🧭 Overview
🧠 One-sentence thesis
Partial molar quantities measure how an extensive property of a mixture changes when a small amount of one component is added at constant temperature and pressure, providing a powerful framework for understanding mixture behavior and equilibrium.
📌 Key points (3–5)
- Definition: A partial molar quantity X_i is the rate of change of extensive property X with the amount of species i added, holding T, p, and all other amounts constant.
- Key insight: When you add one mole of a substance to a large mixture, the volume (or other property) change is usually not equal to the molar volume of the pure substance—intermolecular interactions in the mixture cause deviations.
- Additivity rule: The total value of any extensive property X equals the sum of (amount of each species) × (its partial molar quantity).
- Gibbs–Duhem constraint: Changes in partial molar quantities are linked—if one increases with composition change, another must decrease in a related way.
- Chemical potential: The partial molar Gibbs energy is called the chemical potential and governs the escaping tendency of a species, central to equilibrium problems.
📐 Defining partial molar quantities
📐 The core definition
Partial molar quantity X_i: the rate at which property X changes with the amount of species i added to the mixture, at constant T, p, and amounts of all other species: X_i = (∂X/∂n_i) at constant T, p, n_j≠i
- X is any extensive property (volume, enthalpy, entropy, Gibbs energy, etc.).
- The subscript i identifies a constituent species.
- This is an intensive state function—its value depends on T, p, and composition, not on system size.
⚠️ Practical limitation for charged species
- A partial molar quantity of an ion (charged species) is a theoretical concept.
- You cannot physically add a macroscopic amount of a single ion to a phase without creating a huge electric charge.
- Therefore, partial molar quantities of ions cannot be determined experimentally in isolation (though relative values can be found using reference ions).
🧪 Partial molar volume: a concrete example
🧪 Water–methanol mixing behavior
The excerpt uses volume because it is easily visualized:
- Pure water at 25 °C, 1 bar: molar volume = 18.07 cm³/mol
- Pure methanol at 25 °C, 1 bar: molar volume = 40.75 cm³/mol
- Mix 100.0 cm³ water + 100.0 cm³ methanol → total volume = 193.1 cm³, not 200.0 cm³
- The 6.9 cm³ "missing" volume arises from new intermolecular interactions in the mixture.
🔬 Adding methanol to a large mixture
Imagine a large volume (10,000 cm³) of water–methanol mixture with mole fraction x_B = 0.307 (B = methanol):
- Add 40.75 cm³ (one mole) of pure methanol.
- The mixture volume increases by only 38.8 cm³, not 40.75 cm³.
- Because the added amount is small compared to the total, the composition barely changes (x_B increases by only 0.5%).
- This volume change per mole added approximates the partial molar volume: V_B ≈ 38.8 cm³/mol at this composition.
Interpretation: The partial molar volume V_B is the volume increase per mole of B when B is mixed with such a large volume of mixture that the composition is not appreciably affected—or equivalently, the volume change per amount when an infinitesimal amount is mixed with a finite volume.
🔄 Limiting values
- As x_B → 1 (pure B), the partial molar volume V_B approaches the molar volume of pure B: V_B(x_B=1) = V°_B.
- As x_B → 0 (infinite dilution), V_B approaches a limiting value V∞_B, the partial molar volume at infinite dilution (each solute molecule surrounded only by solvent).
➖ Negative partial molar volumes
- It is possible for a partial molar volume to be negative.
- Example: Magnesium sulfate in dilute aqueous solution (molality < 0.07 mol/kg) has negative V_MgSO₄.
- Physical meaning: when a small amount of crystalline MgSO₄ dissolves in water at constant T, the liquid phase contracts.
- Cause: strong attractive water–ion interactions.
🧮 Mathematical framework
🧮 Total differential for an open binary mixture
For a binary mixture (substances A and B), the volume has four independent variables: T, p, n_A, n_B.
The total differential of V is:
dV = (∂V/∂T) dT + (∂V/∂p) dp + (∂V/∂n_A) dn_A + (∂V/∂n_B) dn_B
Recognizing the partial derivatives:
- (∂V/∂T) at constant p, n_A, n_B = αV (thermal expansion)
- (∂V/∂p) at constant T, n_A, n_B = −κ_T V (compressibility)
- (∂V/∂n_A) at constant T, p, n_B = V_A (partial molar volume of A)
- (∂V/∂n_B) at constant T, p, n_A = V_B (partial molar volume of B)
So: dV = αV dT − κ_T V dp + V_A dn_A + V_B dn_B
At constant T and p: dV = V_A dn_A + V_B dn_B
➕ Additivity rule
Imagine continuously pouring pure A and pure B at constant rates into a stirred container at constant T and p, forming a mixture of increasing volume and constant composition.
Because T, p, and composition are constant, V_A and V_B remain constant during the process.
Integrating dV = V_A dn_A + V_B dn_B gives:
Additivity rule: V = n_A V_A + n_B V_B (binary mixture)
This allows calculating the mixture volume from the amounts and the appropriate partial molar volumes for the particular T, p, and composition.
Example: For water–methanol mixture with x_B = 0.307, given V_A = 17.74 cm³/mol and V_B = 38.76 cm³/mol:
- n_A = 5.53 mol, n_B = 2.45 mol
- V = (17.74)(5.53) + (38.76)(2.45) = 193.1 cm³ ✓
🔗 Gibbs–Duhem equation
Differentiating the additivity rule V = n_A V_A + n_B V_B:
dV = V_A dn_A + V_B dn_B + n_A dV_A + n_B dV_B
But we already know dV = V_A dn_A + V_B dn_B at constant T and p.
These are consistent only if:
Gibbs–Duhem equation: n_A dV_A + n_B dV_B = 0 (constant T and p)
Equivalently: x_A dV_A + x_B dV_B = 0
Meaning: Changes in V_A and V_B are linked when composition changes at constant T and p.
Rearranging: dV_A = −(n_B/n_A) dV_B
- A composition change that increases V_B (positive dV_B) must make V_A decrease.
- The water–methanol data show this mirroring: a minimum in V_B at x_B ≈ 0.09 corresponds to a maximum in V_A (though attenuated because n_B/n_A is small there).
📊 Experimental determination: method of intercepts
📊 Mean molar volume plot
Plot V/n (the mean molar volume) versus mole fraction x_B.
At the composition of interest x°_B:
- Draw the tangent line to the curve at that point.
- The tangent intercepts the vertical axis at x_B = 0 at V_A.
- The tangent intercepts the vertical axis at x_B = 1 at V_B.
Derivation sketch:
- From the additivity rule: V/n = V_A x_A + V_B x_B = V_A(1 − x_B) + V_B x_B = (V_B − V_A)x_B + V_A
- Differentiating: d(V/n)/dx_B = V_B − V_A + [terms involving dV_A/dx_B and dV_B/dx_B]
- Using the Gibbs–Duhem equation, the derivative simplifies to: d(V/n)/dx_B = V_B − V_A
- The tangent line at x°_B has slope (V°_B − V°_A) and passes through the point with ordinate (V°_B − V°_A)x°_B + V°_A.
- This line has intercepts V°_A at x_B = 0 and V°_B at x_B = 1.
📈 Molar volume of mixing plot (variant)
An alternative is to plot the molar volume of mixing:
ΔV_m(mix) = ΔV(mix)/n = V/n − x_A V°_A − x_B V°_B
where V°_A and V°_B are the molar volumes of pure A and pure B.
On this plot, the tangent at composition x°_B has intercepts:
- At x_B = 0: V_A − V°_A
- At x_B = 1: V_B − V°_B
This variant directly shows deviations from ideal mixing (where partial molar volumes would equal pure-component molar volumes).
🔍 Don't confuse: partial molar volume vs. molar volume
- Molar volume of pure B (V°_B): volume per mole of pure substance B.
- Partial molar volume of B in a mixture (V_B): volume change per mole of B added to a large amount of mixture at a given composition.
- These are equal only when x_B = 1 (pure B).
- At other compositions, V_B ≠ V°_B due to intermolecular interactions in the mixture.
🌐 General relations for any property and any number of components
🌐 Generalized definitions
For any extensive property X and species i in a mixture:
Partial molar quantity: X_i = (∂X/∂n_i) at constant T, p, n_j≠i
Additivity rule: X = Σ_i n_i X_i
Gibbs–Duhem equation: Σ_i n_i dX_i = 0 (constant T and p)
Equivalently: Σ_i x_i dX_i = 0 (constant T and p)
These apply to mixtures where each species i can be:
- A nonelectrolyte substance
- An electrolyte substance (dissociated into ions)
- An individual ionic species
Important: In the Gibbs–Duhem equation, mole fraction x_i must be based on the species considered present. For aqueous NaCl, you could treat it as {H₂O, NaCl} or as {H₂O, Na⁺, Cl⁻}, but the mole fractions must be consistent with that choice.
🧪 What can and cannot be measured
Can measure experimentally (for uncharged species):
- V_i (partial molar volume)
- C_p,i (partial molar heat capacity)
- S_i (partial molar entropy)
Cannot measure absolute values:
- U_i, H_i, A_i, G_i (partial molar internal energy, enthalpy, Helmholtz energy, Gibbs energy)
- Reason: these involve the internal energy brought into the system by the species, and absolute internal energy cannot be evaluated.
- However, we can measure differences like H_i − H°_i from calorimetric measurements of mixing enthalpies.
- These quantities are still useful in theoretical relations.
⚡ Partial molar quantities of ions (relative values)
For a fully dissociated electrolyte M^(ν₊)X^(ν₋) in aqueous solution:
V_B = ν₊ V₊ + ν₋ V₋
where V₊ and V₋ are the (unmeasurable) partial molar volumes of the cation and anion.
Convention for aqueous solutions:
- Reference ion: H⁺
- Set V∞_H⁺ = 0 (partial molar volume of H⁺ at infinite dilution)
Example chain:
- Measure V∞_HCl = 17.82 cm³/mol
- Then "conventional" V∞_Cl⁻ = V∞_HCl − V∞_H⁺ = 17.82 cm³/mol
- Measure V∞_NaCl = 16.61 cm³/mol
- Then conventional V∞_Na⁺ = V∞_NaCl − V∞_Cl⁻ = 16.61 − 17.82 = −1.21 cm³/mol
These are called "conventional" values because they depend on the arbitrary choice V∞_H⁺ = 0.
🔬 Partial specific quantities
🔬 Definition and use
Partial specific quantity: the partial molar quantity divided by the molar mass.
Example: partial specific volume v_B = V_B / M_B = (∂V/∂m_B) at constant T, p, m_A
where m_A and m_B are masses (not amounts).
Advantage: Can be evaluated without knowing the molar mass.
- Used in sedimentation equilibrium experiments to determine molar mass.
Analogous relations:
- Replace amounts by masses
- Replace mole fractions by mass fractions
- Replace partial molar quantities by partial specific quantities
Example additivity: V = Σ_i m_i v_i
Example Gibbs–Duhem: Σ_i w_i dv_i = 0 (where w_i is mass fraction)
Method of intercepts for binary mixture:
- Plot specific volume v versus mass fraction w_B
- Tangent at composition w°_B has intercepts v_A at w_B = 0 and v_B at w_B = 1
- Variant: plot (v − w_A v°_A − w_B v°_B) versus w_B; intercepts are (v_A − v°_A) and (v_B − v°_B)
⚗️ Chemical potential and equilibrium
⚗️ Definition of chemical potential
Chemical potential μ_i: the partial molar Gibbs energy of species i in a mixture: μ_i = (∂G/∂n_i) at constant T, p, n_j≠i
- If nonexpansion work coordinates exist, hold them constant too.
- The chemical potential is a measure of the escaping tendency of the species from the phase.
- Crucial role in equilibrium problems.
- We cannot determine the absolute value of μ_i, but we can usually evaluate the difference between the value in a given state and a defined reference state.
📝 Gibbs fundamental equation for mixtures
For an open single-phase system with s different nonreacting species, there are 2 + s independent variables (T, p, and n_i for each species).
Gibbs fundamental equation: dG = −S dT + V dp + Σ_i μ_i dn_i
This generalizes the closed-system equation by adding a term for each species to allow composition to vary.
⚡ Chemical potentials of ions (theoretical concept)
Consider aqueous KCl solution. Constituents could be:
- {H₂O, KCl}: amounts can be independently varied in practice
- {H₂O, K⁺, Cl⁻}: amounts cannot be independently varied (must maintain electrical neutrality)
The chemical potential μ_K⁺ is defined as the rate at which G changes with amount of K⁺ added at constant T, p, and amount of Cl⁻.
- This is a hypothetical process in which the net charge increases.
- Therefore, μ_K⁺ is a valid but purely theoretical concept.
Both formulations are valid:
- dG = −S dT + V dp + μ_H₂O dn_H₂O + μ_KCl dn_KCl
- dG = −S dT + V dp + μ_H₂O dn_H₂O + μ_K⁺ dn_K⁺ + μ_Cl⁻ dn_Cl⁻
🔄 Extension to multiphase, multicomponent systems
The excerpt mentions (but does not detail) that the equilibrium derivation from Section 8.1.2 (single substance, multiple phases) extends to systems with:
- Two or more homogeneous phases
- Mixtures of nonreacting species
- No internal partitions preventing transfer
- Negligible gravity and external force fields
The system consists of a reference phase α⁰ and other phases labeled α ≠ α⁰, with species transferable between phases.
(The excerpt ends before completing this derivation.)