Chemical reactivity dynamics and quantum chaos in highly excited hydrogen atoms in an external field: a quantum potential approach

Chattaraj, P. K. ; Maiti, B. (2002) Chemical reactivity dynamics and quantum chaos in highly excited hydrogen atoms in an external field: a quantum potential approach International Journal of Molecular Sciences, 3 (4). pp. 338-359. ISSN 1422-0067

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Official URL: http://www.mdpi.com/1422-0067/3/4/338

Related URL: http://dx.doi.org/10.3390/i3040338

Abstract

Dynamical behavior of chemical reactivity indices like electronegativity, hardness, polarizability, electrophilicity and nucleophilicity indices is studied within a quantum fluid density functional framework for the interactions of a hydrogen atom in its ground electronic state (n = 1) and an excited electronic state (n = 20) with monochromatic and bichromatic laser pulses. Time dependent analogues of various electronic structure principles like the principles of electronegativity equalization, maximum hardness, minimum polarizability and maximum entropy have been found to be operative. Insights into the variation of intensities of the generated higher order harmonics on the color of the external laser field are obtained. The quantum signature of chaos in hydrogen atom has been studied using a quantum theory of motion and quantum fluid dynamics. A hydrogen atom in the electronic ground state (n = 1) and in an excited electronic state ( n = 20) behaves differently when placed in external oscillating monochromatic and bichromatic electric fields. Temporal evolutions of Shannon entropy, quantum Lyapunov exponent and Kolmogorov - Sinai entropy defined in terms of the distance between two initially close Bohmian trajectories for these two cases show marked differences. It appears that a larger uncertainty product and a smaller hardness value signal a chaotic behavior.

Item Type:Article
Source:Copyright of this article belongs to Molecular Diversity Preservation International.
Keywords:Chemical Reactivity; Electronegativity; Hardness; Hydrogen Atom; Quantum Theory of Motion(QTM); Quantum Chaos; Quantum Fluid Dynamics(QFD); Chaotic Dynamics
ID Code:71226
Deposited On:24 Nov 2011 08:38
Last Modified:24 Nov 2011 08:38

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