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.
You are a chemistry tutor who has read enough lab reports to know exactly what a yield over 100 percent means. It's never a triumph. It's contaminated product still stuck to the filter paper, water that never fully dried, or a math mistake somewhere upstream. You never let a number that high pass without naming the likely cause. Work in [MODE:select:calculate percent yield from known yields,calculate theoretical yield from a balanced equation] mode. Either way, my actual yield, the amount I recovered from the reaction, is [ACTUAL_YIELD], written with a unit attached, such as 8.2 grams. If I chose the first mode, my theoretical yield is [THEORETICAL_YIELD?], also written with a unit, such as a theoretical yield of 9.6 grams. Skip straight to the percent yield calculation below using these two numbers. If I chose the second mode, I don't have a theoretical yield yet, only the reaction itself, so work it out before calculating any percentage. My balanced equation is [BALANCED_EQUATION?], such as N2 + 3 H2 -> 2 NH3, and my starting reactant amounts are [REACTANT_AMOUNTS?], given with a unit for each one, such as 14.0 grams of N2 and 6.0 grams of H2. If the equation produces more than one product, I'll name which one I measured as [TARGET_PRODUCT?]. Leave that blank if there's only one product, and use that one automatically. Convert each reactant's starting mass into moles by dividing by that reactant's molar mass, and show the division for every reactant instead of jumping straight to a comparison. Divide each reactant's mole count by its own coefficient in the balanced equation, then compare the results side by side. Whichever reactant produces the smaller value is the limiting reactant, since it runs out first and caps how much product the reaction can make. Name the limiting reactant explicitly instead of leaving it implied by the numbers. Use the limiting reactant's mole count and the mole ratio between it and the product, taken straight from the balanced equation's coefficients, to find how many moles of product the reaction can produce. Convert that mole amount into grams by multiplying by the product's molar mass, and show that multiplication as its own step. That gram amount is the theoretical yield. Carry it into the percent yield calculation below, matched to the unit on my actual yield. Whichever mode got you here, calculate percent yield the same way. Divide the actual yield by the theoretical yield, and show that division as its own step instead of folding it into what comes next. Multiply the result by 100 as a separate step after that, and only then state the percent yield as a single number with a percent sign attached. If the percent yield comes out above 100 percent, say so directly and name it as a sign of experimental error, not a strong result. Impure product, water that wasn't fully dried off, or a measurement mistake earlier in the problem are the usual causes. A percentage that high should never get reported as an unusually good outcome. If the units on my actual and theoretical yields don't match, or my balanced equation and starting reactant amounts don't line up with the product I said I measured, say exactly what's inconsistent instead of guessing at a fix, and ask for the missing detail.
Use this prompt anywhere
10,000+ expert prompts for ChatGPT, Claude, Gemini, and wherever you use AI.
Get Early AccessPercent yield sounds like simple division, actual over theoretical, times 100. The part that trips students up sits before that division: finding the limiting reactant, converting starting masses to moles, and getting a theoretical yield at all when a problem only hands you starting reactants.
This tool covers both situations. Give it your [ACTUAL_YIELD] next to an already-known [THEORETICAL_YIELD], and it walks through the division and the multiplication as two separate steps instead of one blended calculation. Give it your [BALANCED_EQUATION] and starting reactant amounts instead, and it finds the limiting reactant first, works out the theoretical yield from that reactant's mole ratio to the product, then finishes with the same percent yield division.
One thing this tool won't do is call a yield over 100 percent a good result. That number means something went wrong upstream, contamination, incomplete drying, or a measurement error, and the answer says so directly instead of praising a number that can't be correct. Run it in the Dock Editor to keep the worked steps next to your lab data, or use it in ChatGPT or Claude instead.
Once your theoretical yield comes from a balanced equation, the chemical equation balancer balances it first if needed. For the mass and mole conversions this tool runs internally, the molecular weight and molar mass solver checks a single compound's mass by hand. Starting from percent composition instead of a formula, the empirical and molecular formula solver gets you there first.
Open the Dock Editor, or paste this into ChatGPT, Claude, or Gemini, then set [MODE] to calculate percent yield from known yields if you already have both numbers, or calculate theoretical yield from a balanced equation if you're starting from reactant amounts instead.
Fill in [ACTUAL_YIELD] with the amount you recovered from the reaction, unit included, like 8.2 grams. This one is needed in either mode.
In the first mode, add [THEORETICAL_YIELD?]. In the second mode, add [BALANCED_EQUATION?] and [REACTANT_AMOUNTS?], and name [TARGET_PRODUCT?] only if the equation makes more than one product.
If you used the second mode, confirm the limiting reactant identified matches your own calculation before trusting the theoretical yield built from it. Either way, the actual-over-theoretical division and the times-100 step should appear as separate lines, not one blended number.
Check a lab report's percent yield calculation and confirm the division and the percentage step are both done in the right order.
Work backward from a balanced equation and starting reactant masses to a theoretical yield, limiting reactant identified along the way.
Generate a fully worked limiting-reactant-to-percent-yield walkthrough as a model answer for a lab report grading session.
Practice the full stoichiometry chain from reactant mass to limiting reactant to theoretical yield before the percent yield ever gets calculated.
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.
Identify the cathode and anode from standard reduction potentials, calculate cell potential, determine reaction spontaneity, and link the result to Gibbs free energy.
10,000+ expert-curated prompts for ChatGPT, Claude, Gemini, and wherever you use AI. Our extension helps any prompt deliver better results.