Nonequilibrium Green's Function simulation of Cu2O photocathodes for photoelectrochemical hydrogen production

Abstract: In this work we present a simulation of the semiconductor electrodes of photoelectrochemical (PEC) water splitting cells based on the nonequilibrium Green's function (NEGF) formalism. While the performance of simple PEC cells can be adequately explained with semi-classical drift-diffusion theory, the increasing interest towards thin film cells and nanostructures in general requires theoretical treatment that can capture the quantum phenomena influencing the charge carrier dynamics in these devices. Specifically, we study a p-type Cu2O electrode and examine the influence of the bias voltage, reaction kinetics and the thickness of the Cu2O layer on the generated photocurrent. The NEGF equations are solved in a self-consistent manner with the electrostatic potential from Poisson's equation, sunlight induced photon scattering and the chemical overpotential required to drive the water splitting reaction. We show that the NEGF simulation accurately reproduces experimental results from both voltammetry and impedance spectroscopy measurements, while providing an energy resolved solution of the charge carrier densities and corresponding currents inside the semiconductor electrode at nanoscale.