2], ‘kling2.5turbo’: [3, 2, 2], ‘ray2’: [3, 2, 2]}",212
Molecular Polarity,Chemistry,"Electrostatics, Surface Tension","A thin, steady stream of water flows from a tap. A balloon, freshly rubbed on someone's hair is brought near the stream (without touching it).",https://www.science-sparks.com/how-to-bend-water-with-static-electricity/,"The stream of water instantly bends, deflecting from its vertical path to move toward the charged balloon. The water's surface moves as one, demonstrating the attraction of its polar molecules to the static field.",Abhilash,Veo3.1,Done,Daniel Zhao,dz: good,,,,,,84
"Non-Newtonian Fluid ",Chemistry,"Standing waves, Viscosity","A shallow pool of cornstarch and water mixture is placed on top of a large audio speaker. A low-frequency (e.g., 40 Hz) sound is played.",https://www.youtube.com/watch?v=Ob2-GUuz2Ag,"The vibrations from the speaker cause the mixture to thicken and behave more like a solid, forming strange dancing shapes, waves, and ""monsters"" or ""tentacles"" that appear to climb out of the pool. This phenomenon occurs because the cornstarch and water mixture is a non-Newtonian fluid, specifically a shear-thickening fluid. When the fluid is hit by these vibrations, the cornstarch particles jam together, trapping the water and making the mixture rigid. When the force is removed, it flows like a liquid again.",Abhilash,Wan2.5,Done,Daniel Zhao,"dz: for some reason the prompt gives me actual corn in the mixture on wan2.5. maybe this is a one off thing? hahaha
abhi: I tested again on Wan and Sora it looks good",,,,,,83
Osmosis,Chemistry,Diffusion,"A ""U-tube"" is filled with water and divided at the bottom by a semipermeable membrane. A large amount of salt is added to the right side, and a blue dye is added to the left side.",https://kitchenpantryscientist.com/diffusion-and-osmosis-experiments,"The blue dye stays on the left, but the water level on the right side (salt) begins to rise immediately, pulling water from the left side against gravity. The blue-dyed water level on the left visibly drops.",Abhilash,Wan2.5,Done,Daniel Zhao,dz: good,,,,,,82
Supercooling,Chemistry,"Condensation, Nucleation","A perfectly still, clear jar of purified water is removed from a freezer (-5°C), but it remains liquid. A single shard of ice is dropped in.",https://www.youtube.com/watch?v=13unrtlvfrw&t=17s,"The instant the ice crystal hits, a wave of crystallization (freezing) visibly propagates from the top down. The entire bottle of liquid water turns to solid ice in under 5 seconds.",Abhilash,Sora-2,Done,Daniel Zhao,dz: good,,,,,,81
Ferrofluid,Chemistry,"Magnetics, Viscosity","A shallow, clear dish contains black ferrofluid forming a flat pool. A strong magnet approaches from directly above the center of the dish, moving downwards toward the bottom surface.",https://www.youtube.com/watch?v=kL8R8SfuXp8,"The flat liquid instantly spikes upwards, forming dozens of sharp, perfectly defined cones that trace the invisible magnetic field lines. The liquid's structure changes instantly from a flat pool to a bristling, solid-like sculpture.",Abhilash,Wan2.5,Done,Daniel Zhao,dz: good,,,,,,80
Starch-Iodine Reaction,Chemistry,"Diffusion, Stoichiometry","A petri dish completely filled with solid purple gelatin containing starch. A cylindrical well is carved directly into the center of the gelatin, creating a hole. Sulfuric acid and potassium iodide are poured directly into this well in the gelatin.",https://www.chemistryviews.org/details/education/10128441/Why_Does_Iodine_Turn_Starch_Blue,"2 distinct, colored rings rapidly expand from the center. A dark blue-black inner ring (iodine reacting with starch) moves outward, followed by a slower, faint brown outer ring (iodine). ",Abhilash,Sora-2,Done,Daniel Zhao,dz: good,,,,,,79
Spinning wheel tied to a rope,Physics,"Angular Momentum, Gyroscopic Precession",A bicycle wheel is spinning rapidly. The axle is held horizontally. One end of the wheel's axle is attached to a rope hanging from above. And the other end is released.,https://www.youtube.com/watch?v=8H98BgRzpOM,"Instead of the wheel's axle falling to a vertical, hanging position, it remains horizontal. The entire spinning wheel assembly begins to rotate slowly (precess) around the rope's attachment point, seemingly defying gravity.",Abhilash,Wan2.5,Done,Daniel Zhao,dz: good,,,,,,78
Tyndall effect: water-milk solution,Physics,"Emulsion, Tyndall Effect","In a dimly lit room, direct a narrow beam of light (from a laser pointer) through the side of a beaker containing the water–milk mixture. Place a ceramic mug behind the beaker, viewed from the side, to provide a contrasting background for observing the scattered light.",https://www.khanacademy.org/science/in-in-class10th-physics/in-in-the-human-eye-and-the-colourful-world/in-in-scattering-of-light-and-tyndall-effect/v/scattering-of-light-tyndall-effect,The beam of light becomes visible within the beaker due to scattering by the milk particles.,Lanxiang Hu,Sora-2,Done,"Yixin Huang, Yujie Zhao",yixin: good example yujie: LGTM,"{’hailuo2.3’: [4, 4, 4], ‘seedance1pro’: [3, 4, 3], ‘sora2’: [4, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [2, 4, 4] , ‘kling2.5turbo’: [3, 4, 4], ‘ray2’: [3, 4, 4]}","{’hailuo2.3’: [3, 4, 4], ‘seedance1pro’: [3, 4, 3], ’sora2’: [4, 4, 4], ‘veo3.1’: [4], ‘wan2.5’: [2, 4, 4], ‘kling2.5turbo’: [3, 4, 4], ‘ray2’: [2, 3, 3]}","{’hailuo2.3’: [4, 3, 4], ‘seedance1pro’: [2, 4, 3], ‘sora2’: [4, 4, 4], ‘veo3gen’: [3], , ‘wan2.5’: [2, 3, 4], ‘kling2.5turbo’: [3, 4, 4], ‘ray2’: [2, 3, 3]}","{’hailuo-2.3’: [3, 2, 3], ‘seedance-pro-1’: [3, 1, 2], ‘sora2’: [4, 4, 4], ‘veo3gen’: [3], ‘wan2.5’: [2, 2, 3], ‘kling2.5turbo’: [3, 3, 2], ‘ray2’: [2, 2, 2]}","{’hailuo2.3’: [4, 3,2 ], ‘seedance1pro’: [2, 2, 2], ‘sora2’: [4, 4, 4], ‘veo3.1’: [3], ‘wan2.5’: [3, 2, 4], ‘kling2.5turbo’: [4, 3, 3] , ‘ray2’: [3, 2, 2]}",211
Walking on spinning disk,Physics,Angular Momentum,"A flat circular disk spins, like a merry-go-round. A person stands at the center of this spinning disk. The person walks straight outward across the disk toward its edge.",https://www.youtube.com/watch?v=KcAzWPHVRH4,"When a person walks straight outward on a spinning disk, the disk slows down and the person follows a curved path due to the conservation of angular momentum and the Coriolis effect. ",Abhilash,Sora-2,Done,Daniel Zhao,dz: good,,,,,,77
Spinning Wheel,Physics,"Angular Momentum, Rotational Dynamics",A person sits upright on a rotatable office chair with feet off the ground. They hold a rapidly spinning bicycle wheel by its axle handles with the wheel's rotation axis vertical. The person then tilts the wheel to the left.,https://www.exploratorium.edu/snacks/bicycle-wheel-gyro,"When the person tilts the spinning bicycle wheel to the left, the person and the chair will start to rotate to the right (clockwise when viewed from above). The person, chair, and bicycle wheel form an isolated system. Since there are no external torques acting on the system about the vertical axis (the feet are off the ground and the chair has low friction), the total angular momentum must remain constant. ",Abhilash,Sora-2,Done,Daniel Zhao,dz: need to change expected phenomenon. its currently a copy of propmt (fixed),,,,,,76
https://fyfluiddynamics.com/tagged/Marangoni+effect,Physics,"Density, Diffusion, Surface Tension",Several drops of different colored food coloring are placed gently onto the surface of a shallow dish of milk. A cotton swab dipped in dish soap is then touched to the center of the milk.,https://fyfluiddynamics.com/2010/12/in-this-video-the-householdhacker-heads-to-the/,"The instant the soap touches the milk, the colors burst outward in psychedelic swirls. The soap breaks the surface tension and also reacts with the fats in the milk (saponification), causing chaotic, rapid mixing and Marangoni-driven flow.",Abhilash,Wan2.5,Done,Daniel Zhao,dz: good,,,,,,75
Acetone evaporation,Physics,"Heat, Phase transitions","A room-temperature ceramic plate sits on a dark surface. Using two separate droppers, a person simultaneously places one drop of acetone on the left side of the plate and one drop of pentane on the right side of the plate. Both drops are approximately the same size ",https://www.comsol.com/multiphysics/marangoni-effect,Liquid at the edges evaporates first,Abhilash,Wan2.5,Done,Daniel Zhao,dz: good,,,,,,74
Freezing water droplets,Physics,"Heat, Nucleation, Phase transitions","A person stands outside in an environment with a temperature of -20°C. They hold a spray bottle filled with room-temperature. The person aims the spray bottle upward and outward into the air, squeezing the trigger to create a fine mist of water droplets that arcs through the cold air.",https://www.ktalnews.com/lovinglivinglocalnbc6/exploring-extreme-cold-the-science-behind-hot-water-freezing-mid-air/,"Rapid Cooling is observed, water freezes instantly",Abhilash,Wan2.5,Done,Daniel Zhao,dz: good,,,,,,73
Melting Butter,Physics,"Heat, Phase transitions",A slice of bread has just been removed from a toaster and placed on a white plate. The bread it is visibly steaming. A pat of cold butter from the refrigerator is placed in the center of the hot toast surface.,https://www.liuacademy.com/post/capillary-action-in-sponges-bread,Capillary effect as the butter melts,Abhilash,Wan2.5,Done,Daniel Zhao,dz: good,,,,,,72
Dry Ice in Water,Physics,"Heat, Phase transitions",A clear glass bowl or beaker filled with room-temperature tap water sits on a table. A person holding a spoon with several small chunks of dry ice and drops them into the water all at once.,https://www.experimentarchive.com/experiments/dry-ice-in-water,"When a spoonful of dry ice is dropped into room temperature water, it undergoes rapid sublimation, creating a theatrical, bubbling cloud of fog. It does not melt, as normal water ice does, but turns directly from a solid into a gas. ",Abhilash,Wan2.5,Done,Daniel Zhao,dz: good,,,,,,71
Connected Cups Spinning with Balls,Physics,"Centrifugal Force, Centripetal Force, Inertia","Two plastic cups are joined mouth-to-mouth, with a wooden stick fixed along the outside connecting them. One small ball is placed inside each cup, and the stick is spun rapidly around its center.",https://www.youtube.com/watch?v=20kWPQ1dmIs,"As the system spins, both balls move outward and press against the sides of their cups. They remain in that outward position while the rotation continues.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",,"{'hailuo2.3': [1, 4, 4], 'seedance1pro': [4, 2, 2], 'sora2': [4, 4, 2], 'veo3.1': [4, 2], 'wan2.5': [4, 1, 3], 'kling2.5turbo': [4, 4, 2], 'ray2': [3, 1, 1]}","{'hailuo2.3': [2, 2, 3], 'seedance1pro': [4, 1, 3], 'sora2': [4, 3, 2], 'veo3.1': [3, 1], 'wan2.5': [4, 1, 2], 'kling2.5turbo': [4, 2, 2], 'ray2': [4, 2, 1]}","{'hailuo2.3': [4, 3, 2], 'seedance1pro': [4, 1, 3], 'sora2': [3, 4, 3], 'veo3.1': [4, 2], 'wan2.5': [4, 2, 3], 'kling2.5turbo': [4, 4, 3], 'ray2': [4, 2, 3]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 1, 1], 'sora2': [1, 1, 1], 'veo3.1': [1, 2], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [1, 1, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 1, 4], 'seedance1pro': [1, 1, 1], 'sora2': [1, 2, 1], 'veo3.1': [1, 1], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [1, 2, 1], 'ray2': [1, 1, 1]}",143
Electrolysis of Water with Pencil,Chemistry,"Electrolysis, Redox Reaction","Two pencil leads connected to a 9 V battery are immersed in saltwater in a beaker. ",https://www.youtube.com/watch?v=ntjq8W9PL3E,"Fine bubbles appear at both pencil leads. Hydrogen gas forms at the negative electrode (cathode), while oxygen or chlorine gas forms at the positive electrode (anode).",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",,"{'hailuo2.3': [4, 3, 4], 'seedance1pro': [4, 3, 3], 'sora2': [4, 4, 4], 'veo3.1': [3, 4], 'wan2.5': [4, 4, 4], 'kling2.5turbo': [4, 4, 4], 'ray2': [2, 4, 2]}","{'hailuo2.3': [4, 2, 3], 'seedance1pro': [2, 1, 2], 'sora2': [4, 4, 3], 'veo3.1': [4, 3], 'wan2.5': [2, 3, 3], 'kling2.5turbo': [4, 3, 2], 'ray2': [2, 2, 1]}","{'hailuo2.3': [4, 4, 4], 'seedance1pro': [4, 3, 3], 'sora2': [4, 4, 4], 'veo3.1': [4, 3], 'wan2.5': [4, 4, 4], 'kling2.5turbo': [4, 4, 4], 'ray2': [2, 4, 3]}","{'hailuo2.3': [4, 1, 4], 'seedance1pro': [1, 1, 1], 'sora2': [3, 4, 3], 'veo3.1': [2, 3], 'wan2.5': [1, 1, 4], 'kling2.5turbo': [2, 2, 1], 'ray2': [2, 2, 1]}","{'hailuo2.3': [4, 2, 4], 'seedance1pro': [2, 2, 2], 'sora2': [3, 4, 2], 'veo3.1': [4, 3], 'wan2.5': [2, 3, 3], 'kling2.5turbo': [2, 2, 3], 'ray2': [3, 3, 2]}",142
Milk and vinegar plastic formation,Chemistry,"Acid-Base Reaction, Precipitation reaction, Protein Denaturation","A cup of hot milk is poured into a container, and 3–4 tablespoons of white vinegar are added. The mixture is stirred continuously with a spoon.",https://www.youtube.com/watch?v=J2sqUbh_qnU,"White curds begin to form and clump together while the remaining liquid becomes clearer and yellowish. ",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai","Abhilash: I don’t thinks curds appear in 5 secs (haoyang: From the reference video, it takes about 5 seconds for the curds to appear,  around 4:15–4:20 in the clip.)","{'hailuo2.3': [4, 4, 3], 'seedance1pro': [4, 4, 3], 'sora2': [4, 4, 4], 'veo3.1': [4, 4], 'wan2.5': [4, 2, 1], 'kling2.5turbo': [2, 4, 4], 'ray2': [4, 1, 2]}","{'hailuo2.3': [4, 4, 2], 'seedance1pro': [4, 3, 2], 'sora2': [3, 3, 4], 'veo3.1': [4, 4], 'wan2.5': [4, 1, 1], 'kling2.5turbo': [2, 3, 4], 'ray2': [3, 1, 2]}","{'hailuo2.3': [4, 3, 3], 'seedance1pro': [4, 4, 4], 'sora2': [2, 2, 4], 'veo3.1': [4, 3], 'wan2.5': [4, 3, 1], 'kling2.5turbo': [4, 4, 4], 'ray2': [4, 2, 2]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 1, 1], 'sora2': [1, 1, 1], 'veo3.1': [3, 4], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [1, 1, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 1, 2], 'seedance1pro': [3, 3, 3], 'sora2': [4, 3, 4], 'veo3.1': [4, 4], 'wan2.5': [2, 1, 3], 'kling2.5turbo': [1, 2, 2], 'ray2': [1, 3, 2]}",141
Cabbage Indicator with Vinegar and Baking Soda,Chemistry,"Acid-Base Reaction, Indicator color change",Two cups are prepared: one with vinegar and one with baking soda. Red-cabbage indicator solution is added to each to observe the color change.,https://www.youtube.com/watch?v=hPcRylO4lQM,"The indicator turns pink in the vinegar cup (acidic) and blue in the baking soda cup (basic). Over time, the baking soda may also decolorize the indicator due to oxidation.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",,"{'hailuo2.3': [2, 4, 1], 'seedance1pro': [2, 2, 1], 'sora2': [4, 4, 4], 'veo3.1': [4, 2], 'wan2.5': [2, 4, 2], 'kling2.5turbo': [4, 4, 3], 'ray2': [2, 2, 3]}","{'hailuo2.3': [2, 2, 1], 'seedance1pro': [2, 1, 1], 'sora2': [3, 2, 4], 'veo3.1': [3, 2], 'wan2.5': [2, 4, 2], 'kling2.5turbo': [2, 2, 2], 'ray2': [2, 1, 2]}","{'hailuo2.3': [4, 4, 1], 'seedance1pro': [4, 2, 2], 'sora2': [4, 2, 4], 'veo3.1': [4, 2], 'wan2.5': [2, 4, 2], 'kling2.5turbo': [4, 2, 3], 'ray2': [3, 2, 3]}","{'hailuo2.3': [3, 2, 4], 'seedance1pro': [2, 1, 1], 'sora2': [3, 4, 4], 'veo3.1': [4, 4], 'wan2.5': [1, 2, 2], 'kling2.5turbo': [2, 3, 4], 'ray2': [1, 2, 2]}","{'hailuo2.3': [4, 2, 3], 'seedance1pro': [3, 2, 3], 'sora2': [4, 4, 4], 'veo3.1': [4, 4], 'wan2.5': [4, 2, 4], 'kling2.5turbo': [4, 3, 3], 'ray2': [1, 2, 2]}",140
Lemon Battery Lighting an LED,Chemistry,"Galvanic Cell, Redox Reaction","Four lemons are arranged to form a series circuit. A zinc-coated nail and a copper wire are inserted into opposite sides of each lemon. Using alligator clips, the copper wire of one lemon is connected to the zinc nail of the next, allowing current to flow through all four. The first lemon’s copper wire is connected to the positive (long) leg of a small LED, and the last lemon’s zinc nail is connected to the negative (short) leg.",https://www.youtube.com/watch?v=WNx-bwlTATI,"When all four lemons are connected correctly, electrons flow from the zinc nails to the copper wires through the LED. The combined voltage lights up the LED faintly.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",,"{'hailuo2.3': [4, 4, 2], 'seedance1pro': [2, 2, 2], 'sora2': [3, 4, 4], 'veo3.1': [1, 2], 'wan2.5': [2, 4, 4], 'kling2.5turbo': [4, 3, 4], 'ray2': [2, 2, 4]}","{'hailuo2.3': [2, 1, 2], 'seedance1pro': [2, 2, 2], 'sora2': [2, 4, 1], 'veo3.1': [2, 2], 'wan2.5': [2, 3, 2], 'kling2.5turbo': [2, 1, 2], 'ray2': [4, 1, 2]}","{'hailuo2.3': [4, 4, 2], 'seedance1pro': [4, 4, 4], 'sora2': [4, 4, 4], 'veo3.1': [2, 2], 'wan2.5': [2, 4, 4], 'kling2.5turbo': [4, 4, 4], 'ray2': [4, 3, 3]}","{'hailuo2.3': [4, 1, 4], 'seedance1pro': [4, 4, 3], 'sora2': [4, 4, 3], 'veo3.1': [4, 4], 'wan2.5': [4, 4, 3], 'kling2.5turbo': [4, 2, 4], 'ray2': [1, 2, 3]}","{'hailuo2.3': [4, 2, 2], 'seedance1pro': [3, 2, 2], 'sora2': [4, 3, 2], 'veo3.1': [4, 2], 'wan2.5': [3, 3, 2], 'kling2.5turbo': [3, 2, 3], 'ray2': [1, 2, 3]}",139
P₄ + O₂,Chemistry,"Combustion / flammability, Redox Reaction, Thermal convection",Pure oxygen gas is introduced into the small piece of white phosphorus in a flask.,https://youtu.be/mjkuSm__G7s?si=2DVvcKD6kwcr3s_J,The phosphorus ignites and produces bright white fumes.,Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang",mk: good,,,,,,116
Na + Water,Chemistry,"Buoyancy, Combustion / flammability, Density, Redox Reaction",A small piece of sodium metal is dropped into a beaker of water.,https://www.youtube.com/watch?v=dmcfsEEogxs,"The metal floats, reacts vigorously, and produces a yellow flame.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang",mk: good,,,,,,115
Lava Lamp,Physics,"Buoyancy, Density, Emulsion",A small piece of effervescent tablet is dropped into a tall clear bottle with a layer of red-colored water below a layer of yellow oil.,https://www.youtube.com/watch?v=tRi0G5jnXYU,"Colored blobs rise as bubbles carry them, then sink when bubbles pop.",Forrest Dai,Sora-2,Done,"Abhilash, Murray Kang","Forrest: The generated video was rejected by wan 2.5 for safety reasons, so Sora is used for sanity check.

Abhilash: Was able generate video with Wan",,,,,,114
Aluminum-Iodine Reaction,Chemistry,"Combustion / flammability, Redox Reaction, Thermal convection",A few drops of water are added to a small pile of powdered aluminum and iodine crystals in a shallow dish.,https://commons.wikimedia.org/wiki/File:06._Директна_синтеза_на_алуминиум_јодид.webm,"No reactions before; After water is added, the mixture spontaneously ignites with a violet-blue flash and smoke.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang",mk: good,,,,,,113
Electrolysis of Copper Sulfate,Chemistry,"Electrolysis, Redox Reaction",Two copper wires connected to a battery are placed in a blue copper sulfate solution.,youtube.com/watch?time_continue=263&v=pq5Ysk9YZno&embeds_referring_euri=https%3A%2F%2Fchatgpt.com%2F&source_ve_path=Mjg2NjY,Bubbles appear on one electrode while metallic copper slowly deposits on the other. The solution near the cathode becomes lighter in color as Cu²⁺ ions are reduced and plated.,Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",,"{'hailuo2.3': [2, 4, 4], 'seedance1pro': [2, 2, 2], 'sora2': [4, 4, 4], 'veo3.1': [3, 2], 'wan2.5': [4, 4, 3], 'kling2.5turbo': [4, 4, 4], 'ray2': [1, 2, 2]}","{'hailuo2.3': [2, 2, 2], 'seedance1pro': [2, 1, 2], 'sora2': [2, 2, 2], 'veo3.1': [2, 2], 'wan2.5': [4, 1, 2], 'kling2.5turbo': [3, 3, 3], 'ray2': [1, 2, 2]}","{'hailuo2.3': [3, 4, 4], 'seedance1pro': [3, 3, 3], 'sora2': [4, 4, 3], 'veo3.1': [4, 2], 'wan2.5': [4, 2, 3], 'kling2.5turbo': [4, 4, 4], 'ray2': [1, 2, 3]}","{'hailuo2.3': [2, 1, 1], 'seedance1pro': [1, 1, 1], 'sora2': [2, 2, 2], 'veo3.1': [2, 2], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [1, 1, 2], 'ray2': [1, 1, 1]}","{'hailuo2.3': [3, 2, 3], 'seedance1pro': [2, 2, 2], 'sora2': [4, 4, 3], 'veo3.1': [3, 2], 'wan2.5': [3, 2, 2], 'kling2.5turbo': [3, 3, 2], 'ray2': [1, 2, 2]}",138
KMnO₄ + H₂SO₄ in Water,Chemistry,"Combustion / flammability, Density, Precipitation reaction",A few crystals of potassium permanganate and some concentrated sulfuric acid are carefully added into a glass of water.,https://www.youtube.com/shorts/XfYJiKMfve8,"The mixture sinks to the bottom, where bright flashes of light appear. The solution rapidly heats, and the color turns dark (as Mn⁷⁺ is reduced to brown/black MnO₂ solids).",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang","Abhilash: Explained phenomenon can be improved. Its an exothermic reaction and the solution color changes.
Forrest: added ✅

mk: good",,,,,,112
Warm Water Bottle in Ice,Physics,"Condensation, Thermal convection","A capped clear plastic bottle with warm water already sits inside a bowl filled with ice water, a person pours extra ice over and around the bottle until it’s mostly covered.",https://www.youtube.com/watch?v=uuzqftLCeks,"Within seconds, the plastic bottle dents inward as it cools in the ice water, and droplets of condensed water appear on the inner walls.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang","mk: maybe the expected phenomenon mentioned too much about the underlying reason? Not sure if VLMs can handle this.

Forrest: done ✅",,,,,,111
Covered Burning Candle in Water,Physics,"Combustion / flammability, Hydrostatic, Thermal convection","A burning candle stands upright on a dish containing a thin layer of water. A clear glass jar is then inverted over the candle, covering it and part of the water surface.",https://www.youtube.com/watch?v=pyy_lup0F4c,"Flame goes out, and water level rises inside the glass as oxygen is consumed and air cools.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang",mk: good,,,,,,110
Blowing Between Balloons,Physics,"Bernoulli Effect, Coanda Effect, Statistical equilibrium",Two identical balloons hang about 10 cm apart from strings. A person holds a straw and gently blows air between them.,https://www.youtube.com/watch?v=3fWSTXDQ8eE,"When air is blown between the balloons, they move toward each other and sometimes collide. The fast-moving air between them creates a lower pressure region (Bernoulli effect), so the higher surrounding air pressure pushes the balloons together.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang","Abhilash: Expected phenomenon mention more bernoulli effect 
Forrest: added ✅

mk: good",,,,,,109
Spoon Under a Faucet,Physics,"Bernoulli Effect, Coanda Effect, Statistical equilibrium","A person holds a metal spoon by the handle, vertically near a faucet, the convex back of the spoon approaching a thin vertical water stream from the faucet.",https://www.youtube.com/watch?v=X4l2Irh3UFg,"The spoon is pulled into water as the stream bends along the spoon, then returns straight when the spoon is taken away.",Forrest Dai,Wan2.5,Done,"Abhilash, Murray Kang","Abhilash: The effect is pretty obvious, can we make more complex?

mk: Little bit simple but I am also okay to keep it.

Forrest: I think the water flow absorbing spoon is not that intuitive. Will mark as done for now. but we can always combine this with the “comb near faucet” example to demonstrate two different forces if someone is questioning",,,,,,108
Place a Ball on a Turntable,Physics,"Centrifugal Force, Friction, Inertia","From a top-down view, a small ball is placed near the center of a turntable, then start spinning the turntable. ",https://www.youtube.com/watch?v=3oM7hX3UUEU&t=10s,"At first, friction keeps the ball doing circular motion along with the turntable. After a long time, the ball begins to slowly slide outward toward the edge.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",,"{'hailuo2.3': [4, 4, 4], 'seedance1pro': [4, 1, 4], 'sora2': [4, 4, 4], 'veo3.1': [4, 4], 'wan2.5': [4, 4, 4], 'kling2.5turbo': [4, 4, 4], 'ray2': [4, 1, 3]}","{'hailuo2.3': [3, 2, 3], 'seedance1pro': [3, 2, 3], 'sora2': [2, 2, 2], 'veo3.1': [3, 2], 'wan2.5': [2, 2, 2], 'kling2.5turbo': [4, 3, 2], 'ray2': [2, 2, 3]}","{'hailuo2.3': [2, 4, 3], 'seedance1pro': [4, 2, 3], 'sora2': [3, 3, 3], 'veo3.1': [4, 2], 'wan2.5': [4, 4, 3], 'kling2.5turbo': [4, 2, 2], 'ray2': [4, 2, 3]}","{'hailuo2.3': [2, 2, 3], 'seedance1pro': [3, 2, 3], 'sora2': [2, 2, 3], 'veo3.1': [3, 2], 'wan2.5': [1, 1, 2], 'kling2.5turbo': [1, 1, 2], 'ray2': [2, 3, 1]}","{'hailuo2.3': [4, 4, 4], 'seedance1pro': [4, 4, 4], 'sora2': [4, 4, 2], 'veo3.1': [3, 4], 'wan2.5': [4, 4, 3], 'kling2.5turbo': [2, 2, 3], 'ray2': [4, 4, 1]}",128
Ball Swinging,Physics,"Centripetal Force, Gravity, Inertia, Projectile Motion","A small ball is attached to a light string and is moving in a vertical circle about a fixed pivot. Near the top of the circle, the string suddenly breaks so that the ball is no longer constrained to follow the circular path.",youtube.com/watch?time_continue=7&v=oFwgBXWoWck&embeds_referring_euri=https%3A%2F%2Fchatgpt.com%2F&source_ve_path=Mjg2NjY,"When the ball is released at the top of its circular path, it flies straight forward tangentially to the circle rather than falling immediately downward. ",Haoyang Yu,Wan2.5,Makeup,"Abhilash, Forrest Dai","Forrest: “released” is ambiguous, all models (including text models) interpret this as hands off and let the ball move around the pivot. But what we want is to break the string and let the ball leave its circular path.

Forrest: fixed","{'hailuo2.3': [2, 4, 1], 'seedance1pro': [1, 3, 3], 'sora2': [4, 4, 4], 'veo3.1': [3, 2], 'wan2.5': [4, 4, 4], 'kling2.5turbo': [4, 3, 4], 'ray2': [1, 3, 3]}","{'hailuo2.3': [2, 1, 1], 'seedance1pro': [1, 1, 2], 'sora2': [4, 4, 4], 'veo3.1': [3, 2], 'wan2.5': [3, 3, 3], 'kling2.5turbo': [2, 2, 3], 'ray2': [3, 3, 3]}","{'hailuo2.3': [3, 3, 2], 'seedance1pro': [4, 3, 3], 'sora2': [4, 4, 4], 'veo3.1': [4, 3], 'wan2.5': [4, 4, 4], 'kling2.5turbo': [4, 4, 4], 'ray2': [3, 4, 3]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 1, 1], 'sora2': [1, 1, 1], 'veo3.1': [1, 1], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [1, 1, 1], 'ray2': [1, 1, 1]}","{'hailuo2.3': [1, 1, 1], 'seedance1pro': [1, 1, 1], 'sora2': [1, 1, 1], 'veo3.1': [1, 1], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [1, 1, 1], 'ray2': [1, 1, 1]}",132
Magnetic Collision Between Two Identical Carts,Physics,"Elastic Collision, Magnetics, Momentum Conservation","Two identical carts sit on a frictionless track. Each cart carries a magnet, and they have magnets that oppose each other. The right cart is pushed toward it with an initial speed.",https://www.youtube.com/watch?v=jRliH0jVilM&t=90s,"When the moving cart approaches, magnetic repulsion slows it down until it stops completely. Its kinetic energy and momentum are transferred to the other cart, which then moves away in the opposite direction with nearly the same speed.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai","Forrest: “opposite poles” in prompt should be “same poles”; or use what the prof said in video, “they have magnets that oppose each other”（ ✅ fixed）","{'hailuo2.3': [4, 1, 1], 'seedance1pro': [4, 3, 1], 'sora2': [4, 3, 3], 'veo3.1': [1, 2], 'wan2.5': [1, 2, 3], 'kling2.5turbo': [3, 4, 4], 'ray2': [3, 3, 1]}","{'hailuo2.3': [3, 1, 1], 'seedance1pro': [2, 2, 2], 'sora2': [3, 2, 2], 'veo3.1': [1, 3], 'wan2.5': [2, 2, 3], 'kling2.5turbo': [2, 2, 3], 'ray2': [2, 2, 1]}","{'hailuo2.3': [3, 2, 1], 'seedance1pro': [3, 3, 3], 'sora2': [3, 3, 2], 'veo3.1': [2, 3], 'wan2.5': [3, 2, 3], 'kling2.5turbo': [2, 3, 3], 'ray2': [3, 3, 2]}","{'hailuo2.3': [3, 1, 1], 'seedance1pro': [1, 1, 1], 'sora2': [1, 2, 1], 'veo3.1': [1, 2], 'wan2.5': [1, 1, 1], 'kling2.5turbo': [1, 1, 3], 'ray2': [1, 1, 1]}","{'hailuo2.3': [4, 2, 2], 'seedance1pro': [4, 2, 2], 'sora2': [4, 4, 2], 'veo3.1': [2, 2], 'wan2.5': [1, 2, 1], 'kling2.5turbo': [4, 2, 4], 'ray2': [1, 1, 1]}",133
Projectile from a Moving Cart,Physics,"Inertia, Projectile Motion, Relative Velocity","A cart moves forward at a constant speed and launches a ball straight upward from its top, shown in a side view.",https://www.youtube.com/watch?v=VUGRV7YCoLs&t=188s,"The ball travels upward and then downward in a parabolic path, but lands back on the moving cart because both the ball and the cart have the same horizontal velocity.",Haoyang Yu,Wan2.5,Done,"Abhilash, Forrest Dai",Abhilash: The generated video needs show the side-view of the cart to see the expected phenomenon. Rewrite the prompt. (fixed),"{'hailuo2.3': [2, 2, 3], 'seedance1pro': [2, 4, 2], 'sora2': [1, 4, 4], 'veo3.1': [1, 1], 'wan2.5': [1, 3, 4], 'kling2.5turbo': [4, 4, 4], 'ray2': [1, 3, 1]}","{'hailuo2.3': [3, 2, 3], 'seedance1pro': [2, 3, 2], 'sora2': [2, 4, 4], 'veo3.1': [1, 2], 'wan2.5': [1, 2, 2], 'kling2.5turbo': [4, 4, 3], 'ray2': [1, 2, 1]}","{'hailuo2.3': [4, 4, 3], 'seedance1pro': [2, 4, 3], 'sora2': [2, 2, 4], 'veo3.1': [3, 3], 'wan2.5': [2, 3, 3], 'kling2.5turbo': [4, 4, 3], 'ray2': [1, 3, 2]}","{'hailuo2.3': [1, 1, 4], 'seedance1pro': [1, 1, 1], 'sora2': [1, 2, 4], 'veo3.1': [1, 1], 'wan2.5': [1, 4, 2], 'kling2.5turbo': [4, 4, 4], 'ray2': [1, 1, 1]}","{'hailuo2.3': [2, 2, 4], 'seedance1pro': [1, 3, 1], 'sora2': [2, 3, 4], 'veo3.1': [1, 1], 'wan2.5': [1, 4, 2], 'kling2.5turbo': [4, 4, 4], 'ray2': [1, 1, 1]}",137
Spinning Skater,Physics,"Angular Momentum, Diffusion",A figure skater spins rapidly in place on ice without translating across the surface. She starts with arms fully extended outward holding sparklers that emit smoke trails. She then pulls her arms inward to her chest.,https://www.youtube.com/watch?v=XWjxYdhmMQ4,"When the figure skater pulls her arms inward, she will spin faster, and the smoke trails from her sparklers will appear to tighten and spiral more densely around her. ",Abhilash,Sora-2,Done,Daniel Zhao,dz: good,,,,,,70
Honey & Temperature,Physics,"Fluid Dynamics, Heat, Viscosity","Two identical spoons are held horizontally at the same height above a cold white plate. One spoon contains honey that has been heated to approximately 40°C (warm but not hot), while the other spoon contains honey taken directly from the refrigerator at 4°C. Both spoons are tilted simultaneously to pour the honey onto the plate side by side.",https://www.youtube.com/watch?v=hH2dpMO-frQ,"cold honey flows much slower, while warm honey flows more easily. This difference is because temperature affects molecular motion: cold honey has less molecular energy, causing the molecules to move closer together and resist flow more (higher viscosity), whereas heating honey increases molecular energy, allowing molecules to move further apart and flow more freely (lower viscosity). ",Abhilash,Wan2.5,Done,Daniel Zhao,dz: good,,,,,,69
Raw Egg Spinning,Physics,"Angular Momentum, Viscosity","A raw egg lies on a smooth flat table surface. A hand spins the egg rapidly, causing it to rotate at high speed. After the egg has been spinning for 2-3 seconds, a finger reaches in and briefly presses down on the top of the egg to stop its rotation completely. The finger is held there for about one second, then quickly lifted away.",https://youtu.be/_G5zNZf_6g4?si=uL2XBfTJ6lxuqkg1&t=121,"If you spin a raw egg, stop it briefly with your finger, and then release it, it will start spinning again. This happens because the liquid inside the raw egg continues to move even when the shell is stopped.",Abhilash,Veo3.1,Done,Daniel Zhao,dz: good,,,,,,68
Color Diffusion,Chemistry,"Diffusion, Gravity","A clear glass beaker filled with still, cold water sits on a white surface. A dropper containing blue food coloring is held with its tip positioned just above the water surface. A single drop of blue food coloring is slowly released from the dropper into the water.",https://www.sciencing.com/happens-food-coloring-cold-water-8253853/,"The food coloring has a slightly higher specific gravity, or relative density, than water, so before it has time to diffuse, it tends to sink in the water.

Read More: https://www.sciencing.com/happens-food-coloring-cold-water-8253853/",Abhilash,Wan2.5,Done,Daniel Zhao,dz: good,,,,,,67
Ping Pong Over a Dryer,Physics,"Bernoulli Effect, Centripetal Force, Coanda Effect, Gravity","A hair dryer is blowing straight up, and a ping-pong ball is released above the nozzle.",https://www.youtube.com/watch?v=5zD7Le2mGFg,"The ping-pong ball hovers steadily in the upward air stream, staying aligned with the center of the airflow. When slightly displaced, it returns to the stream instead of falling, stabilized by air pressure differences around the ball.",Forrest Dai,Sora-2,Done,"Abhilash, Murray Kang","mk: maybe the expected phenomenon can be more detailed like mentioning it hovers aligned with same direction as hair dryer?
Forrest: added ✅",,,,,,107