1000 Solved Problems in Modern Physics

274 4 Thermodynamics and Statistical Physics

4.31 TakingTandPas independent variables

S=f(T,P)

dS=

(

∂S

∂T

)

P

dT+

(

∂S

∂P

)

T

dP

orTdS=T

(

∂S

∂T

)

P

dT+T

(

∂S

∂P

)

T

dP

=CPdT+T

(

∂S

∂P

)

T

dP

orTdS=CPdT−T

(

∂V

∂T

)

P

dP

=CPdT−TVαdP

4.32 TakingPandVas independent variables,

S=f(P,V)

dS=

(

∂S

∂P

)

V

dP+

(

∂S

∂V

)

P

dV

TdS=T

(

∂S

∂P

)

V

dP+T

(

∂S

∂V

)

P

dV

=T

(

∂S

∂T

)

V

(

∂T

∂P

)

V

dP+T

(

∂S

∂T

)

P

(

∂T

∂V

)

P

dV

=CV

(

∂T

∂P

)

V

dP+CP

(

∂T

∂V

)

P

dV

4.33 In the Joule–Thompson effect heat does not enter the expanding gas, that is
ΔQ=0. The net work done by the external forces on a unit mass of the gas
is (P 1 V 1 −P 2 V 2 ), whereP 1 andP 2 refer to higher and lower pressure across
the plug respectively.
ΔW=P 1 V 1 −P 2 V 2
If the internal energy of unit mass isU 1 andU 2 before and after the gas
passes through the plug
ΔU=U 1 −U 2
By the first law of Thermodynamics
ΔQ= 0 =ΔW+ΔU
or U 2 −U 1 =P 1 V 1 −P 2 V 2
or Δ(U+PV)= 0
or ΔH= 0