Abstract
Abstract Thin-film ZnS is highly insulating until the applied field rises above approximately 1 MVcm−1. The current then rises almost exponentially with increasing voltage, and current densities in excess of 1 A cm−2 2 can be maintained. If the ZnS is doped with Mn, the resulting efficient electroluminescence provides a means of spatially and temporally mapping the local current density. Device behaviour under both steady-state and non-equilibrium conditions has been investigated including laterally uniform current, filamentary current flow, kinetic electroluminescence and negative-capacitance behaviour. This behaviour is inconsistent with previously reported transport models but can be understood, at least qualitatively, within the framework of the novel high-field transport mechanism proposed. This is based on tunnelling from states within the bandgap and the dynamics of interacting regions of space charge within the ZnS.
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