2.1 Work and the State of a System 45
Solution
We first convert the equation of state to an expression in terms ofT,V, andninstead ofT
andVm:P
nRT
V
+
n^2 RTB 2
V^2wrev∫cPdV−nRT∫V 2V 11
V
dV+n^2 RTB 2∫V 2V 11
V^2dV−nRTln(
V 2
V 1)
+n^2 RTB 2(
1
V 2−
1
V 1)−nRTln(
Vm,2
Vm,1)
+nRTB 2(
1
Vm,2
−1
Vm,1)
(2.1-15)Exercise 2.1
a.Calculate the work done in the reversible expansion of 100.00 g of CO 2 from a volume of
10.000 L to a volume of 50.00 L at a constant temperature of 25.00◦C. Use the truncated
virial equation of state of Example 2.3. The second virial coefficient of CO 2 is equal to
−128 cm^3 mol−^1 at this temperature.
b.Recalculate the work done in the process of part a, assuming CO 2 to be an ideal gas.Work and Irreversible Processes
All real processes with nonzero rates are irreversible. If we knowP(transmitted) we
can writedwirrev−P(transmitted)dV (2.1-16)for a simple system. We cannot discuss irreversible processes in a general way, since
P(transmitted) can differ from the equilibrium pressure in complicated ways. However,
there are some processes for which we can obtain an adequate approximation for
P(transmitted).Constant-Pressure Processes
In some chemical reactions and some phase changes the system is open to the
atmosphere andPextis equal to the barometric pressure, which is nearly constant.
In this case we can assume thatP(transmitted) is equal toPextand toP. We can
writew−∫
PextdV−Pext∆V−P∆V (constant-pressure process) (2.1-17)where “constant-pressure” means not only that the pressure is constant, but also that
it is equal toP(transmitted) and toPext. This equation is valid for both increases and