Exact solution of the Schrodinger equation for photoemission from a metal

TL;DR

This paper rigorously solves the time-dependent Schrödinger equation for electron photoemission from a metal surface under a laser field, revealing complex oscillatory behavior and conditions for photoelectric effect onset.

Contribution

It provides an exact mathematical solution to the Schrödinger equation for this system, including convergence analysis and physical implications for photoemission.

Findings

Surface current exhibits complex oscillations

Convergence to a periodic state occurs at rate t^{-3/2}

Photoelectric effect threshold observed when photon energy exceeds work function

Abstract

We solve rigorously the time dependent Schr\"odinger equation describing electron emission from a metal surface by a laser field perpendicular to the surface. We consider the system to be one-dimensional, with the half-line $x<0$ corresponding to the bulk of the metal and $x>0$ to the vacuum. The laser field is modeled as a classical electric field oscillating with frequency $\omega$, acting only at $x>0$. We consider an initial condition which is a stationary state of the system without a field, and, at time $t=0$, the field is switched on. We prove the existence of a solution $\psi(x,t)$ of the Schr\"odinger equation for $t>0$, and compute the surface current. The current exhibits a complex oscillatory behavior, which is not captured by the "simple" three step scenario. As $t\to\infty$, $\psi(x,t)$ converges with a rate $t^{-\frac32}$ to a time periodic function with period $\frac{2\pi}{\omega}$ which coincides with that found by Faisal, Kami\'nski and Saczuk (Phys Rev A 72, 023412, 2015). However, for realistic values of the parameters, we have found that it can take quite a long time (over 50 laser periods) for the system to converge to its asymptote. Of particular physical importance is the current averaged over a laser period $\frac{2\pi}\omega$, which exhibits a dramatic increase when $\hbar\omega$ becomes larger than the work function of the metal, which is consistent with the original photoelectric effect.