Proton conductivity in quasi-one-dimensional hydrogen-bonded systems: Nonlinear approach
- 1 April 1989
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review B
- Vol. 39 (10) , 7161-7173
- https://doi.org/10.1103/physrevb.39.7161
Abstract
Defect formation and transport in a hydrogen-bonded system is studied via a two-sublattice soliton-bearing one-dimensional model. Ionic and orientational defects are associated with distinct nonlinear topological excitations in this model. The dynamics of these excitations are studied both analytically and with the use of numerical simulations. It is shown that the two types of defects are soliton solutions of a double-sine-Gordon equation which describes the motion of the protons in the long-wavelength limit. With each defect there is an associated deformation in the ionic lattice that, for small speeds, follows the defect dynamically albeit resisting its motion. Free propagation as well as collision properties of the proton solitons are presented.Keywords
This publication has 32 references indexed in Scilit:
- Alternative formulation of Davydov’s theory of energy transport in biomolecular systemsPhysical Review A, 1988
- Theoretical aspects of solid hydrogen halides under pressurePhysical Review B, 1987
- Solitons in Molecular SystemsPublished by Springer Nature ,1985
- Solitons and proton motion in ice‐like structuresPhysica Status Solidi (b), 1983
- Theory of hydrogen bonded chains in bioenergeticsThe Journal of Chemical Physics, 1980
- Proton conduction and injection in solidsChemical Reviews, 1975
- Proton Migration in Hydrogen-bonded ChainsNature, 1970
- The Motion of Ions: Principles and ConceptsScience, 1969
- Structure and Properties of IceScience, 1952
- A Theory of Water and Ionic Solution, with Particular Reference to Hydrogen and Hydroxyl IonsThe Journal of Chemical Physics, 1933