Epitaxial Growth of 1D Atomic Chain Based Se Nanoplates on Monolayer ReS 2 for High‐Performance Photodetectors

Mixed‐dimensional (0D, 1D, and 3D) heterostructures based on 2D layered materials have been proven as a promising candidate for future nanoelectronics and optoelectronics applications. In this work, it is demonstrated that 1D atomic chain based Se nanoplates (NPs) can be epitaxially grown on monolayer ReS 2 by a chemical transport reaction, thereby creating an interesting mixed‐dimensional Se/ReS 2 heterostructure. A unique epitaxial relationship is observed with the (110) planes of the Se NPs parallel to the corresponding ReS 2 (010) planes. Experimental and theoretical studies reveal that the Se NPs could conjugate with underlying monolayer ReS 2 via strong chemical hybridization at heterointerface, which is expected to originate from the intrinsic defects of ReS 2 . Remarkably, photodetectors based on Se/ReS 2 heterostructures exhibit ultrahigh detectivity of up to 8 × 10 12 Jones, and also show a fast response time of less than 10 ms. These results illustrate the great advantage of directly integrated 1D Se based nanostructure on planar semiconducting ReS 2 films for optoelectronic applications. It opens up a feasible way to obtain mixed‐dimensional heterostructures with atomic interfacial contact by epitaxial growth.