A Gibbs and Helmholtz Free Energies We have energy dU = TdS-PdV, which is not useful since we can’t hold S constant very easily so it would be more.

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Presentation transcript:

A

Gibbs and Helmholtz Free Energies

We have energy dU = TdS-PdV, which is not useful since we can’t hold S constant very easily so it would be more useful to have a different energy expression that depends on V and T rather than V and S. To obtain this we find the desired varible, T = (dU/dS)V. T is the conjugate variable of S in the dU equation. The Legendre transform of the dU equation is dA = -SdT-PdV. This is arrived at from A = U – TS and dA = dU – TdS –SdT. Start with is dA = -SdT-PdV, that depends on V and T. Use P as the conjugate variable to V. Define G = A + PV, and dG = dA +VdP + PdV = -SdT+VdP and G =PV -ST.

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From the definitions of Cp and Cv and the chain rule: