Prompt stringlengths 11 171 | Explanation stringlengths 24 475 | Category stringclasses 6 values | Subcategory stringclasses 27 values | prompt_id int64 1 1k | bucket stringclasses 6 values |
|---|---|---|---|---|---|
A candle in space | The model should generate an image showing a candle that is not burning | Chemistry | Combustion | 901 | CHEMISTRY |
Within a sealed glass container of carbon dioxide, a burning candle has been left to stand for a while | The model should generate an image showing a candle in a sealed glass jar and its flame has been extinguished | Chemistry | Combustion | 902 | CHEMISTRY |
A sealed glass jar filled with carbon dioxide contains a burning magnesium rod | The model should generate an image showing a vigorously burning magnesium rod inside a sealed glass jar. The image should prominently feature a dazzling, intense white light emanating from the burning magnesium | Chemistry | Combustion | 903 | CHEMISTRY |
A sealed glass jar filled with nitrogen contains a burning magnesium rod | The model should generate an image showing a burning magnesium rod inside a sealed glass jar, with intense light | Chemistry | Combustion | 904 | CHEMISTRY |
A sealed glass jar filled with oxygen contains a burning iron wire | The model should generate an image showing a thin iron wire inside a sealed glass jar that is burning intensely and producing sparks in a pure oxygen atmosphere, illustrating that oxygen greatly supports combustion | Chemistry | Combustion | 905 | CHEMISTRY |
A small piece of wood burning in a sealed jar with pure oxygen | The model should generate an image of a piece of wood that is burning very intensely inside of a jar filled with pure oxygen | Chemistry | Combustion | 906 | CHEMISTRY |
A lit match inside a sealed jar with only water vapor | The model should generate an image showing a match that has been extinguished inside of a jar full of only water vapor, with the match looking dark or burnt, and illustrating the lack of oxygen to support combustion | Chemistry | Combustion | 907 | CHEMISTRY |
A piece of phosphorus burning inside a sealed jar with fluorine gas | The model should generate an image showing a piece of phosphorus burning rapidly in a sealed jar filled with fluorine gas, with very strong and quick combustion, as fluorine will support even more vigorous combustion than oxygen does | Chemistry | Combustion | 908 | CHEMISTRY |
A sodium metal burning inside of a jar of chlorine gas | The model should generate an image of sodium metal burning in a sealed jar of chlorine gas, with a bright flame and white smoke or particulates | Chemistry | Combustion | 909 | CHEMISTRY |
A small candle flame inside of a sealed jar where the air has been replaced with helium | The model should generate an image of a candle flame that is extinguishing inside of a sealed jar | Chemistry | Combustion | 910 | CHEMISTRY |
The sodium is burning, highlighting the color | The model should generate an image showing a flame that is distinctly yellow or orange, representing the characteristic flame color when sodium is burned | Chemistry | Combustion | 911 | CHEMISTRY |
The copper is burning, highlighting the color | The model should generate an image showing a flame that is distinctly green or blue-green, representing the characteristic flame color when copper is burned | Chemistry | Combustion | 912 | CHEMISTRY |
The potassium is burning, highlighting the color | The model should generate an image showing a flame that is distinctly lilac or violet, representing the characteristic flame color when potassium is burned | Chemistry | Combustion | 913 | CHEMISTRY |
The lithium is burning, highlighting the color | The model should generate an image showing a flame that is distinctly crimson or deep red, representing the characteristic flame color when lithium is burned | Chemistry | Combustion | 914 | CHEMISTRY |
The calcium is burning, highlighting the color | The model should generate an image showing a flame that is distinctly orange-red, representing the characteristic flame color when calcium is burned | Chemistry | Combustion | 915 | CHEMISTRY |
The barium is burning, highlighting the color | The model should generate an image showing a flame that is distinctly pale green or yellow-green, representing the characteristic flame color when barium is burned | Chemistry | Combustion | 916 | CHEMISTRY |
The strontium is burning, highlighting the color | The model should generate an image showing a flame that is distinctly crimson or scarlet, representing the characteristic flame color when strontium is burned | Chemistry | Combustion | 917 | CHEMISTRY |
The cesium is burning, highlighting the color | The model should generate an image showing a flame that is distinctly blue or violet, representing the characteristic flame color when cesium is burned | Chemistry | Combustion | 918 | CHEMISTRY |
The magnesium is burning, highlighting the color | The model should generate an image showing a very bright white flame, representing the characteristic flame color when magnesium is burned | Chemistry | Combustion | 919 | CHEMISTRY |
The aluminum is burning, highlighting the color | The model should generate an image showing a flame that is mostly colorless or a very bright white color, with the lack of strong color representing the typical flame color when aluminum is burned | Chemistry | Combustion | 920 | CHEMISTRY |
The zinc is burning, highlighting the color | The model should generate an image showing a flame that is mainly colorless or blueish-white to pale green, representing the characteristic flame color when zinc is burned | Chemistry | Combustion | 921 | CHEMISTRY |
The lead is burning, highlighting the color | The model should generate an image showing a flame that appears a pale blue or white color, representing the characteristic flame color when lead is burned, which may be faint | Chemistry | Combustion | 922 | CHEMISTRY |
The antimony is burning, highlighting the color | The model should generate an image showing a flame that is pale blue or white, which is the typical color that antimony produces when burned | Chemistry | Combustion | 923 | CHEMISTRY |
The cadmium is burning, highlighting the color | The model should generate an image showing a flame that is red or orange, representing the characteristic flame color when cadmium is burned | Chemistry | Combustion | 924 | CHEMISTRY |
The arsenic is burning, highlighting the color | The model should generate an image showing a flame that is pale blue or whitish, representing the characteristic flame color when arsenic is burned, which is typically very faint | Chemistry | Combustion | 925 | CHEMISTRY |
The boron is burning, highlighting the color | The model should generate an image showing a flame that is bright green, representing the characteristic flame color when boron is burned | Chemistry | Combustion | 926 | CHEMISTRY |
an iron block that is not rusted | The model should generate an image showing an iron block with a clean, metallic, and shiny surface, with no visible signs of rust or corrosion | Chemistry | Metal Corrosion | 927 | CHEMISTRY |
an iron block that is rusted | The model should generate an image showing an iron block with a surface covered in visible rust, having a reddish-brown color and a rough, pitted texture indicating corrosion | Chemistry | Metal Corrosion | 928 | CHEMISTRY |
A copper pipe that is rusted | The model should generate an image of a copper pipe with a visible layer of green patina, showing the characteristic corrosion of copper | Chemistry | Metal Corrosion | 929 | CHEMISTRY |
Copper wire exposed to air for a long time | The model should generate an image showing a copper wire with a duller, slightly greenish or brownish surface | Chemistry | Metal Corrosion | 930 | CHEMISTRY |
A piece of weathered aluminum | The model should generate an image showing a piece of aluminum that appears weathered, with a dull grey surface due to the formation of aluminum oxide, rather than rust | Chemistry | Metal Corrosion | 931 | CHEMISTRY |
A lead roof with signs of oxidation | The model should generate an image of a lead roof with a dull grey or white surface due to the formation of lead oxide, not rust or red, due to oxidation | Chemistry | Metal Corrosion | 932 | CHEMISTRY |
A piece of galvanized steel exposed to moisture, with early signs of corrosion | The model should generate an image showing a piece of galvanized steel with some white corrosion products forming in spots where the zinc coating is compromised, showing a different type of oxidation to iron | Chemistry | Metal Corrosion | 933 | CHEMISTRY |
A piece of silver cutlery that has some tarnish | The model should generate an image of a piece of silver cutlery, with a dark grey or black tarnish on its surface due to its reaction with sulfur compounds, and not rust | Chemistry | Metal Corrosion | 934 | CHEMISTRY |
A piece of gold that has been exposed to oxygen for decades | The model should generate an image of a piece of gold that has no visible corrosion or oxidation, demonstrating that it is highly resistant to oxidation, even after decades of exposure to oxygen | Chemistry | Metal Corrosion | 935 | CHEMISTRY |
A Gold block submerged in hydrochloric acid | The model should generate an image showing a gold block in hydrochloric acid with no visible change on the surface of the block, no bubbling, and the solution appearing colorless, demonstrating gold's lack of reactivity with hydrochloric acid | Chemistry | Solution Chemical Reaction | 936 | CHEMISTRY |
An iron nail submerged in hydrochloric acid | The model should generate an image showing an iron nail immersed in hydrochloric acid, with visible bubbling, some corrosion around the nail, and the solution potentially appearing a very pale green or yellow, indicating that it is reacting with the acid | Chemistry | Solution Chemical Reaction | 937 | CHEMISTRY |
A piece of copper in nitric acid | The model should generate an image showing a piece of copper in nitric acid, with bubbles forming and brown fumes coming from the solution, and the solution potentially having a blue or green tint as copper ions dissolve into the acid, demonstrating copper reacting with nitric acid | Chemistry | Solution Chemical Reaction | 938 | CHEMISTRY |
A strip of zinc in sulfuric acid | The model should generate an image showing a strip of zinc in sulfuric acid with a good amount of bubbling and a colorless and transparent solution during the reaction | Chemistry | Solution Chemical Reaction | 939 | CHEMISTRY |
A sample of aluminum in hydrochloric acid | The model should generate an image of aluminum in hydrochloric acid showing visible bubbling and signs of a reaction, that the aluminum is being dissolved in the acid, and that the solution appears colorless and transparent during this reaction process | Chemistry | Solution Chemical Reaction | 940 | CHEMISTRY |
A piece of magnesium in a solution of hydrochloric acid | The model should generate an image of a piece of magnesium that is reacting vigorously in hydrochloric acid with the production of many bubbles, indicating that it is rapidly reacting, and the solution appearing colorless and transparent throughout this process | Chemistry | Solution Chemical Reaction | 941 | CHEMISTRY |
A silver ring placed in nitric acid | The model should generate an image of a silver ring placed in nitric acid showing no visible reaction or bubbling, and the solution appearing colorless and transparent, indicating silver’s inert nature in that acid | Chemistry | Solution Chemical Reaction | 942 | CHEMISTRY |
A platinum wire submerged in hydrochloric acid | The model should generate an image showing a platinum wire immersed in hydrochloric acid that has no visible bubbling or change, and the solution appearing colorless and transparent, showing its lack of reactivity with this acid | Chemistry | Solution Chemical Reaction | 943 | CHEMISTRY |
A piece of tin in dilute sulfuric acid | The model should generate an image showing a piece of tin in dilute sulfuric acid with visible bubbling, indicating that a chemical reaction is taking place, and the solution appearing colorless and transparent as this reaction occurs | Chemistry | Solution Chemical Reaction | 944 | CHEMISTRY |
A piece of nickel being placed in hydrochloric acid | The model should generate an image showing a piece of nickel in hydrochloric acid where small amounts of bubbling are occurring and the nickel appears to be dissolving very slowly in the acid, demonstrating a slow reaction, with the solution potentially being a very pale green color | Chemistry | Solution Chemical Reaction | 945 | CHEMISTRY |
A large amount of carbon dioxide is bubbled through clear limewater solution | The model should generate an image showing a clear limewater solution becoming cloudy or milky as a large amount of carbon dioxide is bubbled through it, due to the formation of a calcium carbonate precipitate | Chemistry | Solution Chemical Reaction | 946 | CHEMISTRY |
A copper sulfate solution and an iron rod in it, the state of the solution and the iron rod should be highlighted | The model should generate an image showing an iron rod immersed in a blue copper sulfate solution, where the iron rod is corroding, and the blue color of the solution is beginning to fade or change to a light green color, while the surface of the iron rod is covered with a layer of red material demonstrating the reaction between iron and copper sulfate | Chemistry | Solution Chemical Reaction | 947 | CHEMISTRY |
A silver nitrate solution and a zinc bar in it, the state of the solution and the zinc bar should be highlighted | The model should generate an image showing a zinc bar immersed in a silver nitrate solution where silver metal is forming as a solid, and the zinc bar is being coated with a silvery layer, indicating the reaction between zinc and silver nitrate | Chemistry | Solution Chemical Reaction | 948 | CHEMISTRY |
A lead strip in a copper nitrate solution, highlighting the state of the solution and the lead strip | The model should generate an image of a lead strip in a blue copper nitrate solution where solid copper is beginning to form and plate out on the lead strip, with a reddish-brown color, and the lead metal is appearing corroded and having a duller appearance as it has begun to react in the solution | Chemistry | Solution Chemical Reaction | 949 | CHEMISTRY |
A piece of silver in a solution of copper nitrate, highlighting the state of the solution and the piece of silver | The model should generate an image of silver in a blue copper nitrate solution, showing no noticeable reaction and no change to either the silver metal or the solution | Chemistry | Solution Chemical Reaction | 950 | CHEMISTRY |
A strip of copper in a solution of aluminum sulfate, highlighting the state of the solution and the copper strip | The model should generate an image of a copper strip in a solution of aluminum sulfate showing no signs of any reaction in the solution or corrosion on the copper | Chemistry | Solution Chemical Reaction | 951 | CHEMISTRY |
A magnesium strip immersed in a solution of copper chloride, highlighting the state of the solution and the magnesium strip | The model should generate an image of a magnesium strip reacting rapidly in a solution of copper chloride, with bubbles forming, and the magnesium metal corroding and becoming smaller, and with the copper coming out of solution and visibly plating on the magnesium strip with a reddish-brown color, showing a very rapid reaction | Chemistry | Solution Chemical Reaction | 952 | CHEMISTRY |
A piece of iron wire immersed in a nickel sulfate solution, highlighting the state of the solution and the iron wire | The model should generate an image showing a piece of iron wire in a solution of nickel sulfate, with the wire corroding, and with nickel plating out of solution on the wire with a silvery appearance and the solution's original green color fading or becoming more pale | Chemistry | Solution Chemical Reaction | 953 | CHEMISTRY |
A strip of tin placed in a silver nitrate solution, highlighting the state of the solution and the tin strip | The model should generate an image of a strip of tin in a silver nitrate solution where silver metal is visibly forming as a solid, and plating out on the tin strip with a shiny, silvery color and the tin metal is being dissolved and corroding with a pitted or uneven surface, due to the reaction | Chemistry | Solution Chemical Reaction | 954 | CHEMISTRY |
A nickel bar immersed in a copper chloride solution, highlighting the state of the solution and the nickel bar | The model should generate an image showing a nickel bar immersed in a green solution of copper chloride, with the nickel slowly dissolving, and a reddish-brown copper layer forming on the surface of the nickel bar, and the solution gradually appearing less green, demonstrating the reaction between copper chloride and nickel, but being slower | Chemistry | Solution Chemical Reaction | 955 | CHEMISTRY |
A small piece of sodium metal added to water | The model should generate an image showing a small piece of sodium metal reacting vigorously with water, with visible bubbling, fizzing, and potentially a flame, demonstrating the exothermic reaction | Chemistry | Solution Chemical Reaction | 956 | CHEMISTRY |
A solution of potassium iodide being mixed with lead nitrate | The model should generate an image showing two clear solutions being mixed together to create a cloudy or yellow solution with a yellow precipitate, demonstrating a double displacement reaction | Chemistry | Solution Chemical Reaction | 957 | CHEMISTRY |
Hydrogen sulfide gas is bubbled through a copper sulfate solution | The model should generate an image showing a clear copper sulfate solution becoming cloudy, and forming a black precipitate as hydrogen sulfide gas is bubbled through it | Chemistry | Solution Chemical Reaction | 958 | CHEMISTRY |
Hydrogen sulfide gas is bubbled through a solution of concentrated sulfuric acid | The model should generate an image showing a concentrated sulfuric acid solution becoming cloudy with visible yellow or white particulate matter (sulfur) | Chemistry | Solution Chemical Reaction | 959 | CHEMISTRY |
The process of electrolysis of molten sodium chloride | The model should generate an image showing an electrolysis setup with molten sodium chloride, producing sodium metal at the cathode, and showing a greenish-yellow gas (chlorine) forming at the anode | Chemistry | Solution Chemical Reaction | 960 | CHEMISTRY |
The mixture of vinegar and litmus solution in a glass | The model should generate an image showing a glass of a vinegar and litmus solution mixture, with the liquid appearing red or pink, indicating an acidic solution | Chemistry | Solution Chemical Reaction | 961 | CHEMISTRY |
The mixture of cola and litmus solution in a glass | The model should generate an image of a glass of cola and litmus solution mixed liquid, with the liquid appearing red or pink, indicating an acidic solution | Chemistry | Solution Chemical Reaction | 962 | CHEMISTRY |
The mixture of baking soda solution and litmus solution in a glass | The model should generate an image showing a glass of baking soda and litmus solution mixture, with the liquid appearing blue or purple, indicating a basic (alkaline) solution | Chemistry | Solution Chemical Reaction | 963 | CHEMISTRY |
The mixture of milk and litmus solution in a glass | The model should generate an image of a glass of milk with litmus solution that has been left standing for a while, with the liquid appearing purple or a light blue-purple, indicating a neutral to slightly basic solution | Chemistry | Solution Chemical Reaction | 964 | CHEMISTRY |
A glass of lemon juice and litmus solution mixed liquid that has been standing for a while | The model should generate an image of a glass containing lemon juice mixed with litmus solution, and the liquid appearing red or pink, indicating an acidic solution | Chemistry | Solution Chemical Reaction | 965 | CHEMISTRY |
A glass of soapy water and litmus solution mixed liquid that has been standing for a while | The model should generate an image showing a glass of soapy water mixed with litmus solution, with the solution appearing blue or purple, indicating the basic nature of soapy water | Chemistry | Solution Chemical Reaction | 966 | CHEMISTRY |
A glass of black coffee and litmus solution mixed liquid that has been standing for a while | The model should generate an image of a glass of black coffee and litmus solution, with the liquid appearing red or pink, indicating an acidic solution | Chemistry | Solution Chemical Reaction | 967 | CHEMISTRY |
A glass of ammonia and litmus solution mixed liquid that has been standing for a while | The model should generate an image of ammonia mixed with litmus solution, with the liquid appearing a dark blue or purple, due to the high basicity of ammonia | Chemistry | Solution Chemical Reaction | 968 | CHEMISTRY |
A glass of apple juice and litmus solution mixed liquid that has been standing for a while | The model should generate an image of a glass of apple juice with litmus solution, with the liquid appearing red or pink, indicating that it is an acidic solution | Chemistry | Solution Chemical Reaction | 969 | CHEMISTRY |
A glass of hydrochloric acid and phenolphthalein solution mixed liquid that has been standing for a while | The model should generate an image showing a glass of hydrochloric acid mixed with phenolphthalein solution, with the liquid appearing colorless | Chemistry | Solution Chemical Reaction | 970 | CHEMISTRY |
A glass of sodium hydroxide solution and phenolphthalein solution mixed liquid that has been standing for a while | The model should generate an image showing a glass of sodium hydroxide solution mixed with phenolphthalein solution, with the liquid appearing pink or magenta, indicating a basic (alkaline) solution | Chemistry | Solution Chemical Reaction | 971 | CHEMISTRY |
Vinegar after mixing with red cabbage indicator | The model should generate an image showing a clear solution of vinegar mix with indicator, the solution should look red, indicating its acidity | Chemistry | Solution Chemical Reaction | 972 | CHEMISTRY |
The mixture of baking soda solution and vinegar in a glass | The model should generate an image showing a glass where a baking soda solution is reacting with vinegar, with visible bubbling due to the release of carbon dioxide gas | Chemistry | Solution Chemical Reaction | 973 | CHEMISTRY |
The mixture of baking soda solution and lemon juice in a glass | The model should generate an image showing a glass of lemon juice mixed with baking soda, with the mixture fizzing and producing bubbles, due to the formation of carbon dioxide gas | Chemistry | Solution Chemical Reaction | 974 | CHEMISTRY |
A piece of marble reacting with hydrochloric acid | The model should generate an image of a piece of marble reacting with hydrochloric acid, with visible bubbles being released from the surface of the marble due to carbon dioxide production | Chemistry | Solution Chemical Reaction | 975 | CHEMISTRY |
A solution of calcium carbonate reacting with acetic acid | The model should generate an image showing a solution of calcium carbonate reacting with acetic acid, producing clear bubbles due to the formation of carbon dioxide | Chemistry | Solution Chemical Reaction | 976 | CHEMISTRY |
Excess hydrochloric acid is added to a cloudy limewater solution | The model should generate an image showing a cloudy limewater solution becoming clear after excess hydrochloric acid is added, as the calcium carbonate precipitate dissolves due to the acid | Chemistry | Solution Chemical Reaction | 977 | CHEMISTRY |
Copper sulfate solution mixing with sodium hydroxide solution in a beaker | The model should generate a image of liquid in a beaker and should show the formation of a light blue precipitate (copper hydroxide) | Chemistry | Solution Chemical Reaction | 978 | CHEMISTRY |
Sodium sulfate solution mixing with barium chloride solution in a beaker | The model should generate a image of liquid in a beaker, and must show the formation of a white precipitate | Chemistry | Solution Chemical Reaction | 979 | CHEMISTRY |
Silver nitrate solution mixing with potassium chromate solution in a test tube | The model should generate a image of liquid in a test tube, and must show the formation of a red precipitate | Chemistry | Solution Chemical Reaction | 980 | CHEMISTRY |
Silver nitrate solution mixing with sodium chloride solution in a beaker | The model should generate a image of liquid in a beaker, and must show the formation of a white precipitate | Chemistry | Solution Chemical Reaction | 981 | CHEMISTRY |
Sulfuric acid stained the T-shirt | The model should generate an image showing a T-shirt with visible damage and charring in the area where sulfuric acid was spilled, indicating the destructive nature of the acid on organic material | Chemistry | Solution Chemical Reaction | 982 | CHEMISTRY |
A piece of wood that has been splashed with concentrated nitric acid | The model should generate an image showing a piece of wood that has been splashed with concentrated nitric acid with the wood showing signs of burning, discoloration, and degradation, from the acid corrosion | Chemistry | Solution Chemical Reaction | 983 | CHEMISTRY |
A sheet of paper after concentrated sulfuric acid is poured on it | The model should generate an image showing a sheet of paper with significant charring, blackening, and degradation in the area where concentrated sulfuric acid was poured, illustrating the destructive and corrosive effect of the acid on organic material | Chemistry | Solution Chemical Reaction | 984 | CHEMISTRY |
A laser beam slicing through a glass of colloid | Image depicts a clear glass or beaker filled with a fluid exhibiting the Tyndall effect. A visible laser beam should be shown passing through the fluid, with the path of the beam clearly illuminated within the fluid due to light scattering by colloidal particles. The fluid should appear slightly hazy or cloudy, not completely clear | Chemistry | Chemical Properties | 985 | CHEMISTRY |
A molecule of methane | The model should generate an image depicting a ball-and-stick or space-filling model of a methane molecule, showing one carbon atom bonded to four hydrogen atoms, to show a simple organic molecule | Chemistry | Chemical Properties | 986 | CHEMISTRY |
Unused charcoals | The model should generate an image showing unused charcoal, with the pieces appearing dark black, solid, and retaining their original shape and structure, representing the state before combustion | Chemistry | Chemical Properties | 987 | CHEMISTRY |
Used charcoals | The model should generate an image showing used charcoal, with pieces that appear white or light grey, broken, indicating that they have undergone combustion and the original carbon source has been consumed | Chemistry | Chemical Properties | 988 | CHEMISTRY |
Much Salt have been added into the protein solution in a beaker | The model should generate a beaker, and the solution in it should appear cloudy or have a visible precipitate of the protein | Chemistry | Chemical Properties | 989 | CHEMISTRY |
A burning matchstick dipped into water | The model should generate an image showing a burning matchstick that is quickly extinguished after being dipped into water, with the charred part of the matchstick appearing darker or blacker due to the water and the extinguishing process | Chemistry | Chemical Properties | 990 | CHEMISTRY |
White sugar crystals | The model should generate an image showing pure, white sugar crystals with a clear, well-defined crystalline structure | Chemistry | Chemical Properties | 991 | CHEMISTRY |
Burnt sugar | The model should generate an image showing burnt sugar with a dark brown or black color, a sticky or caramelized texture, and possibly smoke or fumes | Chemistry | Chemical Properties | 992 | CHEMISTRY |
Ammonium nitrate crystals dissolving in water in a beaker | The model should generate an image of water in a beaker with ammonium nitrate crystals being added and dissolving. The image should suggest a decrease in temperature, with condensation forming on the outside of the beaker | Chemistry | Chemical Properties | 993 | CHEMISTRY |
Sodium hydroxide pellets dissolving in water in a beaker | The model should generate an image of water in a beaker with sodium hydroxide pellets being added and dissolving, with slight wisps of steam rising from the solution, demonstrating the released heat | Chemistry | Chemical Properties | 994 | CHEMISTRY |
A clear solution of copper sulfate | The model should generate an image showing a transparent, bright blue solution in a glass container, representing dissolved copper sulfate | Chemistry | Chemical Properties | 995 | CHEMISTRY |
A solution of silver nitrate before light exposure | The model should generate an image depicting a clear, colorless liquid in a transparent container. There should be no visible precipitate or cloudiness, representing a stable silver nitrate solution protected from light | Chemistry | Chemical Properties | 996 | CHEMISTRY |
A solution of silver nitrate after light exposure | The model should generate an image depicting a solution in transparent container with the silver particles on the bottom. This showcases a container that was not covered or not shielded from radiation | Chemistry | Chemical Properties | 997 | CHEMISTRY |
A solid sample of potassium permanganate | The model should generate an image showing dark purple or almost black crystals or powder, characteristic of solid potassium permanganate | Chemistry | Chemical Properties | 998 | CHEMISTRY |
Potassium permanganate dissolved in water | The model should generate an image showing a deep purple or magenta solution, representing potassium permanganate dissolved in water. The intensity of the color should indicate a significant concentration | Chemistry | Chemical Properties | 999 | CHEMISTRY |
An open container of a volatile organic solvent | The model should generate an image showing an open container holding a liquid, with visible vapors emanating from the surface. The scene should convey the rapid evaporation of the solvent and potential hazards associated with its flammability or inhalation | Chemistry | Chemical Properties | 1,000 | CHEMISTRY |
Subsets and Splits
No community queries yet
The top public SQL queries from the community will appear here once available.