English

Dynamically assisted tunneling in the impulse regime

Quantum Physics 2021-08-18 v1

Abstract

We study the enhancement of tunneling through a potential barrier V(x)V(x) by a time-dependent electric field with special emphasis on pulse-shaped vector potentials such as Ax(t)=A0/cosh2(ωt)A_x(t)=A_0/\cosh^2(\omega t). In addition to the known effects of pre-acceleration and potential deformation already present in the adiabatic regime, as well as energy mixing in analogy to the Franz-Keldysh effect in the non-adiabatic (impulse) regime, the pulse Ax(t)A_x(t) can enhance tunneling by ``pushing'' part of the wave-function out of the rear end of the barrier. Besides the natural applications in condensed matter and atomic physics, these findings could be relevant for nuclear fusion, where pulses Ax(t)A_x(t) with ω=1 keV\omega=1~\rm keV and peak field strengths of 1016 V/m10^{16}~\rm V/m might enhance tunneling rates significantly.

Keywords

Cite

@article{arxiv.2102.07474,
  title  = {Dynamically assisted tunneling in the impulse regime},
  author = {Christian Kohlfürst and Friedemann Queisser and Ralf Schützhold},
  journal= {arXiv preprint arXiv:2102.07474},
  year   = {2021}
}
R2 v1 2026-06-23T23:09:56.278Z