Tuning the workfunction of ZnO through surface doping with Mn from first-principles simulations

Surface doping of ZnO allows for the tailoring of the surface chemistry of the material while preserving the superb electronic structure of the bulk. Apart from obvious changes in adsorption energies and activation energies for catalysis, surface doping can alter the workfunction of the material and allow it to be tuned for specific photocatalytic and optoelectronic applications. We present first-principles electronic structure calculations for surface doping of Mn on the ZnO (0001) surface. Various dopant concentrations have been considered at the outmost (surface) layer of Zn atoms, while the interior of the material is kept at the ideal wurtzite structure. For each system, the surface energy and surface workfunction have been calculated. Both workfunction and surface energy drop with increasing Mn concentration for O-terminated surfaces, while more complex behaviour is observed in metal-terminated ones. We discuss trends in surface stability and surface electronic structure of this material and how they affect its properties.

Automated summary

Surface doping of ZnO can alter the surface chemistry of the material and tune the workfunction for specific photocatalytic and optoelectronic applications. The changes in workfunction and surface energy with increasing dopant concentration vary for different surface terminations.