A Summary of Statistical Thermodynamics Calculations

Nov 11, 2006 - Computer-Based Learning; Mathematics/Symbolic Mathemat- ics; Statistical Mechanics; Thermodynamics. Requires: Mathcad 12 or higher...
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JCE SymMath: Symbolic Mathematics in Chemistry

Theresa Julia Zielinski Monmouth University West Long Branch, NJ 07764-1898

A Summary of Statistical Thermodynamic Calculations by Theresa Julia Zielinski, Department of Chemistry, Medical Technology and Physics, Monmouth University, West Long Branch, NJ, 07764;[email protected]. Sidney Young* File Names: stat_thermo12.mcd and stat_thermo12.pdf Keywords: Upper-Division Undergraduate; Physical Chemistry; Computer-Based Learning; Mathematics/Symbolic Mathematics; Statistical Mechanics; Thermodynamics

the 1997 “Workshop for Integration of Numerical Methods into the Undergraduate Physical Chemistry Curriculum Using the Mathcad Software” at the University of South Alabama, Mobile, Alabama. *Sid Young died in 2004 after a long illness. He was a beloved teacher and a leader in the development and use of Mathcad as a tool to promote student learning in physical chemistry. A memorial to him was established by the University of South Alabama ACS Student Affiliate; see http://www.southalabama.edu/acs/ memorial.html (accessed Sep 2006).

Requires: Mathcad 12 or higher

In this document students can explore the full set of statistical thermodynamic calculations leading to the prediction of the heat capacity at constant volume from the translational, rotational, vibrational, and electronic partition functions. The document is heavily annotated to permit independent study or review of the concepts. Some questions in the document help students to focus on the chemical concepts while others focus on the mathematical methods. The document demonstrates using the symbolic derivation feature of Mathcad by a derivation of the vibrational contribution to the heat capacity of a molecule. An extension of the calculation of the thermodynamic properties of a molecule is made to predict the equilibrium constant of the dissociation of N2. The document concludes with the study of the NO molecule, which has a low lying electronic energy level. A mastery exercise is included for students to use to extend their understanding. This document was completed during

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Heat capacity at constant volume for NO as a function of T ( as i K). Cv(i K) is the total heat capacity (solid line); Cvv(i K) is the vibrational component of the heat capacity (dotted line); Cve is the electronic heat capacity component (dot-dash line).

Vol. 83 No. 11 November 2006



Journal of Chemical Education

1727