CHAP. 3: FUNDAMENTALS OF THERMODYNAMICS [CONTENTS] 93
The volumeV 1 is often chosen as large as would allow for a system in its initial state to behave
as an ideal gas. In the limitV 1 → ∞at a constant amount of substance, equation (3.68)
rearranges to
U(T, V) =U◦(T 1 ) +
∫TT 1CV◦(T) dT+∫V∞[
T(
∂p
∂T)V−p]
dV. (3.69)If the volume is constant, equation (3.68) simplifies to
U(T, V) =U(T 1 , V) +
∫TT 1CV(T, V) dT , [V]. (3.70)For an isothermal process, equation (3.68) becomes
U(T, V) =U(T, V 1 ) +
∫VV 1[
T(
∂p
∂T)V−p]
dV , [T]. (3.71)3.5.2.2 Ideal gas.
For an ideal gas, the partial derivative of internal energy with respect to volume is zero, as
follows from (3.55) [see also the example in section3.4.5]. The internal energy of an ideal gas
is thus a function of temperature only (isothermal processes in an ideal gas are processes at
constant internal energy). Equation (3.70) for an ideal gas is
U◦(T) =U◦(T 1 ) +
∫TT 1CV◦(T)dT. (3.72)3.5.2.3 Changes at phase transitions
The changes of internal energy during a crystalline transformation, melting and boiling (∆crystU,∆fusU
and ∆vapU) are calculated as follows
∆U = ∆H−p∆V , [T, p], (3.73)where ∆Hand ∆V are changes of enthalpy and volume at the respective phase transition.