Direct atomic layer deposition of ultra-thin Al2O3 and HfO2 films on gold-supported monolayer MoS2

Abstract

In this paper, the atomic layer deposition (ALD) of ultra-thin films (<4 nm) of Al2O3 and HfO2 on Au-supported monolayer (1L) MoS2 is investigated, providing an insight on the nucleation mechanisms in the early stages of the ALD process. A preliminary multiscale characterization of large area 1L-MoS2 exfoliated on sputter-grown Au/Ni films revealed an almost conformal MoS2 membrane with the Au topography and the occurrence of strain variations at the nanoscale. Ab-initio DFT calculations of MoS2/Au(111) interface showed a significant influence of the Au substrate on the MoS2 energy band structure, whereas small differences were accounted for the adsorption of the H2O, TMA and TDMAHf precursors. This suggests a crucial role of nanoscale morphological effects, such as local curvature and strain of the MoS2 membrane, in the enhanced physisorption of the precursors. Therefore, the nucleation and growth of Al2O3 and HfO2 films onto 1L-MoS2/Au was investigated, by monitoring the surface coverage as a function of the number (N) of ALD cycles, with N from 10 to 120. At low N values, a slower growth rate of the initially formed nuclei was observed for HfO2, probably due to the bulky nature of the TDMAHf precursor as compared to TMA. On the other hand, the formation of continuous films was obtained in both cases for N>80 ALD cycles, corresponding to 3.6 nm Al2O3 and 3.1 nm HfO2. Current mapping by C-AFM showed, for the same applied bias, a uniform insulating behavior of Al2O3 and the occurrence of few localized breakdown spots in the case of HfO2, associated to less compact films regions. Finally, an increase of the 1L-MoS2 tensile strain was observed by Raman mapping after encapsulation with both high-k films, accompanied by a reduction in the PL intensity.