116 3 The Second and Third Laws of Thermodynamics: Entropy
VVT(a)(c)TV
(b)TFigure 3.5 Reversible Cycles of Isotherms and Adiabats.(a) A cycle equivalent to
three Carnot cycles. (b) A cycle equivalent to eight Carnot cycles. (c) A cycle equivalent to
a large number of Carnot cycles.Carnot cycles, and Figure 3.5c shows a more complicated cycle that can be divided
into a large number of Carnot cycles. We conclude that the line integral ofdqrev/T
around any path consisting of reversible isotherms and adiabats vanishes.
In order to represent an arbitrary cycle we construct reversible isothermal and adi-
abatic steps that are smaller and smaller in size, until the curve of the arbitrary cycle
is more and more closely approximated by isothermal and adiabatic steps. In the limit
that the sizes of the steps approach zero, any curve is exactly represented and the line
integral ofdqrev/Tvanishes for any cycle. The differentialdSdqrev/Tis therefore
exact andSis a state function. For a simple system containing one substance and one
phase,Smust be a function of three state variables. We can writeSS(T,V,n) (3.2-5)orSS(U,V,n) (3.2-6)and so on. Because we have defined only the differential of the entropy, any constant can
be added to the value of the entropy without any significant change, just as a constant
can be added to the value ofUwithout any significant change.