Localization and quantum-mechanical resonant tunneling in the presence of a time-dependent potential

15 February 1985

journal article
research article
Published by American Physical Society (APS) in Physical Review B

Vol. 31 (4) , 1707-1714
https://doi.org/10.1103/physrevb.31.1707

Abstract

A model for tunneling in the presence of a localized, harmonic time-dependent potential is presented. The effect of dynamic oscillations on the static resonances is determined in two important cases: (1) two consecutive high barriers where resonances arise from potential energy traps, and (2) a sequence of random barriers where resonances arise from disorder-localized states. In both cases strong resonances survive even when the potential varies rapidly compared to the particle’s intrinsic lifetime. Analysis of the two-barrier case reveals an interesting connection to a solvable model of the incommensurate potential problem.

Keywords

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