Applied-field effects on molecular switches
- 25 May 1998
- journal article
- Published by IOP Publishing in Journal of Physics: Condensed Matter
- Vol. 10 (20) , 4423-4434
- https://doi.org/10.1088/0953-8984/10/20/010
Abstract
Electron transmission through an electrified composite metal-doped polymer-metal system is investigated by means of the Lippmann-Schwinger equation. The electric field, applied via the metal leads, acts across the polymer chain containing the single-impurity atom, which behaves as a molecular switch. The Stark-ladder effect in the doped polymer is described by utilizing the recursive-Green-function (RGF) approach, where repeated use of the Dyson equation gives rise to a continued-fraction form of the RGF, which can be expressed analytically as a ratio of Bessel functions. Molecular switch control of the transmission is achieved by adjusting the parameters characterizing the impurity. The influence of the applied field on the transmission process is discussed.Keywords
This publication has 23 references indexed in Scilit:
- Many-neighbor treatment of molecular-switch transmissionChemical Physics Letters, 1996
- Transmission of double-impurity atomic switchesPhysical Review B, 1996
- Tight-binding study of interaction time in molecular switchesPhysical Review B, 1996
- Transmission properties of molecular switches in semiconducting polymersPhysical Review B, 1994
- Modulated barrier approach to the interaction time in tunneling for arbitrary potentialsPhysical Review A, 1993
- Electronic transmission coefficient for the single-impurity problem in the scattering-matrix approachPhysical Review B, 1988
- Field-effect transistor with polythiophene thin filmSynthetic Metals, 1987
- Electrical Conductivity in Doped PolyacetylenePhysical Review Letters, 1977
- Molecular rectifiersChemical Physics Letters, 1974
- Linear crystal energy bands via the many-neighbour approximationChemical Physics Letters, 1969