Condensed-matter analogs of the Sauter--Schwinger effect

Abstract

The Sauter--Schwinger effect predicts the creation of electron--positron pairs from the vacuum due to a quasiconstant electric field Estrong. The pair-creation yield can be exponentially enhanced without destroying the tunneling-like nature of this mechanism by adding a weaker temporal Sauter pulse Eweak/2(ω t) with ω above a certain threshold ωcrit. In this original form of the so-called dynamically assisted Sauter--Schwinger effect, ωcrit is independent of Eweak Estrong. Via the semiclassical solution (contour integral) of the Riccati equation in 1+1 spacetime dimensions, we find that a Gaussian-shaped pulse Eweak[-(ω t)2] assists tunneling in a similar way but with ωcrit depending on Eweak. This remarkable sensitivity to the pulse shape arises due to the different pole structures of the vector potentials for complex times. We also study dynamical assistance by an oscillation Eweak(ω t) as a model for counterpropagating laser beams and find another dependence ωcrit(Eweak). The largeness of the Schwinger limit EcritQED≈ 1018\,V/m has rendered the observation of this nonperturbative pair-creation mechanism impossible so far. In order to facilitate a better understanding of this effect and its dynamical assistance via experiments, we propose an analog of the many-body Dirac Hamiltonian in direct-bandgap semiconductors. The nonrelativistic Bloch-electron Hamiltonian is restricted to the valence and conduction bands in reciprocal space, which correspond to the two relativistic energy continua. Similar models have been considered before---but mainly for constant external fields. [...]