Related papers: Low-energy subband wave-functions and effective $g$-factor of one-dimensional hole gas

Low-energy subband wave-functions and effective $g$-factor of one-dimensional hole gas

URL: http://arxiv.org/abs/2103.13541v3
Date: Sun, 8 May 2022 00:46:50 GMT
Title: Low-energy subband wave-functions and effective $g$-factor of one-dimensional hole gas
Authors: Rui Li
Abstract summary: One-dimensional (1D) hole gas confined in a cylindrical Ge nanowire has potential applications in quantum information technologies. We analytically study the low-energy properties of this 1D hole gas.
Score: 2.696926374562295
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: One-dimensional (1D) hole gas confined in a cylindrical Ge nanowire has potential applications in quantum information technologies. Here, we analytically study the low-energy properties of this 1D hole gas. The subbands of the hole gas are two-fold degenerate. The low-energy subband wave-functions are obtained exactly, and the degenerate pairs are related to each other via a combination of the time-reversal and the spin-rotation transformations. In evaluating the effective $g$-factor of these low-energy subbands, the orbital effects of the magnetic field are shown to contribute as strongly as the Zeeman term. Also, near the center of the $k_{z}$ space, there is a sharp dip or a sharp peak in the effective $g$-factor. At the site $k_{z}=0$, the longitudinal $g$-factor $g_{l}$ is much less than the transverse $g$-factor $g_{t}$ for the lowest subband, while away from the site $k_{z}=0$, $g_{l}$ can be comparable to $g_{t}$.

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