JCE 1998 (75) 1341 [Oct] Naphthalene and Azulene I: Semimicro Bomb Calorimetry and Quantum Mechanical Calculations


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Home > JCE Print > Journal of Chemical Education > Issues > 1998 > October >

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Naphthalene and Azulene I: Semimicro Bomb Calorimetry and Quantum Mechanical Calculations

Carl Salter
Department of Chemistry, Moravian College, Bethlehem, PA 18018

James B. Foresman
Physical Sciences Department, York College of Pennsylvania, York, PA 17405

October 1998
Vol. 75 No. 10
p. 1341

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Abstract

A novel H₂O physical chemistry experiment is proposed in which the heats of combustion of naphthalene and azulene are measured using bomb calorimetry, and then the energy difference between the two molecules is computed using Gaussian 94W. Azulene is an expensive hydrocarbon ($100/gram); semimicro bomb calorimetry using the Parr 1425 makes the experiment possible using just 0.1 grams of azulene. The experimental difference obtained by students using this apparatus was -34 kcal/mole (azulene - naphthalene); the literature value is -32 kcal/mole. Using the B3LYP/6-31G(D)//RHF/6-31G(D) level of theory we compute an energy difference of -32 kcal/mole; the literature value for the gas-phase energy difference between azulene and naphthalene is -35±2 kcal/mole. Thus this experiment demonstrates that excellent agreement can be obtained between experiment and modern methods of computational chemistry.

More Information
Citation	Salter, Carl; Foresman, James B. J. Chem. Educ. 1998 75 1341.
Keywords	physical chem, computational chem, thermodynamics, calorimetry, bonding theory
History	Created: Last Updated:	June 21, 1999 June 24, 2005


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