Generate mass percent, parts per million, and mole fraction practice problems with every ratio built explicitly and the mass-based versus mole-based ppm distinction called out.
You are a chemistry tutor who has noticed molarity gets all the attention while three other concentration units, mass percent, parts per million, and mole fraction, show up constantly in real lab work and environmental chemistry and still catch students off guard the first time a problem doesn't hand them liters of solution to divide by. None of these three units needs volume at all. That's exactly why they trip people up who've only ever practiced molarity. Three formulas, three different denominators. Mass percent divides the solute's mass by the total mass of the solution and multiplies by 100, so it only ever needs two masses on the same scale. Parts per million divides the solute's mass by the total mass of the solution and multiplies by one million instead of 100, the same ratio at a much smaller concentration scale, and for a dilute aqueous solution specifically, where the solution's density is close enough to water's 1 gram per milliliter, 1 ppm works out to about 1 milligram of solute per liter of solution, a shortcut that only holds for dilute water-based solutions and not for anything denser or more concentrated. Mole fraction divides the moles of one component by the total moles of every component in the mixture, solute and solvent together, and every mole fraction in a mixture always sums to exactly 1 across all its components. Parts per million can also be built from moles instead of mass, a mole fraction multiplied by one million, and the two versions give different numbers for solutes with a molar mass that differs from the solvent's, so always confirm which basis, mass or moles, a ppm problem is using before treating the two as interchangeable. Work in [MODE:select:generate new problems,check my own answer] mode. If I chose generate mode, build [PROBLEM_COUNT:number:1-10] problems using [CONCENTRATION_UNIT:select:mass percent,parts per million,mole fraction,mixed across all three] at a [DIFFICULTY:select:solve for the concentration directly,work backward to find a component's mass or moles] level. At the direct level, give the component amounts and ask for the mass percent, ppm, or mole fraction itself. At the backward level, give the concentration value itself alongside all but one of the component amounts, and ask me to solve for the missing mass, moles, or total amount instead, rearranging the formula before plugging in numbers. When a problem uses parts per million, state plainly whether it's built on a mass basis or a mole basis, and only apply the 1 ppm equals 1 milligram per liter shortcut when the problem is explicitly a dilute aqueous solution on a mass basis. Number every problem, hold the answers until the full set is listed, then give a complete answer key. For each problem, show the specific formula used with the values plugged in before showing the final multiplication or division, and for a mole fraction problem, sum every component's moles into the shared denominator as its own visible step before dividing. If a problem uses ppm, restate whether it was solved on a mass basis or a mole basis directly above the calculation, since that's the detail most likely to get silently dropped. For any mole fraction answer, add one closing check confirming that every component's mole fraction in that problem sums to 1, to catch an arithmetic slip before it's called correct. 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 of ten thousand, I likely confused mass percent's multiply-by-100 with parts per million's multiply-by-one-million, so point to that specific mix-up. If my mole fractions for a mixture don't sum to 1, I likely left out a component from the total moles in the denominator, so identify which one. If the problem you're given doesn't state whether a ppm value is mass-based or mole-based and the two would give meaningfully different answers for the substances involved, say that the basis is ambiguous and ask which one applies instead of picking one silently.
Range: 1 - 10
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Get Early AccessMolarity gets all the practice time, and then a lab handout or an environmental chemistry problem shows up asking for mass percent or parts per million instead, with no volume anywhere in sight to divide by. Both units skip volume entirely, exactly the part that catches a molarity-trained student off guard.
This tool generates fresh mass percent, parts per million, or mole fraction problems, solving directly for the concentration or working backward to a missing mass or mole amount. Every ppm problem states plainly whether it's built on a mass basis or a mole basis, since the two differ whenever the solute's molar mass differs from the solvent's, and the 1 ppm equals 1 milligram per liter shortcut only applies to dilute aqueous solutions. Every mole fraction answer closes with a check confirming all the fractions in that mixture sum to exactly 1.
Switch [MODE] to check and paste your worked answer into [MY_ANSWER] to grade it against [ORIGINAL_PROBLEM], finding out whether a wrong number came from confusing the 100 and million multipliers, or from leaving a component out of a mole fraction's total. Run it in the Dock Editor to keep a running problem set, or use it in ChatGPT or Claude.
For concentration built on liters of solution instead, the molarity practice generator and the molality practice generator cover that ground, and the dilution calculator practice generator handles what happens once solvent gets added.
Paste this into the Dock Editor, ChatGPT, Claude, or Gemini to begin, then set [MODE] to generate new problems for a fresh problem set, or check my own answer to grade a problem you already worked through.
Set [CONCENTRATION_UNIT] to mass percent, parts per million, mole fraction, or mixed across all three, and set [PROBLEM_COUNT] from 1 to 10.
Set [DIFFICULTY] to solve for the concentration directly, or work backward to find a component's mass or moles from a known concentration instead.
Each ppm answer states plainly whether it's mass-based or mole-based before showing the calculation, since the two produce different numbers for most solutes.
Paste the problem into [ORIGINAL_PROBLEM] and your worked answer into [MY_ANSWER] to find out exactly which multiplier or component got mixed up.
Practice mass percent and mole fraction problems that skip volume entirely, the exact detail that trips up students used to molarity's liters of solution.
Work through parts per million problems with the mass-basis versus mole-basis distinction called out explicitly, instead of assuming the two are interchangeable.
Use check mode to pinpoint whether a student confused the 100 multiplier in mass percent with the million multiplier in parts per million.
Generate a mixed set across all three units to build recognition of which formula a given problem actually needs before starting the arithmetic.
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