c03 JWBS043-Rogers September 13, 2010 11:24 Printer Name: Yet to Come
38 THE THERMODYNAMICS OF SIMPLE SYSTEMS
First
Path
Second
Path
T
p
1 10
290
310
A
B
FIGURE 3.1 Different path transformations from A to B.
The work done on the system in the first compression (lower horizontal) is
w=−
∫V 2
V 1
pdV=−
∫V 2
V 1
RT
V
dV=−
∫V 2
V 1
RT
dV
V
=−RTln
V 2
V 1
=−RTln 0. 100 =− 8 .314(290) ln 0. 100 =5552 J
The work done in the heating step (rightmost vertical) is isobaric withp=10.0 bar:
w=p(V 2 −V 1 )= 10 .0 (266. 0 − 244 .1)=219 J
so the total over the first path is 5771 J.
Over the second path, the leftmost vertical givesw= 1 .00(2660−2441)=219 J;
thus the two isobaric steps require the same work into the system. The isothermal
compressions are not the same. The topmost horizontal is
−RTln 0. 100 =− 8 .314(320) ln 0. 100 =6126 J
so the total work done over the second path is obviously not the same as by the first
path. The difference is 574 J.
3.2.1 Hey, Let’s Make a Perpetual Motion Machine!
Let’s run the thermodynamic system in Fig. 3.1 around a cycle such that the transfor-
mation over the second path runs backwards; that is, the top horizontal is an expansion
instead of a compression and the leftmost step is a temperature decrease. The first
path remains as before.