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Hauptverfasser: Liu, Yang, Wang, Gang, Guan, Shan, Luo, Jun-Wei, Li, Shu-Shen
Format: Preprint
Veröffentlicht: 2025
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Online-Zugang:https://arxiv.org/abs/2511.22066
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author Liu, Yang
Wang, Gang
Guan, Shan
Luo, Jun-Wei
Li, Shu-Shen
author_facet Liu, Yang
Wang, Gang
Guan, Shan
Luo, Jun-Wei
Li, Shu-Shen
contents Regardless of various material design strategies, experimentally achieving substantial and controllable valley splitting in Si/SiGe quantum wells remains a central challenge for ensuring high gate uniformity. This difficulty arises from unavoidable atomic-scale disorder at the interface, caused by alloy randomness, which suppresses valley splitting and, more critically, induces large variations. Here, we demonstrate that CMOS-compatible uniaxial strain can substantially enhance valley splitting, rendering it immune to interface disorder. Atomistic pseudopotential calculations show that uniaxial strain linearly restores the valley splitting suppressed by interfacial disorder, with a large enhancement rate, while keeping disorder-induced variations within a narrow distribution. We reveal that uniaxial strain introduces a new coupling channel between bulk valleys in adjacent Brillouin zones through a small momentum transfer, which markedly reduces the susceptibility of valley splitting to interfacial disorder. These findings establish a viable route to improve gate uniformity in silicon-based spin qubits, paving the way for scalable quantum processors.
format Preprint
id arxiv_https___arxiv_org_abs_2511_22066
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Protected valley splitting against interface disorder toward scalable silicon electron spin qubits
Liu, Yang
Wang, Gang
Guan, Shan
Luo, Jun-Wei
Li, Shu-Shen
Mesoscale and Nanoscale Physics
Regardless of various material design strategies, experimentally achieving substantial and controllable valley splitting in Si/SiGe quantum wells remains a central challenge for ensuring high gate uniformity. This difficulty arises from unavoidable atomic-scale disorder at the interface, caused by alloy randomness, which suppresses valley splitting and, more critically, induces large variations. Here, we demonstrate that CMOS-compatible uniaxial strain can substantially enhance valley splitting, rendering it immune to interface disorder. Atomistic pseudopotential calculations show that uniaxial strain linearly restores the valley splitting suppressed by interfacial disorder, with a large enhancement rate, while keeping disorder-induced variations within a narrow distribution. We reveal that uniaxial strain introduces a new coupling channel between bulk valleys in adjacent Brillouin zones through a small momentum transfer, which markedly reduces the susceptibility of valley splitting to interfacial disorder. These findings establish a viable route to improve gate uniformity in silicon-based spin qubits, paving the way for scalable quantum processors.
title Protected valley splitting against interface disorder toward scalable silicon electron spin qubits
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2511.22066