Physical Review Research (Aug 2021)
Dynamically assisted tunneling in the impulse regime
Abstract
We study the enhancement of tunneling through a potential barrier V(x) by a time-dependent electric field with special emphasis on pulse-shaped vector potentials such as A_{x}(t)=A_{0}/cosh^{2}(ωt). In addition to the known effects of preacceleration and potential deformation already present in the adiabatic regime, as well as energy mixing in analogy to the Franz-Keldysh effect in the nonadiabatic (impulse) regime, the pulse A_{x}(t) can enhance tunneling by “pushing” part of the wave function out of the rear end of the barrier. Aside from the natural applications in condensed matter and atomic physics, these findings could be relevant for nuclear fusion, where pulses A_{x}(t) with ω=1keV and peak field strengths of 10^{16}V/m might enhance tunneling rates significantly.