Statistical Thermodynamics and Spectroscopy

kirjoittanut Wolfgang Schärtl
( 0 )
92 pages
This book discusses the connection of classical thermodynamics and the quantum chemical description of matter, in three chapters: statistical thermodynamics, optical spectroscopy, and group theory.
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Wolfgang Schaertl studied Chemistry at Mainz University, Germany, and received his PhD in Physical Chemistry. As a post-doc, he joined the Hashimoto ERATO Polymer Phasing Project in Kyoto/Japan. Afterwards he came back to Mainz University to Manfred Schmidt’s group as a research fellow, wh

Classical thermodynamics provides a phenomenological approach towards energy transfer, phase equilibria and chemical equilibria. As a macroscopic approach, it is not related to the microscopic properties of matter (atoms, molecules). These microscopic properties of matter, on the other hand, have to be described using quantum chemistry. Here, statistical thermodynamics provides the connection between the macroscopic physicochemical quantities addressed in classical thermodynamics, and the microscopic quantum chemical description of matter. To calculate the properties of molecules as predicted by quantum chemistry, on the other hand, we need certain input parameters such as the chemical bond strengths or chemical bond lengths, quantities which can experimentally be determined by optical spectroscopy. This booklet tries to provide an overview on this topic, organized in three separate chapters: statistical thermodynamics, optical spectroscopy, and group theory/symmetry analysis.

  1. Statistical thermodynamics
    1. The Boltzmann statistics
    2. Calculation of molecular partition functions
    3. The molecular partition function and macroscopic thermodynamic properties
    4. Heat capacities of gases, and characteristic temperatures
    5. Statistical thermodynamics and chemical equilibrium
  2. Optical spectroscopy
    1. Mathematical background – complex numbers
    2. Principles of spectroscopy
    3. Quantum mechanical treatment of spectroscopy
    4. Optical spectroscopic methods
  3. Group theory
    1. C2v – a simple example to introduce the concept
    2. The point group C3v
    3. Td
    4. Group theory and excitation of molecular electronic transitions, e.g. C2v