Explanation The reduced variables are t = T T c , p = P P c and v = V V c . Formula used: Write the expression for the van der Waals equation. ( P + a N 2 V 2 ) ( V − N b ) = N k T …… (1) Here, P is the pressure, V is the volume, T is the absolute temperature, N is the number of moles of the gas, a and b are van der Waals constants. Write the expressions for the critical values of volume of a gas. V c = 3 N b Here, V c is critical volume of a gas. Write the expressions for the critical values of temperature of a gas. k T c = 8 a 27 b Here, T c is critical temperature of a gas. Write the expressions for the critical values of pressure of a gas. P c = a 27 b 2 Here, P c is critical pressure. Rearrange expression (1). P = N k T V − N b − a N 2 V 2 Write the expression for Helmholtz free energy. d F = − S d T − P d V + μ d N …… (2) Calculation: Rearrange expression (1) at constant number of molecules N and at constant temperature T , for which d N = d T = 0 . ( ∂ F ∂ V ) T , N = − P Substitute ( N k T V − N b − a N 2 V 2 ) for P in the above expression and rearrange the expression. d F = ∫ ( N k T V − N b − a N 2 V 2 ) d V Integrate both sides of the above expression

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Author: Daniel V. Schroeder

Publisher: Addison Wesley

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Boltzmann statistics of Ideal gas

In statistical mechanics and thermodynamics, Maxwell - Boltzmann statistics explains the statistical distribution of the energies of the classic gas molecules over different states in thermal equilibrium. Maxwell Boltzmann statistics helps us to derive t…

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Chapter 5.3, Problem 54P

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The variation of Helmholtz free energy of a van der Waal fluid.

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