Solution‐Growth Strategy for Large‐Scale “CuGaO2 Nanoplate/ZnS Microsphere” Heterostructure Arrays with Enhanced UV Adsorption and Optoelectronic Properties

Intrinsically p‐type conductivity and a wide bandgap of ≈3.6 V endow inorganic delafossite CuGaO₂ with great promise for fabricating high‐performance UV photodetectors. Nevertheless, CuGaO₂‐based optoelectronic devices hindered because the intrinsic direct transitions are symmetry forbidden in CuGaO₂. This study reports a large‐area synthesis of “CuGaO₂ nanoplate/ZnS microsphere” heterostructure arrays using a facile solution‐based strategy associated with an oil/water interfacial self‐assembly approach. It is found that a large number of ZnS microspheres with a polycrystalline structure grow on the top surface of CuGaO₂ hexagonal platelets through Ostwald ripening mechanism, forming high‐density p–n heterojunctions. A parabolic dependence between the size of ZnS microsphere and the growth time is confirmed in this growth. The UV light adsorption of the heterostructure CuGaO₂/ZnS thin film is two times higher than that of the pristine CuGaO₂ thin film. Furthermore, the as‐designed “CuGaO₂ nanoplate/ZnS microsphere” heterostructure arrays exhibit enhanced photoresponse properties. This work offers a new insight into the rational design of optoelectronic devices from the synergetic effect of p‐type 2D nanoplates as well as n‐type nanostructures such as ZnS, ZnO, CdS, and CdO.