📝 SummarXiv

Abstract

Mg is currently the only p-type dopant in technological use in GaN. Its incorporation into the GaN lattice is difficult. It requires a thermal treatment that only partially activates the Mg. To achieve moderate p-type doping requires high doses of Mg that mostly remain inactive. High p-type doping is thus typically achieved at the cost of certain lattice distortion and the creation of defects. Using low-temperature surface photovoltage spectroscopy, we obtain a wide spectrum of optical transitions within the bandgap of Mg-doped GaN. The results reveal an optical transition from the valence band into a deep trap around 0.49 eV above the valence band, along with what appears to be a complimentary transition from the same trap into the conduction band observed at 2.84 eV (coinciding with the energy of the famous Mg-related GaN blue luminescence). The similar shape of the spectra, their complimentary energies within the GaN gap and their opposite nature (hole vs. electron trap) appear to be more than a coincidence suggesting that this is an Mg-related surface state. The density of charge we calculate for this surface state is about 2x10^12 cm-2. We suggest that these small amounts of surface-segregated Mg partially oxidize during the growth and further oxidize during the consecutive Mg-activation heat treatment. This minute quantity of oxidized surface Mg should be about enough to form an Mg-related surface state. Etching the GaN with HCl is shown to affect the photovoltage at the blue-luminescence-related energy. Finally, we show that pure MgO powder produces the same blue luminescence even at the absolute absence of GaN.