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formulas:maxwell_relations

Maxwell Relations

Intuitive

Explanations in this section should contain no formulas, but instead colloquial things like you would hear them during a coffee break or at a cocktail party.

Concrete

Derivation

The Maxwell relations follow directly from the fact that partial derivatives commute: $\partial_x \partial_y = \partial_y \partial_x$.

If we have some function $U(S,V)$ (called the internal energy) that depends on the entropy $S$ and the volume $V$, the total change of it is given by

$$ dU = \frac{\partial U}{\partial S} \big |_V dS + \frac{\partial U}{\partial V} \big |_S dV, $$

where $\big |_V$ means that we keep $V$ fixed.

Then, we introduce two definitions:

$$ \frac{\partial U}{\partial S} \big |_V \equiv T , \quad -\frac{\partial U}{\partial V} \big |_S \equiv P.$$

The minus sign here is just a convention and can be understood as follows: The internal energy usually gets smaller when we increase the volume. Thus, if we want to work with positive pressure $P$ in most situations, we need to include the minus sign here.

Using these definitions equation reads

$$ dU = T dS - P dV, $$

which is the fundamental thermodynamic relation.

Next, we use that partial derivative commute:

$$ \frac{\partial^2 U}{\partial V\partial S} = \frac{\partial^2 U}{\partial S\partial V} $$

and put in our two definitions from above:

$$ \frac{\partial T}{\partial S} \big |_V = -\frac{\partial P}{\partial V}\big |_S $$

This is one of the Maxwell relations.

The other Maxwell relations follow completely analogous, but with different functions instead of the internal energy $U$.

For example, if we start with the Helmholtz free energy $A(T,V)$:

$$ A = U -TS $$

and follow exactly the same steps ($dA= dU-d(TS) = (Tds-PdV)-(SdT+TdS)=-SdT-PdV$), we can derive

$$ \frac{\partial S}{\partial V} \big |_T = \frac{\partial P}{\partial T} \big |_V $$

The other Maxwell relations follow by starting with the enthalpy $H(S,P)$ or the Gibbs free energy $G(T,P)$.

(These notions appear, since:

  • a system with fixed entropy and volume will choose the state with minimum internal energy $U$,
  • a system with fixed temperature and volume will choose the state with minimum enthalpy $H$,
  • a system with fixed entropy and pressure will choose the state with minimum Helmholtz free energy $A$,
  • a system with fixed temperature and pressure will choose the state with minimum Gibbs free energy $G$.)

For a great explanation, why the Maxwell relations are "just a sneaky way of saying that the mixed partial derivatives of the function U commute". see https://johncarlosbaez.wordpress.com/2012/01/19/classical-mechanics-versus-thermodynamics-part-1/

(The fact that partial derivatives commute is known as Schwarz' theorem (see https://en.wikipedia.org/wiki/Maxwell_relations . Schwarz' theorem is simply a way of stating "the fact that a function S doesn’t change when we go around a parallelogram" https://johncarlosbaez.wordpress.com/2012/01/23/classical-mechanics-versus-thermodynamics-part-2/)

Abstract

The motto in this section is: the higher the level of abstraction, the better.

Why is it interesting?

The Maxwell relations encode useful relationships between notions of thermodynamics.

formulas/maxwell_relations.txt · Last modified: 2018/12/19 11:01 by jakobadmin