Synthesis and transport properties of epitaxial Bi (0001) films on GaAs (111) substrates

Abstract: In recent decades, the growth of ultrathin epitaxial bismuth (Bi) films on various substrates has garnered interest due to their topological, thermoelectric, and even ferroelectric properties. We report upon the growth and transport properties of epitaxial Bi (0001) films in the thickness range of 5-32 nm deposited directly on GaAs (111) substrates, without a buffer layer. The quality of Bi films are found to depend on conditions for substrate treatment using Ar+ ion-milling and annealing. Substrates milled at low ion beam currents display poor surface reconstruction after annealing, which hinders the growth of high-quality films. In contrast, substrates milled under optimized conditions led to reconstructed surfaces upon annealing, resulting in epitaxial Bi films with predominantly single-domain orientation. Although epitaxial films formed in both cases, transport measurements indicated significantly higher conductivity for films grown on optimally treated substrates. Measurements at low temperatures suggest that the transport properties are dominated by a surface state. Magneto-transport measurements suggest that conductivity and mobility improve progressively with increasing film thickness. Remarkably, our 5 nm Bi film demonstrated resilience to ambient conditions without oxidation, with transport properties similar to those of bilayer Bi films grown by confinement heteroepitaxy in other studies. These results provide a robust methodology for growing high-quality epitaxial Bi films on GaAs (111) and offer insights into their unique transport properties.