c03 JWBS043-Rogers September 13, 2010 11:24 Printer Name: Yet to Come
44 THE THERMODYNAMICS OF SIMPLE SYSTEMS
for an ideal gas. We can also define anadiabaticprocess, which is a perfectly insulated
process. Before doing so, we shall need the concept of heat capacity.
3.7 HEAT CAPACITY
When heatqis put into a system its temperature rises. The change in temperature is
proportional to the amount of heat
q=CT
whereCis a proportionality constant.Cdepends on both the nature of, say, a chemical
substance and the amount taken; it is an extensive property (Section 1.6).Cis really
a parameter because it is different for different substances. It is common experience
that metals heat up faster over a flame than does water. They have differentcapacities
to absorbheat; hence the parameterCis called theheat capacity.
To use calculus in working with the heat capacity, it is necessary to replace the ap-
proximate macroscopic observationC=q/Twith the infinitesimalC=dq/dT.
Furthermore, we chemists carry our ordinary bench reactions under conditions of
constant (atmospheric) pressure, and thermochemists carry out combustion reactions
inside a closed bomb. The heat capacity under constant volume conditions is not
exactly the same as the heat capacity under constant pressure conditions, so we
distinguish between the two heat capacitiesCVandCpas
CV=
(
∂q
∂T
)
V
and Cp=
(
∂q
∂T
)
p
The infinitesimals in the heat capacity equations are partials because each parameter
is defined holding eitherVorpconstant.
3.8 ENERGY AND ENTHALPY
Having stipulated constant volume for the first of the heat capacity expressions, the
workpdVdisappears for a system that can do only work of expansiondVagainst a
pressurep
dU=dq+pdV
Consequently,
CV≡
(
∂q
∂T
)
V
=
(
∂U
∂T
)
V