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Thermodynamic Equilibrium in Systems with Other Constraints

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Chemical Thermodynamics

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Abstract

The four postulates enable to perform many equilibrium calculations, but they rely on isolated and isentropic (adiabatic) conditions. These conditions are not suitable in many circumstances to do calculations easily. This chapter shows how to derive energy-like potential functions that largely facilitate calculations in systems at constant pressure, constant temperature, or constant pressure and temperature. The respective potentials enthalpy, free energy, and the Gibbs potential are introduced by reformulating the problem of equilibrium within isenthalpic conditions. (The mathematical method of Legendre transformation is explained in the Appendix.) Using these energy-like potential functions, an overview of the equilibrium conditions in terms of extremum principles within different conditions is given, along with the formal relationships concerning the potential functions and their variables. The possibility of calculation of heat and volume work from these functions accompanying changes at different conditions is treated in detail. Based on the machinery of formal relations, the determination of entropy and the energy-like potential functions from measurable quantities such as compressibility, heat capacity, and the coefficient of thermal expansion is demonstrated. It is also shown in detail, how all thermodynamic quantities can be calculated from a particular fundamental equation. At the end of the chapter, a concise treatment of the equations of state of real gases, liquids, and solids is provided, along with a detailed explanation of using fugacity to calculate the chemical potential.

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Notes

  1. 1.

    Enthalpy has a Greek origin, similar to energy. The ancient Greek noun ενεργεια [energeia] means actively used power, or work done. It is derived from the word εργον [ergon] = work, action. In a similar way, the coined Greek word ενθαλπεια [enthalpeia] can be derived from the word θαλπος [thalposz] = warming effect. It refers to the heat absorbed.

  2. 2.

    The name comes from the German freie Energie (free energy). It also has another name, Helmholtz potential, to honor Hermann Ludwig Ferdinand von Helmholtz (1821–1894), a German physician and physicist. Apart from F, it is denoted sometimes by A, the first letter of the German word Arbeit = work, referring to the available useful work of a system.

  3. 3.

    The name free enthalpy (rarely used in English) can be derived from enthalpy the same way as free energy is derived from energy. (See footnote 2 of this Chapter.) Usual names are Gibbs function, Gibbs energy, and Gibbs potential to honor Josiah Willard Gibbs (1839–1903), an American physicist who had a significant contribution to the development of thermodynamics. The alternative name Gibbs free energy is rarely used to avoid confusion with the (Helmholtz) free energy F.

  4. 4.

    Z is also called compressibility factor, but it is easy to mistake for the compressibility defined in (4.31).

  5. 5.

    The name of the virial equation and the virial coefficients comes from the Latin noun vis = force (whose stem can change to vir). It refers to the fact that the reason for deviations from the ideal gas equation is due to interaction forces between molecules.

Further Reading

  • Atkins P, de Paula J (2009) Physical chemistry, 9th edn. Oxford University Press, Oxford

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  • Callen HB (1985) Thermodynamics and an introduction to thermostatistics, 2nd edn. Wiley, New York

    Google Scholar 

  • Denbigh KG (1981) The principles of chemical equilibrium, 4th edn. Cambridge University Press, Cambridge

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  • Guggenheim EA (1985) Thermodynamics: an advanced treatment for chemists and physicists, 7th edn. North Holland, Amsterdam

    Google Scholar 

  • Moore WJ (1998) Physical chemistry, 4th edn. Prentice-Hall, Indianapolis, IN

    Google Scholar 

  • Silbey LJ, Alberty RA, Moungi GB (2004) Physical chemistry, 4th edn. Wiley, New York

    Google Scholar 

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Authors and Affiliations

  1. Dept. Physical Chemistry Lab. Chemical Kinetics, Eötvös Loránd University (ELTE), Budapest, Hungary

    Dr. Ernő Keszei

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  1. Dr. Ernő Keszei
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Correspondence to Ernő Keszei .

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© 2012 Springer-Verlag Berlin Heidelberg

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Keszei, E. (2012). Thermodynamic Equilibrium in Systems with Other Constraints. In: Chemical Thermodynamics. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-19864-9_4

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