Thermodynamics of Multicomponent Systems

Multicomponent systems and composition variables

A closed system with variable composition can, under some changing conditions, behave in much the same way as an open system. Here “closed” does not mean absolutely isolated; it only means that total matter is conserved.

• A closed system with variable composition can be treated analogously to an open system.

State description for a variable-composition system:

• Extensive variables: $V = (T, p, n_B, n_C)$, giving a total of $k + 2$ variables.
  • These are the mole numbers of each substance together with temperature and pressure.
• Intensive variables: $\rho = \rho(T, p, x_B, x_C)$, giving a total of $k + 1$ variables.
  • Since these are relative amounts, one variable is effectively removed.

Partial molar quantities

Definition

• These describe how a thermodynamic quantity changes when the mole number of a component changes.
• Because the definition is based on mole number, partial molar quantities are associated with extensive properties.
• A partial molar quantity is itself a state function, so its value no longer depends directly on the total amount $n$.
• Common examples:

$$V_B=\left( \frac{\partial V}{\partial n_B} \right)_{T,p,b_C}\qquad V=\sum_{B}n_{B}V_{B}$$

$$U_B=(\frac{\partial U}{\partial n_B})_{T,p,b_C}\qquad U=\sum_{B}n_{B}U_{B}$$

$$H_B=(\frac{\partial H}{\partial n_H})_{T,p,b_C}\qquad H=\sum_{B}n_{B}H_{B}$$

$$F_B=(\frac{\partial F}{\partial n_B})_{T,p,b_C}\qquad F=\sum_{B}n_{B}F_{B}$$

$$S_B=(\frac{\partial S}{\partial n_B})_{T,p,b_C}\qquad S=\sum_{B}n_{B}S_{B}$$

$$G_B=(\frac{\partial G}{\partial n_B})_{T,p,b_C}\qquad G=\sum_{B}n_{B}G_{B}$$

• The same relations between thermodynamic functions for pure substances or fixed-composition systems also hold for partial molar quantities:
  • $H_B = U_B + pV_B$
  • $F_B = U_B - TS_B$
  • $G_B = H_B - TS_B = U_B + pV_B - TS_B = F_B + pV_B$
  • In other words, the usual thermodynamic identities still hold on a per-mole basis.

Additive formula

The sum over all components gives the total quantity:

• $\sum n_B V_B = V$

Gibbs-Duhem formula

If we differentiate a state description with respect to $T$, $p$, and the component amounts, we obtain:

$$dV=(\frac{\partial V}{\partial T})_{p,n_B,n_C,\dots}dT+(\frac{\partial V}{\partial p})_{T,b_B,n_C,\dots}dp+\sum V_Bdn_B$$

Chemical potential

Definition

The chemical potential is the partial derivative of $G$ with respect to $n$. Since Gibbs free energy combines the system’s internal energy with its capacity to do useful work on the surroundings, it is especially useful when describing chemical reactions and phase changes.

$$\mu_B=(\frac{\partial G}{\partial n_B})_{T,p,b_C,\dots}$$

• Similar to other partial molar quantities, it satisfies the same general formal properties.

• To be honest, some textbook discussions around it feel more verbose than enlightening.

• The absolute value of $\mu_B$ depends on the chosen reference, which is why it is called a potential.

• Combining it with the basic thermodynamic identities gives:

  • $\mu=(\frac{\partial U}{\partial n_{B}})_{S,V,n_{c},\cdots}$
  • $\mu=(\frac{\partial H}{\partial n_{B}})_{S,p,n_{c},\cdots}$
  • $\mu=(\frac{\partial H}{\partial n_{B}})_{T,V,n_{c},\cdots}$

• Under different constraints, the chemical potential may be written as:

$$\mu_B=(\frac{\partial G}{\partial n_B})_{T,p,n_C,\dots}$$

$$\mu_B=(\frac{\partial U}{\partial n_B})_{S,V,n_C,\dots}$$

$$\mu_B=(\frac{\partial H}{\partial n_B})_{S,p,n_C,\dots}$$

$$\mu_B=(\frac{\partial F}{\partial n_B})_{T,V,n_C,\dots}$$

Dependence on temperature and pressure

$$\mu_{B}=f(T,p,x_{B},x_{C},\cdots)$$

For the simpler case $\mu_B = f(T, p)$:

• Dependence on $T$:

$$(\frac{\partial \mu}{\partial T})_{p,n_{B},n_{C},\cdots}=[\frac{\partial}{\partial T}(\frac{\partial G}{\partial n_{B}})_{T,p,n_{C},\cdots}]_{p,n_{B},n_{C}}$$

$$\qquad \qquad \qquad \qquad=[\frac{\partial}{\partial n_{B}}(\frac{\partial G}{\partial T})_{p,n_{B},n_{C},\cdots}]_{T,p,n_{C},\cdots}$$

$$\qquad \quad=[\frac{\partial(-S)}{\partial n_{B}}]_{T,p,n_{C},\cdots}$$

$$T \uparrow, \mu_{B}\downarrow$$

• Dependence on $p$:

$$(\frac{\partial \mu}{\partial p})_{T,n_{B},n_{C},\cdots}=[\frac{\partial}{\partial p}(\frac{\partial G}{\partial n_{B}})_{T,p,n_{C},\cdots}]_{p,n_{B},n_{C}}$$

$$\qquad \qquad \qquad \qquad=[\frac{\partial}{\partial n_{B}}(\frac{\partial G}{\partial p})_{T,n_{B},n_{C},\cdots}]_{T,p,n_{C},\cdots}$$

$$\qquad \quad=[\frac{\partial(V)}{\partial n_{B}}]_{T,p,n_{C},\cdots}$$

$$T \uparrow, \mu_{B}\uparrow$$

• Note: this uses relations such as
  • $V=(\frac{\partial G}{\partial p})_{T}=(\frac{\partial G}{\partial p})_{S}$
  • $S=-(\frac{\partial F}{\partial T})_{V}=-(\frac{\partial G}{\partial T})_{p}$

Criterion based on chemical potential

• For a system of fixed composition at constant $T$ and $p$, with $W' = 0$:

$$dG_{T,p,W'=0}\le 0$$

• For a multicomponent homogeneous system:

$$dG=-SdT+Vdp+\sum\mu_{B}dn_{B}$$

• Therefore, under constant $T$ and $p$ with $W' = 0$, the criterion for direction and limit of a process is:

$$\sum\mu_{B}dn_{B}\le 0$$

• In short, the conclusion is still the same: check whether $dG \le 0$.