Epitaxial growth of large-area and highly crystalline anisotropic ReSe atomic layer.

The anisotropic two-dimensional (2D) layered material rhenium disulfide (ReSe) has attracted considerable attention because of its unusual properties and promising applications in electronic and optoelectronic devices. However, because of its low lattice symmetry and interlayer decoupling, anisotropic growth and out-of-plane growth occur easily, yielding thick flakes, dendritic structure, or flower-like structure. In this study, we demonstrated a bottom-up method for the controlled and scalable synthesis of ReSe by van der Waals epitaxy. To achieve controllable growth, a micro-reactor with a confined reaction space was constructed by stacking two mica substrates in the chemical vapor deposition system. Within the confined reaction space, the nucleation density and growth rate of ReSe were significantly reduced, favoring the large-area synthesis of ReSe with a uniform monolayer thickness. The morphological evolution of ReSe with growth temperature indicated that the anisotropic growth was suppressed at a low growth temperature (<600 °C). Field-effect transistors employing the grown ReSe exhibited p-type conduction with a current ON/OFF ratio up to 10 and a hole carrier mobility of 0.98 cm/(V·s). Furthermore, the ReSe device exhibited an outstanding photoresponse to near-infrared light, with responsivity up to 8.4 and 5.1 A/W for 850- and 940-nm light, respectively. This work not only promotes the large-scale application of ReSe in high-performance electronic devices but also clarifies the growth mechanism of low-lattice symmetry 2D materials. [ABSTRACT FROM AUTHOR]