Observation of an Abrupt 3D-2D Morphological Transition in Thin Al Layers Grown by MBE on InGaAs surface

Autor: Elbaroudy, A., Khromets, B., Sfigakis, F., Bergeron, E., Shi, Y., Tam, M. C. A., Blaikie, T., Nichols, George, Baugh, J., Wasilewski, Z. R.
Rok vydání: 2024
Předmět:
Druh dokumentu: Working Paper
DOI: 10.1116/6.0003459
Popis: Among superconductor/semiconductor hybrid structures, in-situ aluminum (Al) grown on InGaAs/InAs is widely pursued for the experimental realization of Majorana Zero Mode quasiparticles. This is due to the high carrier mobility, low effective mass, and large Land\'e g-factor of InAs, coupled with the relatively high value of the in-plane critical magnetic field in thin Al films. However, growing a thin, continuous Al layer using the Molecular Beam Epitaxy (MBE) is challenging due to aluminum's high surface mobility and tendency for 3D nucleation on semiconductor surfaces. A study of epitaxial Al thin film growth on In0.75Ga0.25As with MBE is presented, focusing on the effects of the Al growth rate and substrate temperature on the nucleation of Al layers. We find that for low deposition rates, 0.1 {\AA}/s and 0.5 {\AA}/s, the growth continues in 3D mode during the deposition of the nominal 100 {\AA} of Al, resulting in isolated Al islands. However, for growth rates of 1.5 {\AA}/s and above, the 3D growth mode quickly transitions into island coalescence, leading to a uniform 2D Al layer. Moreover, this transition is very abrupt, happening over an Al flux increase of less than 1%. We discuss the growth mechanisms explaining these observations. The results give new insights into the kinetics of Al deposition and show that with sufficiently high Al flux, a 2D growth on substrates at close to room temperature can be achieved already within the first few Al monolayers. This eliminates the need for complex cryogenic substrate cooling and paves the way for the development of high-quality superconductor-semiconductor interfaces in standard MBE systems.
Comment: The following article has been published in Journal of Vacuum Science & Technology A. DOI: https://doi.org/10.1116/6.0003459
Databáze: arXiv