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5: Thermodynamics

  • Page ID
    456058
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    Among the many capabilities of chemistry is its ability to predict if a process will occur under specified conditions. Thermodynamics, the study of relationships between the energy and work associated with chemical and physical processes, provides this predictive ability. Previous chapters in this text have described various applications of thermochemistry, an important aspect of thermodynamics concerned with the heat flow accompanying chemical reactions and phase transitions. This chapter will introduce additional thermodynamic concepts, including those that enable the prediction of any chemical or physical changes under a given set of conditions.

    • 5.1: Introduction
    • 5.2: Spontaneity
      Chemical and physical processes have a natural tendency to occur in one direction under certain conditions. A spontaneous process occurs without the need for a continual input of energy from some external source, while a nonspontaneous process requires such. Systems undergoing a spontaneous process may or may not experience a gain or loss of energy, but they will experience a change in the way matter and/or energy is distributed within the system.
    • 5.3: Entropy
      Entropy (S) is a state function that can be related to the number of microstates for a system (the number of ways the system can be arranged) and to the ratio of reversible heat to kelvin temperature. It may be interpreted as a measure of the dispersal or distribution of matter and/or energy in a system, and it is often described as representing the “disorder” of the system. For a given substance, \(S_{solid} < S_{liquid} < S_{gas}\) in a given physical state at a given temperature.
    • 5.4: The Second and Third Laws of Thermodynamics
      The second law of thermodynamics states spontaneous processes increases the entropy of the universe, \(S_{univ} > 0\). If \(ΔS_{univ} < 0\), the process is nonspontaneous, and if \(ΔS_{univ} = 0\_, the system is at equilibrium. The third law of thermodynamics establishes the zero for entropy at 0 for a perfect, pure crystalline solid at 0 K with only one possible microstate. The standard entropy change for a process is computed standard entropy values for the species involved.
    • 5.5: Free Energy
      Gibbs free energy (G) is a state function defined with regard to system quantities only and may be used to predict the spontaneity of a process. A negative value for ΔG indicates a spontaneous process; a positive ΔG indicates a nonspontaneous process; and a ΔG of zero indicates that the system is at equilibrium. A number of approaches to the computation of free energy changes are possible.
    • 5.6: Key Terms
    • 5.7: Key Equations
    • 5.8: Summary
    • 5.9: Exercises
      These are homework exercises to accompany the Textmap created for "Chemistry" by OpenStax.


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