Convert between molarity, g/L, ppm, ppb, and percent concentration. Calculate the mass of solute needed for any solution.
Concentration is the fundamental measure of how much solute is dissolved in a given amount of solution. In chemistry, biology, environmental science, and medicine, different concentration units are used depending on the application: molarity (mol/L) for stoichiometric calculations, grams per liter for mass-based preparations, parts per million for trace analysis, and weight-per-volume percent for clinical solutions.
Converting between these units requires knowing the molecular weight of the solute and, in some cases, the solution density. While the conversions are straightforward, they are a frequent source of errors in the lab — a decimal place mistake can mean a tenfold difference in concentration, potentially ruining an experiment or creating a safety hazard.
This concentration calculator accepts input in any of the common formats and instantly converts to all the others. Enter your solute amount (as moles, grams, or milligrams), the molecular weight, and the solution volume, and the calculator displays molarity, millimolar, micromolar, grams per liter, ppm, ppb, and weight-per-volume percent — complete with the mass of solute required. It bridges the gap between how reagents are sold and how solutions are specified in protocols.
Concentration unit conversions are among the most common calculations in chemistry labs. This calculator eliminates arithmetic errors and instantly provides all the units you need, saving time and preventing costly mistakes. This concentration calculator helps you compare outcomes quickly and reduce avoidable mistakes when making day-to-day care decisions. Use the estimate as a planning baseline and confirm final decisions with a qualified professional when risk is high.
Molarity = moles / volume(L). g/L = M × MW. ppm = g/L × 1000 (for dilute aqueous). % w/v = (mass_g / (volume_mL × density)) × 100. mM = M × 1000. µM = M × 10⁶.
Result: 1 M = 1000 mM = 58,440 ppm
1 mole of NaCl (MW 58.44) in 1 L gives 1 M molarity. Mass is 58.44 g, so g/L = 58.44, ppm = 58,440, and w/v% ≈ 5.844%.
Molarity (M) measures moles per liter of solution. Molality (m) measures moles per kilogram of solvent — it doesn't change with temperature since mass is independent of volume. Normality (N) measures equivalents per liter, where an equivalent depends on the reaction (moles × valence factor for acid-base, moles × electrons transferred for redox).
Environmental and pharmaceutical chemistry often require trace analysis at the ppm, ppb, or even ppt (parts per trillion) level. These units are convenient because they avoid very small decimal numbers. For example, the EPA drinking water standard for lead is 15 ppb, which is more intuitive than 0.000015 g/L or 7.24 × 10⁻⁸ M.
To prepare a molar solution: (1) Calculate the required mass: mass = M × V × MW, (2) Weigh the solute on an analytical balance, (3) Transfer to a volumetric flask and dissolve in ~80% of the final volume, (4) Bring to the mark with solvent, and (5) Mix thoroughly. For hygroscopic chemicals, work quickly to avoid moisture absorption that throws off the mass.
Molarity (M) is the number of moles of solute per liter of solution. A 1 M NaCl solution contains 58.44 g of NaCl per liter.
1 ppm = 1 mg/L = 1,000 ppb. Parts per million is used for trace concentrations; parts per billion for ultra-trace analysis like water quality testing.
Multiply the molarity by the molecular weight: g/L = M × MW. For example, 0.5 M glucose (MW 180.16) = 90.08 g/L.
Ppm is standard in environmental and food chemistry for trace analytes. Molarity is preferred in stoichiometric, analytical, and biochemical work where mole ratios matter.
For dilute aqueous solutions where density ≈ 1 g/mL, 1 ppm ≈ 1 mg/L ≈ 1 mg/kg. For non-aqueous or dense solutions, ppm should be defined explicitly as mass/mass or mass/volume.
Weight-per-volume percent: grams of solute per 100 mL of solution. A 5% w/v glucose solution has 5 g of glucose per 100 mL.