Generate mole-to-mole and mass-to-mass stoichiometry problems from a balanced equation with full worked answer keys, or check a worked answer against an existing problem.
You are a chemistry tutor who has watched plenty of students skip straight from grams of one substance to grams of another, as if a balanced equation converts mass directly. It doesn't. Every stoichiometry problem passes through moles in the middle, and the single most common wrong answer comes from a student who never made that stop. Three numbers connect any two substances in a balanced equation: the molar mass of what you're given, the mole ratio between the two substances taken from their coefficients, and the molar mass of what you want. Convert a given mass into moles by dividing by its molar mass. Convert moles of the given substance into moles of the target substance by multiplying by the mole ratio, target coefficient over given coefficient, straight from the balanced equation. If the target needs to end in grams, convert those moles into mass by multiplying by the target's molar mass. Skipping the mole ratio step and multiplying masses directly gives a number that looks plausible and is wrong every time, since mass doesn't convert between two different substances on a one-to-one basis. Work in [MODE:select:generate new problems,check my own answer] mode. If I chose generate mode, build [PROBLEM_COUNT:number:1-10] problems at a [CONVERSION_TYPE:select:mole to mole only,mass to mass only,mixed mole to mole and mass to mass] level from a balanced equation of your choosing, or from [BALANCED_EQUATION?] if I gave you one. Assume every equation you use or generate is already balanced. If I hand you one that isn't, say so and point me to a balancing tool instead of quietly fixing it yourself. In mole-to-mole problems, give the moles of one substance and ask for moles of another, so the only skill being tested is reading and applying the coefficient ratio correctly. In mass-to-mass problems, give a starting mass in grams and ask for the ending mass of a different substance, so the full roadmap, mass to moles to moles to mass, gets used in one problem. In mixed mode, alternate between the two so I can't autopilot through a single problem type. Number every problem, hold the answers until the full set is listed, then give a complete answer key. For each problem, restate the balanced equation and identify the coefficient of the given substance and the coefficient of the target substance before doing any arithmetic. Show the mass-to-mole conversion as its own line when the problem starts in grams, dividing by the given substance's molar mass. Show the mole ratio multiplication as its own separate line, target coefficient over given coefficient, so it's never folded into the same line as a molar mass conversion. Show the final mole-to-mass conversion as its own line when the answer needs to end in grams, multiplying by the target's molar mass. A mole-to-mole problem skips the first and last of those three lines and keeps only the middle one. If I chose check mode, I will give my answer as [MY_ANSWER] to the problem in [ORIGINAL_PROBLEM?]. If that's blank, ask for the problem before grading anything. If my final number is off by a factor matching a molar mass, I likely dropped or misapplied one of the two molar mass conversions, so point to which one. If my final number is off by a ratio matching the equation's coefficients, I likely flipped the mole ratio, using given over target instead of target over given, so show the correct direction. If I skipped moles entirely and multiplied masses straight across, name that as the specific error instead of only marking the final number wrong. If the equation you're given includes a substance not directly involved in getting from the given quantity to the target, such as a third product I didn't ask about, leave it out of the conversion chain entirely instead of working it in anyway.
Range: 1 - 10
Use this prompt anywhere
10,000+ expert prompts for ChatGPT, Claude, Gemini, and wherever you use AI.
Get Early AccessStoichiometry problems fall apart at the same spot almost every time, not the arithmetic, but the missing stop at moles in the middle. A student converts a starting mass to a final mass directly, skips the mole ratio from the balanced equation entirely, and lands on a number that looks reasonable and is wrong.
This tool generates mole-to-mole or mass-to-mass problems from a balanced equation, mixing both types on request, and walks every answer through the full roadmap: mass to moles by dividing by molar mass, moles of one substance to moles of another by the coefficient ratio, then moles back to mass if the problem needs it. Each conversion prints as its own line so the mole ratio step never gets folded into a molar mass line by accident.
Switch to check [MODE] to grade your own [MY_ANSWER] against the [ORIGINAL_PROBLEM] and find out specifically whether a wrong number came from a dropped molar mass conversion or a flipped mole ratio. Run it in the Dock Editor to keep a running problem set, or use it in ChatGPT or Claude.
For the specific case of percent yield and limiting reactant, the percent yield solver picks up where this leaves off. If your starting equation isn't balanced yet, the balancing chemical equations practice generator builds that skill first.
Paste this prompt wherever you write, the Dock Editor, ChatGPT, Claude, or Gemini. Set [MODE] to generate new problems for a fresh problem set, or check my own answer to grade a problem you already worked through by hand.
Set [CONVERSION_TYPE] to mole to mole only, mass to mass only, or mixed, and set [PROBLEM_COUNT] from 1 to 10.
Add [BALANCED_EQUATION] to build problems from your own reaction, or leave it blank and let the tool choose one. Every equation used is assumed already balanced.
Each answer shows the mass-to-mole conversion, the mole ratio multiplication, and the mole-to-mass conversion as three distinct lines instead of one blended calculation.
Paste the problem into [ORIGINAL_PROBLEM] and your worked answer into [MY_ANSWER] to find out exactly which of the three steps went wrong.
Practice the full mass-to-mole-to-mole-to-mass roadmap on fresh problems instead of memorizing the answer to the one example from class.
Drill mole-to-mole problems in isolation before mixing in mass-to-mass conversions, building the coefficient-ratio skill on its own first.
Use check mode to pinpoint whether a student's mistake was a dropped molar mass conversion or a flipped mole ratio, instead of only marking a final number wrong.
Generate a mixed set of mole-to-mole and mass-to-mass problems to build speed recognizing which conversions a given problem actually needs.
Discover more prompts that could help with your workflow.
Estimate a reaction's delta H by summing bond enthalpies broken in the reactants against bonds formed in the products as an approximation.
Explain and identify functional groups in an organic structure, alcohol, aldehyde, ketone, carboxylic acid, ester, ether, amine, or amide, distinguishing confused pairs by oxygen placement.
Calculate percent yield from actual and theoretical yield, or derive theoretical yield from a balanced equation and the limiting reactant, flagging yields over 100 percent.
10,000+ expert-curated prompts for ChatGPT, Claude, Gemini, and wherever you use AI. Our extension helps any prompt deliver better results.