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Phase/current information descriptors and equilibrium states in molecules
Author(s) -
Nalewajski Roman F.
Publication year - 2015
Publication title -
international journal of quantum chemistry
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.484
H-Index - 105
eISSN - 1097-461X
pISSN - 0020-7608
DOI - 10.1002/qua.24750
Subject(s) - statistical physics , antisymmetric relation , quantum , degrees of freedom (physics and chemistry) , entropy (arrow of time) , quantum mechanics , physics , mathematics , mathematical physics
Quantum‐generalized entropic descriptors of the complex electronic states and their information distances are reexamined and applied to the phase‐equilibria in molecules. The relation between densities of the ordinary Fisher and Shannon measures of information content is used in determining their supplements due to phases/currents. These nonclassical terms complement the familiar classical (probability) functionals of information theory in the resultant information descriptors. The nonclassical Shannon entropy measures the average magnitude of the system phase distribution, while the current term in the related Fisher measure accounts for the gradient content of the state phase. The density constrained (vertical) and unconstrained (horizontal) equilibria in molecules are distinguished. The consistency requirement that the extreme entropic principles in terms of both these resultant measures have common solutions calls for the modified, negative sign of the nonclassical Fisher indeterminicity term. The equilibrium criteria are shown to give rise to the unitary phase‐transformation of molecular states in a “thermodynamic” representation of quantum‐mechanical description. Possible applications of this generalized description are discussed and thermodynamical analogies are commented upon. A separation of the density (modulus) and current (phase) factors of general many‐electron states is effected using the Harriman–Zumbach–Maschke construction of antisymmetric states yielding the specified electron density. A phenomenological description of molecular subsystems is outlined, which accounts for both the density and phase degrees‐of‐freedom of electronic states, and the current promotion of molecular fragments is explored. © 2014 Wiley Periodicals, Inc.