Growth Mode Transition in Two-Dimensional GaSe on Three-Dimensional GaN/Sapphire Platform: Implication for Self-Powered Photodetection

This work reports molecular beam epitaxy (MBE) of two-dimensional (2D) GaSe on a three-dimensional (3D) GaN/sapphire platform, which is widely recognized as a potential candidate for electronics and optoelectronic applications. Herein, we have demonstrated that regulating the adatoms' mobility via growth temperature can enable a growth mode transition from screw dislocation-driven (SDD) to layer-by-layer (LBL) in the epitaxy of 2D-GaSe. Typically, the high-density and uniform spiral structure is observed in the SDD-GaSe at low temperatures (<= 500 degrees C), while mu m-scale triangular LBL-GaSe morphology was dominant at high-temperature regime. The diverse optical properties of 2D-GaSe layers under different growth modes were comprehensively investigated, where the unique behaviors of the in-plane propagation (E-1g) Raman mode in the SDD-GaSe as well as the resonant effect in the LBL-GaSe have been reported for the first time. Moreover, a significant blueshift of similar to 0.21 eV in PL spectra of the LBL-GaSe layer with respect to the SDD-GaSe layer is indicated. This opens up the probability for band structure engineering of the 2D-GaSe epitaxial layers by switching the growth mode. Attractively, the LBL-GaSe multilayers exhibited a current density similar to 120 nA/cm(2) at zero bias; thus, it could be an auspicious candidate for self-powered photodetecting applications.