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Physical Chemistry XII · 3 Chapters · 23 marks

Physical Chemistry Formula Reference

Solutions, Electrochemistry & Chemical Kinetics — every equation organised for quick revision.

⚡ Critical Formulas — Memorise These First

Nernst EquationE = E° − (0.0591/n) log Q
First-Order kk = (2.303/t) log([A]₀/[A])
Arrheniusk = Ae^(−Ea/RT)
BP ElevationΔTb = Kb × m
FP DepressionΔTf = Kf × m
Osmotic Pressureπ = CRT = (n/V)RT
Faraday's 1st Lawm = (M/nF) × It
Half-Life (1st order)t½ = 0.693/k
01 Solutions 7 marks
Mole Fraction
xA = nA / (nA + nB)
xA + xB = 1. Dimensionless. Used in Raoult's law.
Raoult's Law
pA = xA × p°A ; pTotal = pA + pB
Valid for ideal solutions. p°A = vapour pressure of pure A.
Relative Lowering of Vapour Pressure
ΔP/P° = (p°A − pA)/p°A = xB
xB = mole fraction of solute. ΔP/P° is a colligative property.
Elevation of Boiling Point
ΔTb = Kb × m Kb: K·kg·mol⁻¹
Kb = ebullioscopic constant (water: 0.52). m = molality (mol/kg solvent).
Depression of Freezing Point
ΔTf = Kf × m Kf: K·kg·mol⁻¹
Kf = cryoscopic constant (water: 1.86). Used to find molar mass.
Osmotic Pressure
π = CRT = (n/V)RT π = iCRT [for electrolytes] π: bar or atm
Van't Hoff equation. C = molarity (mol/L). R = 0.083 L·bar·mol⁻¹·K⁻¹ (NCERT). i = van't Hoff factor; use for electrolytes (NaCl: i≈2, MgCl₂: i≈3).
Molar Mass from Colligative Properties
M = (Kb × w × 1000) / (ΔTb × W)
w = mass of solute (g), W = mass of solvent (g). Also works with Kf/ΔTf.
van't Hoff Factor
i = observed colligative property / theoretical value i = 1 + (n−1)α [dissociation] i = 1 − (1 − 1/n)α [association]
n = particles formed; α = degree of dissociation/association. i > 1 for dissociation, i < 1 for association.
02 Electrochemistry 9 marks
Standard Cell EMF
E°cell = E°cathode − E°anode
Cathode = reduction (+ve electrode). Anode = oxidation (−ve electrode).
Nernst Equation
E = E° − (RT/nF) ln Q E = E° − (0.0591/n) log Q [at 25°C]
n = electrons transferred; F = 96500 C/mol; Q = reaction quotient.
Gibbs Energy & EMF
ΔG° = −nFE°cell log K = nE° / 0.0591
Spontaneous if E°cell > 0 (ΔG° < 0). K = equilibrium constant.
Molar Conductivity
Λm = κ × 1000 / M S·cm²·mol⁻¹
κ = conductivity (S/cm); M = molarity (mol/L). Λm increases as dilution increases.
Kohlrausch's Law
Λ°m = Σν₊λ°₊ + Σν₋λ°₋ Λm = Λ°m − b√c [strong electrolytes]
λ° = limiting molar conductivity of individual ions. Used to find Λ°m of weak electrolytes.
Faraday's First Law
m = ZIt = (M / nF) × It m: grams
Z = electrochemical equivalent = M/(nF). I = current (A); t = time (s).
Faraday's Second Law
m₁/m₂ = E₁/E₂
E = equivalent weight = M/n. Same charge deposits masses in ratio of equivalent weights.
Key Constants
F = 96500 C mol⁻¹ RT/F = 0.02569 V [at 25°C]
1 Faraday = charge on 1 mole of electrons. 2.303RT/F = 0.0591 V at 298 K.
03 Chemical Kinetics 7 marks
Rate of Reaction
r = −(1/a) d[A]/dt = +(1/b) d[B]/dt
For aA → bB. Rate is always positive. Units: mol L⁻¹ s⁻¹.
Rate Law
r = k [A]^m [B]^n
m, n = orders (determined experimentally, not from stoichiometry). Overall order = m + n.
Units of Rate Constant k
k: (mol L⁻¹)^(1−n) s⁻¹
Zero order: mol L⁻¹ s⁻¹. First order: s⁻¹. Second order: L mol⁻¹ s⁻¹.
Zero Order Integrated Rate Law
[A] = [A]₀ − kt t½ = [A]₀ / 2k
Plot [A] vs t → straight line (slope = −k). Half-life depends on initial concentration.
First Order Integrated Rate Law
k = (2.303/t) log ([A]₀/[A]) t½ = 0.693/k
Plot ln[A] vs t → straight line (slope = −k). Half-life INDEPENDENT of [A]₀.
Arrhenius Equation
k = A e^(−Ea/RT) log(k₂/k₁) = (Ea/2.303R) × (T₂−T₁)/(T₁T₂) Ea: J mol⁻¹
A = frequency factor. R = 8.314 J mol⁻¹ K⁻¹. Plot log k vs 1/T → slope = −Ea/2.303R.
Effect of Temperature
rate doubles for every 10°C rise
Temperature coefficient ≈ 2. Catalyst lowers Ea without changing ΔH.