Atomically Thin Decoration Layers for Robust Orientation Control of 2D Transition Metal Dichalcogenides

2D semiconducting transition metal dichalcogenides (TMDs) are emerging as promising candidates in the pursuit of advancing semiconductor technology. One major challenge for integrating 2D TMD materials into practical applications is developing an epitaxial technique with robust reproducibility for single-oriented growth and thus single-crystal growth. Here, the growth of single-orientated MoS2 on c-plane sapphire with atomically thin Fe2O3 decoration layers under various growth conditions is demonstrated. The statistical data highlight robust reproducibility, achieving a single orientation ratio of up to 99%. Density functional theory calculations suggest that MoS2 favors a 0 degrees alignment ([112 over bar 0]//[112 over bar 0]$[ {11\bar{2}0} ]//\ [ {11\bar{2}0} ]$) on the Fe2O3 (0001) surface. This preference ensures single-oriented growth, even on mirror-reflected exposed surfaces which typically lead to antiparallel domains. Subsequent optical and electrical analyses confirm the uniformity and undoped nature of MoS2 on Fe2O3-decorated sapphire, showing its quality is comparable to MoS2 grown on bared sapphires. The results underscore the potential of Fe2O3-decorated sapphire as an effective substrate for the consistent and high-quality epitaxial growth of 2D TMDs, illuminating the pathway to epitaxial control of 2D TMD orientation through strategic modulation of crystalline atomic surfaces. Transition metal dichalcogenides face challenges of applications in advancing semiconductors. This work demonstrates robust reproducibility in the growth of single-oriented MoS2 on Fe2O3-decorated sapphire, achieving a remarkable 99% ratio. Simulations reveal a preferred 0 degrees alignment on the Fe2O3-(0001) surface, ensuring single-oriented growth even on mirror-reflected surfaces. These findings highlight Fe2O3-decorated sapphires as effective substrates, enabling epitaxial control of TMD orientation.image