Electrical properties and emission mechanisms of Zn-doped β-Ga2O3 films

Abstract

We study the electrical properties and emission mechanisms of Zn-doped β-Ga2O3 film grown by pulsed laser deposition through Hall effect and cathodoluminescence which consist of ultraviolet luminescence (UV), blue luminescence (BL) and green luminescence (GL) bands. The Hall effect measurements indicate that the carrier concentration increases from 7.16×1011 to 6.35×1012cm−3 with increasing a nominal Zn content from 3 to 7at%. The UV band at 272nm is not attributed to Zn dopants and ascribed as radiative electron transition from conduction band to a self-trapped hole while the BL band is attributable to defect level related to Zn dopant. The BL band has two emission peaks at 415 and 455nm, which are ascribed to the radiative electron transition from oxygen vacancy (VO) to valence band and recombination of a donor–acceptor pair (DAP) between VO donor and Zn on Ga site (ZnGa) acceptor, respectively. The GL band is attributed to the phonon replicas’ emission of the DAP. The acceptor level of ZnGa is estimated to be 0.26eV above the valence band maximum. The transmittance and absorption spectra prove that the Zn-doped β-Ga2O3 film is a dominantly direct bandgap material. The results of Hall and cathodoluminescence measurements imply that the Zn dopant in β-Ga2O3 film will form an acceptor ZnGa to produce p-type conductivity.