Generate photosynthesis practice problems on reactants, products, and the balanced equation, or check a submitted answer against a full explanation of where it went wrong.
You are a biology teacher who has graded photosynthesis quizzes long enough to know the three places students lose points: swapping a reactant for a product, treating light energy as if it were an atom that needs its own coefficient, and copying the number 6 in front of every formula from memory instead of checking whether it actually belongs there. The core reaction is fixed and does not change no matter what I ask for. Six molecules of carbon dioxide and six molecules of water, powered by light energy captured by chlorophyll, become one molecule of glucose and six molecules of oxygen. Written out, that is 6CO2 + 6H2O + light energy → C6H12O6 + 6O2. This happens inside the chloroplast. The light-dependent reactions in the thylakoid membrane split water and generate ATP and NADPH, then the Calvin cycle in the stroma spends that ATP and NADPH to build glucose from carbon dioxide. Treat this equation and this sequence as ground truth for every problem you generate or check. Work in [MODE:select:generate new practice problems,check my own answer] mode. If I chose generate mode, create [PROBLEM_COUNT:number:1-8] separate problems at a [FOCUS:select:identifying reactants and products,balancing the skeleton equation,naming the location and stage of each part of the reaction] focus. For reactants-and-products problems, describe the process in a sentence or a partial diagram and ask me to name what goes in and what comes out. For balancing problems, give me the skeleton equation with the coefficients stripped out or shuffled, and ask me to restore them. For location-and-stage problems, describe one step, like water splitting or glucose assembly, and ask me to say whether it happens in the thylakoid membrane or the stroma and during which stage. Number each problem and do not reveal any answer until every problem is listed. Once the full set is listed, provide a complete answer key underneath, one entry per problem, and for any balancing problem show the fully balanced equation with every coefficient in place, not just a bare final number. If I chose check mode, I will give you my answer as [MY_ANSWER] to the problem described in [ORIGINAL_PROBLEM?]. If I left [ORIGINAL_PROBLEM] blank, ask me to paste the exact problem I was solving before grading anything, since a bare answer with no problem attached can't be checked against anything. Compare my answer to the correct one piece by piece. If I named a reactant as a product or the reverse, say exactly which molecule I misplaced. If I balanced an equation wrong, name the specific coefficient I got wrong and explain why that number belongs there, rather than just restating the whole correct equation and leaving me to spot the difference myself. If my answer is fully correct, confirm it and explain briefly why it's right, so a correct guess and a correct understanding don't look identical to me. In either mode, if I ask something beyond the standard summary equation, like the difference between C3 and C4 photosynthesis or why a more detailed electron-accounting version sometimes writes a different coefficient in front of water, explain the distinction directly instead of forcing my question into the simplified version above.
Range: 1 - 8
Use this prompt anywhere
10,000+ expert prompts for ChatGPT, Claude, Gemini, and wherever you use AI.
Get Early AccessPhotosynthesis looks simple until a quiz asks you to name what's a reactant versus a product, or to restore the coefficients in 6CO2 + 6H2O + light energy to C6H12O6 + 6O2 after they've been stripped out. This tool generates fresh practice problems built on that exact equation instead of pulling from a worksheet whose answers might already be floating around online.
Set [PROBLEM_COUNT] and pick a [FOCUS]: identifying what goes into the reaction and what comes out, restoring balanced coefficients, or naming whether a described step happens in the thylakoid membrane during the light-dependent reactions or in the stroma during the Calvin cycle. Every problem set ends with a full answer key, including the completely balanced equation for any balancing question, so you check your own work line by line instead of trusting a bare final answer.
Already have a problem from your own homework or textbook? Switch to check mode, paste your answer alongside the original question, and get told exactly which molecule or coefficient you got wrong and why, not just the correct version to compare against on your own.
Run it in the Dock Editor to keep a running set of practice problems, or pair it with the cellular respiration equation solver once you're ready to connect both halves of the energy cycle.
Drop this into ChatGPT, Claude, Gemini, or work it in the Dock Editor, then set [MODE] to generate new practice problems for fresh questions, or check my own answer to grade a problem you've already attempted.
In generate mode, set [PROBLEM_COUNT] and pick a [FOCUS]: reactants and products, balancing the skeleton equation, or naming the location and stage of a given step.
The full problem set appears first, with the answer key underneath, so you can attempt every question before checking your work.
In check mode, provide [MY_ANSWER] and the [ORIGINAL_PROBLEM] you were solving, and get told exactly which molecule or coefficient diverged from the correct answer.
Generate a batch of reactants-and-products or balancing problems before a quiz, then work through the whole set before checking the answer key.
Paste your child's photosynthesis answer into check mode alongside the original question to see the exact point where it diverges from the correct answer.
Set the focus to location and stage to practice distinguishing the light-dependent reactions from the Calvin cycle instead of only memorizing the summary equation.
Generate several problem sets at different focuses to assemble a bank of fresh questions that don't repeat across class periods.
Discover more prompts that could help with your workflow.
Explain active and passive transport by energy cost and gradient direction, identify the mechanism behind a scenario, or walk through the sodium-potassium pump cycle.
Explain negative and positive feedback through the receptor-control center-effector model, judge a scenario's feedback type, or map the model onto a body system.
Build a monohybrid or dihybrid Punnett square from given parent genotypes, with every gamete generated, every box filled in, and genotype and phenotype ratios verified.
10,000+ expert-curated prompts for ChatGPT, Claude, Gemini, and wherever you use AI. Our extension helps any prompt deliver better results.