# 14.5: Mechanics of Manipulating a Function of State

Given that f(x,y,z) is any *state function* that characterizes the system and (x,y,z) is a set of independent variable properties of that system, we know that any change Δf will be only a function of the value of “f” at the final and initial states,

(14.13)

Since f=f(x,y,z), we can mathematically relate the total differential change (df) to the partial derivatives ,, and of the function, as follows:

(14.14)

where, in general:

the change of f with respect to x, while y and z are unchanged.

If we want to come up with the total change, Δf, of a property (we want to go from 14.14. to 14.13), we integrate the expression in (14.14) to get:

(14.15)

Let us visualize this with an example. For a system of constant composition, its thermodynamic state is completely defined when two properties of the system are fixed. Let us say we have a pure component at a fixed pressure (P) and temperature (T). Hence, all other thermodynamic properties, for example, enthalpy (H), are fixed as well. Since H is only a function of P and T, we write:

(14.16)

and hence, applying 6.2, any differential change in enthalpy can be computed as:

(14.17)

The total change in enthalpy of the pure-component system becomes:

(14.18)

Now we are ready to spell out the* exactness condition*, which is the mathematical condition for a function to be a *state function*. The fact of the matter is, that for a function to be a *state function* — i.e., its integrated path shown in (14.15) is only a function of the end states, as shown in (14.13) — its total differential must be __exact__. In other words, if the total differential shown in (14.14) is exact, then f(x,y,z) is a *state function*. How do we know if a total differential is exact or not?

Given a function Ψ(x,y,z),

(14.19a)

where:

(14.19b)

(14.19c)

(14.19d)

we say that dψ is an __exact differential__ and consequently Ψ(x,y,z) a *state function* if *all* the following conditions are satisfied:

(14.20a)

(14.20b)

(14.20c)

Equations (14.20) are called the **exactness condition.**

### Contributors

Prof. Michael Adewumi (The Pennsylvania State University). Some or all of the content of this module was taken from Penn State's College of Earth and Mineral Sciences' OER Initiative.