Molality Calculator
Calculate molality, required solute mass, and colligative property changes - boiling point elevation and freezing point depression - for any solvent.
Molality Calculator
Calculate molality, required solute mass, and colligative property changes - boiling point elevation and freezing point depression - for any solvent.
📊 What Is Molality?
Molality (symbol m) is a measure of solute concentration expressed as moles of solute per kilogram of solvent. Unlike molarity, which is based on volume (mol/L), molality is based on mass (mol/kg), making it independent of temperature and pressure. This is why chemists use molality - not molarity - when studying colligative properties such as boiling point elevation, freezing point depression, and osmotic pressure, all of which change with temperature.
The distinction between solvent mass and solution mass is critical. A 1 molal solution of NaCl dissolves 58.44 g of NaCl in exactly 1,000 g of water. The total solution mass is 1,058.44 g - but the molality calculation uses only the solvent mass (1,000 g = 1 kg). This is the standard chemist's definition per IUPAC.
Molality is dimensionally expressed as mol/kg but is often written without units as simply "m" (lowercase, italic). A 0.5 m solution contains 0.5 moles of solute per kilogram of solvent. The term "molal" (as in "0.5 molal") describes such a solution colloquially.
This calculator covers three tasks: computing the molality of a solution from mass and molar mass, back-calculating how much solute to weigh out for a target molality, and predicting the colligative property changes - boiling point elevation and freezing point depression - for six built-in solvents (water, benzene, ethanol, acetone, cyclohexane, acetic acid) or any custom solvent.
📐 Formula
📖 How to Use
Steps to Calculate
💡 Example Calculations
Example 1 — NaCl in water (Find Molality)
Dissolve 5.85 g of NaCl (molar mass = 58.44 g/mol) in 100 g of water.
Example 2 — Preparing 250 g of 0.5 m glucose solution (Find Solute Mass)
Glucose molar mass = 180.16 g/mol; solvent = 250 g of water (0.250 kg).
Example 3 — Colligative properties of 1 m NaCl in water
NaCl dissociates into Na⁺ and Cl⁻, so i = 2. Water: Kb = 0.512, Kf = 1.86 °C·kg/mol.
❓ Frequently Asked Questions
🔗 Related Calculators
What is molality and how is it different from molarity?
Molality (m) is the number of moles of solute per kilogram of solvent: m = n(solute) / kg(solvent). Molarity (M) is moles of solute per litre of solution. The key difference is the denominator: molality uses mass of the pure solvent, while molarity uses volume of the total solution. Molality does not change with temperature because it is based on mass, not volume. Molarity changes slightly with temperature as liquids expand and contract. For colligative property calculations, molality is always preferred.
What is the formula for molality?
Molality (m) = moles of solute / kilograms of solvent = n / m(solvent in kg). The moles of solute = mass of solute in grams / molar mass of solute. So the full formula is: molality = (mass of solute in g / molar mass in g/mol) / mass of solvent in kg. Units are mol/kg, also written as molal (m).
How do I calculate boiling point elevation using molality?
Boiling point elevation: delta Tb = Kb times m, where Kb is the ebullioscopic constant (solvent-specific) and m is the molality of the solution. For water, Kb = 0.512 degrees C per mol/kg. A 1 mol/kg NaCl solution (which dissociates into 2 particles, i = 2) raises the boiling point by 0.512 times 2 times 1 = 1.024 degrees C, so water boils at 101.024 degrees C instead of 100 degrees C.
How do I calculate freezing point depression?
Freezing point depression: delta Tf = Kf times m, where Kf is the cryoscopic constant. For water, Kf = 1.86 degrees C per mol/kg. A 0.5 mol/kg glucose solution (non-electrolyte, i = 1) lowers the freezing point by 1.86 times 0.5 = 0.93 degrees C, so the solution freezes at -0.93 degrees C instead of 0 degrees C. This principle explains why salt lowers the freezing point of ice on roads.
What units does molality use?
Molality uses units of mol/kg, often abbreviated as m (lowercase, italic). A 1 m (1 molal) solution contains 1 mole of solute dissolved in exactly 1 kilogram of solvent. Do not confuse this with molarity (M, uppercase) which uses mol/L. The unit mol/kg is also written as mol kg-1 in IUPAC notation.
How do I find the mass of solute needed for a target molality?
Rearrange the molality formula: mass of solute (g) = target molality times mass of solvent (kg) times molar mass of solute (g/mol). For a 0.5 mol/kg NaCl solution using 500 g of water: moles needed = 0.5 times 0.5 = 0.25 mol. Mass of NaCl = 0.25 times 58.44 = 14.61 g. Use the Find Solute Mass mode in this calculator to compute this instantly.
Why does salt lower the freezing point of water?
Salt (NaCl) dissolves into Na+ and Cl- ions, creating more solute particles than a non-ionic compound. More dissolved particles disrupt the formation of the ice crystal lattice, requiring a lower temperature to freeze. This is the colligative property called freezing point depression: delta Tf = Kf times i times m, where i = 2 for NaCl. A 0.5 mol/kg NaCl solution depresses the freezing point by 1.86 times 2 times 0.5 = 1.86 degrees C.
What is the van't Hoff factor and how does it affect molality calculations?
The van't Hoff factor (i) accounts for the number of particles a solute produces when dissolved. For non-electrolytes like glucose: i = 1. For NaCl: i = 2 (Na+ and Cl-). For CaCl2: i = 3 (Ca2+ and 2 Cl-). Colligative property formulas become: delta Tf = i times Kf times m and delta Tb = i times Kb times m. Without accounting for i, calculations for ionic compounds will underestimate the effect by a factor of 2 or more.