JCE 1999 (76) 267 [Feb] Maximum Chemical and Physical Hardness


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Home > JCE Print > Journal of Chemical Education > Issues > 1999 > February >

Research: Science and Education

Maximum Chemical and Physical Hardness

Ralph G. Pearson
University of California at Santa Barbara, Department of Chemistry, Santa Barbara, CA 93106

February 1999
Vol. 76 No. 2
p. 267

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Abstract

Density functional theory (DFT) is briefly reviewed, especially concepts such as the electronic chemical potential and the hardness of the electron density function. There is much evidence, and a mathematical proof, that this chemical hardness is a maximum for an equilibrium system. The proof is based on a combination of statistical mechanics, the fluctuation-dissipation theorem, and correlation functions. In MO theory the principle of maximum hardness (PMH) corresponds to a maximum difference in the orbital energies of the HOMO and the LUMO, in most cases. Other kinds of evidence for the PMH are presented, along with some of the consequences. Physical hardness concerns changes in shape and volume of a solid sample. Changes in shape are most important in engineering and materials applications. Changes in volume, however, are more fundamental and easier to visualize. The physical hardness, with respect to volume, is given by BV₀, where B is the bulk modulus and V₀ is the equilibrium molar volume per atom. A table of hardness values for various solids is given. Applying the same proof as for chemical hardness, it is shown that BV₀ is a maximum for the equilibrium system. This principle of maximum physical hardness (PMPH) enables us to calculate the Gruneisen constant and the rate of change of the compressibility with pressure for certain simple solids.

More Information
Citation	Pearson, Ralph G. J. Chem. Educ. 1999 76 267.
Keywords	Physical Chemistry; Theoretical Chemistry; Statistical Mechanics; Solid-State Chemistry; compressibility; fluctuation-dissipation
History	Created: Last Updated:	June 15, 1999 June 22, 2005


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