Concentration Terms and Definitions — SaitechAI

Term	Definition / Formula	Units
Weight/Weight % (w/w%)	\(\%w/w = \dfrac{w_2}{W}\times 100\)	% (g solute per 100 g solution)
Weight/Volume % (w/v%)	\(\%w/v = \dfrac{w_2}{V}\times 100\)	% (g solute per 100 mL solution)
Volume/Volume % (v/v%)	\(\%v/v = \dfrac{V_2}{V}\times 100\)	% (mL solute per 100 mL solution)
Molarity (M)	\(M = \dfrac{n_2}{V} = \dfrac{w_2}{M_2 \cdot V}\)	mol·L⁻¹
Molality (m)	\(m = \dfrac{n_2}{w_1(\mathrm{kg})} = \dfrac{w_2}{M_2 \cdot w_1(\mathrm{kg})}\)	mol·kg⁻¹
Normality (N)	\(N = \dfrac{eq_2}{V} = \dfrac{w_2}{\text{GEW}_2 \cdot V}, \ \text{GEW}_2 = \dfrac{M_2}{e}\)	eq·L⁻¹
Mole Fraction (\(x_2\))	\(x_2 = \dfrac{n_2}{n_1+n_2}\)	Dimensionless
Parts per million (ppm)	\(\text{ppm} = \dfrac{w_2}{W}\times 10^6\) For aqueous solutions: \(1 \ \text{mg·L}^{-1} \approx 1 \ \text{ppm}\)	ppm (mg·L⁻¹)

Symbols: \(w_2\) = solute mass (g), \(w_1\) = solvent mass (g or kg), \(W = w_1+w_2\) = solution mass, \(V\) = solution volume (L), \(V_2\) = solute volume, \(M_2\) = molar mass of solute (g·mol⁻¹), \(e\) = equivalence factor.

Expressions of Concentration — SaitechAI

Molarity (\(M\))

\[ M \;=\; \frac{n_2}{V}\;=\;\frac{w_2/M_2}{V}\quad\text{(mol L}^{-1}\text{)} \]

Normality (\(N\))

\[ N \;=\; \frac{\text{equivalents of solute}}{V} \;=\; \frac{eq_2}{V},\qquad eq_2 \;=\; \frac{w_2}{\text{GEW}_2} \]

\[ \text{GEW}_2 \;=\; \frac{M_2}{e} \] where \(e\) is the valence (equivalence) factor determined by the reaction context (acid–base, redox, precipitation, etc.).

Solute (typical context)	\(e\)	Notes
\(\mathrm{HCl}\), \(\mathrm{NaOH}\) (acid–base)	1	Monoprotic acid / monobasic base
\(\mathrm{H_2SO_4}\) (acid–base)	2	Diprotic acid (can donate 2 H\(^+\))
\(\mathrm{CaSO_4}\) (precipitation/ionic)	2	In ionic reactions, \(e\) equals total charge change per mole participating

Molality (\(m\))

Defined per kilogram of solvent (not solution).

\[ m \;=\; \frac{n_2}{\;w_1\;(\mathrm{kg})}\;=\;\frac{w_2/M_2}{w_1(\mathrm{kg})}\quad\text{(mol kg}^{-1}\text{)} \]

Mole Fraction

Sum of all mole fractions equals 1.

\[ x_2 \;=\; \frac{n_2}{n_1+n_2},\qquad x_1 \;=\; \frac{n_1}{n_1+n_2},\qquad x_1+x_2=1 \]

Parts Per Million (ppm)

• Mass fraction (general): \[ \mathrm{ppm} \;=\; \frac{w_2}{W}\times 10^{6} \]
• Aqueous, dilute (practical): \[ \mathrm{ppm} \;\approx\; \frac{\text{mg solute}}{\text{L solution}} \] (since \(1~\mathrm{mg\,L^{-1}}\approx 1~\mathrm{ppm}\) for water-like density)
• Volume basis (less common): if using \(w/v\) fraction, \[ \mathrm{ppm} \;=\; \bigl(\tfrac{w}{v}\bigr)\times 10^{6} \] with consistent units.

Quick Reference

Quantity	Primary Formula	Common Rearrangement
Molarity, \(M\)	\(M=\dfrac{n_2}{V}\)	\(M=\dfrac{w_2}{M_2\,V}\)
Normality, \(N\)	\(N=\dfrac{eq_2}{V}\)	\(N=\dfrac{w_2}{\text{GEW}_2\,V}\)
Molality, \(m\)	\(m=\dfrac{n_2}{w_1(\mathrm{kg})}\)	\(m=\dfrac{w_2}{M_2\,w_1(\mathrm{kg})}\)
Mole fraction, \(x_2\)	\(x_2=\dfrac{n_2}{n_1+n_2}\)	\(x_1=\dfrac{n_1}{n_1+n_2}\)
w/w%	\(\dfrac{w_2}{W}\times 100\)	—
w/v%	\(\dfrac{w_2}{V}\times 100\)	—
v/v%	\(\dfrac{V_2}{V}\times 100\)	—
ppm (mass)	\(\dfrac{w_2}{W}\times 10^{6}\)	\(\approx\dfrac{\text{mg}}{\text{L}}\) (aqueous)

Always specify temperature and density assumptions when converting between mass- and volume-based measures.