- #1
Kori Smith
- 3
- 0
Hello! I understand what specific heats are and how to derive them. I just feel that I'm missing a little something in the methodology.
Consider the 1st law of thermodynamics and the definition of enthalpy:
1) dU = δQ -δW = δQ - PdV
2) H = Q - VP
For the derivation of CV, dV = 0 and the relationship becomes
(∂U/∂T)V = (∂Q/∂T)V = CV
For the derivation of CP, something happens that I don't quite understand. Sources I've found say that the incremental form of the enthalpy relation is given as
3) dH = δQ - VdP
since dP = 0, it becomes
(∂U/∂T)P = (∂Q/∂T)P = CP
but why do we write it like this? Wouldn't the chain rule for differentiation apply to d(VP) s.t. it becomes
d(VP) = VdP + PdV
in which case, where does the PdV component in EQ (3) go? Thanks ahead of time for the clarification!
Consider the 1st law of thermodynamics and the definition of enthalpy:
1) dU = δQ -δW = δQ - PdV
2) H = Q - VP
For the derivation of CV, dV = 0 and the relationship becomes
(∂U/∂T)V = (∂Q/∂T)V = CV
For the derivation of CP, something happens that I don't quite understand. Sources I've found say that the incremental form of the enthalpy relation is given as
3) dH = δQ - VdP
since dP = 0, it becomes
(∂U/∂T)P = (∂Q/∂T)P = CP
but why do we write it like this? Wouldn't the chain rule for differentiation apply to d(VP) s.t. it becomes
d(VP) = VdP + PdV
in which case, where does the PdV component in EQ (3) go? Thanks ahead of time for the clarification!
