Prove that ∆H = CP∆T
Answers
Answer:
From the equation q = n C ∆T, we can say:
At constant pressure P, we have
qP = n CP∆T
This value is equal to the change in enthalpy, that is,
qP = n CP∆T = ∆H
Similarly, at constant volume V, we have
qV = n CV∆T
This value is equal to the change in internal energy, that is,
qV = n CV∆T = ∆U
We know that for one mole (n=1) of an ideal gas,
∆H = ∆U + ∆(pV ) = ∆U + ∆(RT) = ∆U + R ∆T
Therefore, ∆H = ∆U + R ∆T
Substituting the values of ∆H and ∆U from above in the former equation,
CP∆T = CV∆T + R ∆T
CP = CV + R
CP – CV = R
Explanation:
The formula q = n C ∆T represents the heat q required to bring about a ∆T difference in temperature of one mole of any matter. The constant C here is called the molar heat capacity of the body. Thus, the molar heat capacity of any substance is defined as the amount of heat energy required to change the temperature of 1 mole of that substance by 1 unit. It depends on the nature, size, and composition of the system.
In this article, we will discuss two types of molar heat capacity – CP and CV and derive a relationship between Cp and Cv.