Ultraclean two-dimensional hole systems with mobilities exceeding 107 cm2/Vs
Abstract
Owing to their large effective mass, strong and tunable spin-orbit coupling, and complex band-structure, two-dimensional hole systems (2DHSs) in GaAs quantum wells provide rich platforms to probe exotic many-body physics, while also offering potential applications in ballistic and spintronics devices, and fault-tolerant topological quantum computing. We present here a systematic study of molecular-beam-epitaxy grown, modulation-doped, GaAs (001) 2DHSs where we explore the limits of low-temperature 2DHS mobility by optimizing two parameters, the GaAs quantum well width and the alloy fraction (x) of the flanking AlxGa1-xAs barriers. We obtain a breakthrough in 2DHS mobility, with a peak value 18 × 106 cm2/Vs at a density of 3.8 × 1010 /cm2, implying a mean-free-path of 57 μm. Using transport calculations tailored to our structures, we analyze the operating scattering mechanisms to explain the non-monotonic evolution of mobility with density. We find it imperative to include the dependence of effective mass on 2DHS density, well width, and x. We observe concomitant improvement in quality as evinced by the appearance of delicate fractional quantum Hall states at very low density.
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