Two-dimensional electron gases in Ga-face and N-face AlGaN/GaN heterostructures grown by plasma-induced molecular beam epitaxy and metalorganic chemical vapor deposition on sapphire

Abstract

We report on the growth of nominally undoped ${\mathrm{GaN/Al}}_x{\mathrm{Ga}}_{\text{1−x}}\mathrm{N/GaN}$ $\text{(x<0.4)}$ high mobility heterostructures with N-face or Ga-face polarity on sapphire substrates by plasma-induced molecular beam epitaxy (PIMBE) and metalorganic chemical vapor deposition in order to study the formation and electrical transport properties of polarization induced two-dimensional electron gases (2DEGs). By depositing a thin AlN nucleation layer on the sapphire substrates before the growth of a GaN buffer layer by PIMBE, we were able to change the polarity of the wurtzite films from N to Ga face. The switch in the polarity causes a change in the sign of the spontaneous and piezoelectric polarization directed along the c axis of the strained AlGaN barrier. As a consequence the polarization induced 2DEG is confined at different interfaces in heterostructures with different polarities. The transport properties of the 2DEGs in Ga- and N-face heterostructures were investigated by a combination of capacitance–voltage profiling, Hall effect, and Shubnikov-de Haas measurements. Dominant electron scattering mechanisms are studied in order to provide the knowledge necessary for further improvements of the electron transport properties and performance of AlGaN/GaN based “normal” (based on Ga-face heterostructures) and “inverted” (based on N-face heterostructures) high electron mobility transistors.