Mesoscopic Difference of Hydrogen Double Minimum Well in Proton Irradiated Ferroelectric System
POSTER
Abstract
We investigate the microscopic structure of hydrogen double-well potentials in a hydrogen-bonded ferroelectric system exposed to radioactive particles of
hydrogen-ion beams. The hydrogen-bonded system is ubiquitous, forming the base of organic-inorganic materials and the double-helix structure of DNA
inside biological materials. In order to determine the difference of microscopic environments, an atomic-scale level analysis of solid-state 1H high-resolution
nuclear magnetic resonance (NMR) spectra were performed. The hydrogen environments of inorganic systems represent the Morse potentials and wave
function of the eigen-state and eigen-state energy derived from the Schrodinger equation. The wave functions for the real space of the localized
hydrogen derived from the approximated solutions in view of the atomic scale by using quantum mechanics are manifested by a difference in the charge-density
distribution.
hydrogen-ion beams. The hydrogen-bonded system is ubiquitous, forming the base of organic-inorganic materials and the double-helix structure of DNA
inside biological materials. In order to determine the difference of microscopic environments, an atomic-scale level analysis of solid-state 1H high-resolution
nuclear magnetic resonance (NMR) spectra were performed. The hydrogen environments of inorganic systems represent the Morse potentials and wave
function of the eigen-state and eigen-state energy derived from the Schrodinger equation. The wave functions for the real space of the localized
hydrogen derived from the approximated solutions in view of the atomic scale by using quantum mechanics are manifested by a difference in the charge-density
distribution.
Presenters
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Se-Hun Kim
Jeju National University
Authors
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Se-Hun Kim
Jeju National University