Plasma-deposited aluminum-doped ZnO (ZnO:Al) demonstrated a resistivity gradient as function of the film thickness, extending up to about 600nm. This gradient decreased sharply when the ZnO:Al was capped by a hydrogenated amorphous silicon layer (a-Si:H) and subsequently treated according to the solid phase crystallization procedure at 600C. The resistivity reduced from 1.2 ·x  10-1 to 2.6 ·x  10-3Ω cm for a film thickness of 130nm, while for thicker films the decrease in resistivity was less pronounced, i.e., a factor of 2 for a film thickness of 810 nm. While the carrier concentration was not affected, the mobility significantly increased from 7 to 30cm2/V s for the thick ZnO:Al layers. This increase was ascribed to the passivation of grain boundary defects by hydrogen, which diffused from the a-Si:H toward the ZnO:Al during the solid phase crystallization procedure. The passivation effect was more pronounced in thinner ZnO:Al layers, characterized by a smaller grain size, due to the presence of large grain boundaries. For thicker films with grain sizes up to 200-300nm the mobility became progressively less affected by the presence of grain boundaries. Therefore, the hydrogen-induced improvement in conductivity was less significant for the thick ZnO:Al films.

Improved Conductivity of Aluminum-Doped ZnO: the Effect of Hydrogen Diffusion from a Hydrogenated Amorphous Silicon Capping Layer. Ponomarev, M.V., Sharma, K., Verheijen, M.A., van de Sanden, M.C.M., Creatore, M.: Journal of Applied Physics, 2012, 111[6], 063715