254 4 Thermodynamics and Statistical Physics
4.30 Obtain the followingTdsequation
Tds=CVdT+TαETdV
where ET =−V
(∂P
∂V)
T is the isothermal elasticity andα =1
V(∂V
∂T)
P
is the volume coefficient of expansion,Sis the entropy andTthe Kelvin
temperature.4.31 Obtain the equation
Tds=CpdT−TVαdp
4.32 Obtain the equation
Tds=CV(
∂T
∂P
)
VdP+CP(
∂T
∂V
)
PdV4.33 Obtain the formula for the Joule–Thompson effect
ΔT=[T(∂V/∂T)P−V]ΔP
CP
4.34 (a) Show that for a perfect gas governed by the equation of statePV=RT
the Joule-Thompson effect does not take place.
(b) Show that for an imperfect gas governed by the equation of state
(
P+
a
V^2)
(V−b)=RT, the Joule-Thompson effect is given by
ΔT=1
CP
(
2 a
RT−b)
ΔP.
4.35 Explain graphically the condition for realizing cooling in the Joule-Thompson
effect using the concept of the inversion temperature.
4.36 Prove that for any substance the ratio of the adiabatic and isothermal elastici-
ties is equal to the ratio of the two specific heats.
4.37 Prove that the ratio of the adiabatic to the isobaric pressure coefficient of
expansion is 1/(1−γ).
4.38 Show that the ratio of the adiabatic to the isochoric pressure coefficient is
γ/(γ−1).
4.39 IfUis the internal energy then show that for an ideal gas(∂U/∂V)T=0.
[Nagarjuna University 2004]
4.40 Find the change in boiling point when the pressure on water at 100◦Cis
increased by 2 atmospheres. (L =540 Calg−^1 , volume of 1 g of steam=
1 ,677 cc)
[Nagarjuna University 2000]
4.41 If 1 g of water freezes into ice, the change in its specific volume is 0.091 cc
Calculate the pressure required to be applied to freeze 10 g of water at− 1 ◦C.
[Sri Venkateswara University 1999]