c03 JWBS043-Rogers September 13, 2010 11:24 Printer Name: Yet to Come
ADIABATIC WORK 51
andp=RT
/
Vso
CVdT+
RT
V
dV=CV
dT
T
+R
dV
V
= 0
SinceCp−CV=R, we obtain
CV
dT
T
+R
dV
V
=
dT
T
+
Cp−CV
CV
dV
V
=
dT
T
+(γ− 1 )
dV
V
= 0
Integrating between limits, with a little algebraic manipulation, yields
TVγ−^1 =k and pVγ=k′
wherekandk′are constant.
The expressionpVγ=k′looks like Boyle’s law except for the parameterγ,
which is always greater than 1. The presence ofγcauses the pressurep=k′/Vγto
be lower at any point during the expansion than it is during the isothermal (Boyle’s
law) expansion (upper curve in Fig. 3.7).
The difference between the two expansions is in the heat that flows or does not flow
into the system to maintainT=const. In the isothermal case heat transfer is allowed.
Heat is not allowed into the system in the adiabatic case wheredq=0 by definition.
Without a compensating heat flow, the adiabatic system cools during expansion and
the pressure is always lower at any specified volume than it is in the isothermal
case (p=k′/Vγ,γ> 1 .0). The entirepVcurve falls below the isothermal curve in
Fig. 3.7.
p
V
V 1 V 2
FIGURE 3.7 Two expansions of an ideal gas. The upper curve is isothermal and the lower
curve is adiabatic. The adiabatic expansion does less work because there is no heat flow into
the system.