Tuning hydrogen adsorption on pure and doped ZnO (000 1 ¯) surfaces by a simple electron counting model

Hydrogen (H) adsorption strengths on oxygen-terminated (000 1 ¯) surfaces of pure and doped wurtzite ZnO are investigated under varying H surface coverage conditions. Consistent with the prediction of the classical electron counting rules, a 1 2 monolayer (ML) of adsorbed H changes the electronic structure of pure ZnO (000 1 ¯) surface from metallic to semiconductor state by saturating unpaired electrons of surface oxygen atoms. This closed-shell electron configuration of the ZnO (000 1 ¯) surface significantly reduces the adsorption strengths of subsequent H atoms, making the dissociative adsorption of a H 2 molecule endothermic. We apply a simple electron counting model to predict and tune the coverage-dependent H adsorption strengths on general polar semiconductor surfaces. This model is confirmed by our investigations of H adsorption on (000 1 ¯) surfaces of ZnO with a series of dopant elements (Na, Mg, Al, Ti, Fe, Sn, etc.). It can also be applied to H adsorption on other similar polar semiconductors...