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Main Authors: Mauro, Lorenzo, Rodriguez, Mauricio J., Rodriguez-Mena, Esteban A., Niquet, Yann-Michel
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.04977
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author Mauro, Lorenzo
Rodriguez, Mauricio J.
Rodriguez-Mena, Esteban A.
Niquet, Yann-Michel
author_facet Mauro, Lorenzo
Rodriguez, Mauricio J.
Rodriguez-Mena, Esteban A.
Niquet, Yann-Michel
contents Strained germanium heterostructures are one of the most promising material for hole spin qubits but suffer from the strong anisotropy of the gyromagnetic factors that hinders the optimization of the magnetic field orientation. The figures of merit (Rabi frequencies, lifetimes...) can indeed vary by an order of magnitude within a few degrees around the heterostructure plane. We propose to address this issue by confining the holes at the interface of an unstrained, bulk Ge substrate or thick buffer. We model such structures and show that the gyromagnetic anisotropy is indeed considerably reduced. In addition, the Rabi frequencies and quality factors can be significantly improved with respect to strained heterostructures. This extends the operational range of the qubits and shall ease the scale-up to many-qubit systems.
format Preprint
id arxiv_https___arxiv_org_abs_2506_04977
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Hole spin qubits in unstrained Germanium layers
Mauro, Lorenzo
Rodriguez, Mauricio J.
Rodriguez-Mena, Esteban A.
Niquet, Yann-Michel
Mesoscale and Nanoscale Physics
Strained germanium heterostructures are one of the most promising material for hole spin qubits but suffer from the strong anisotropy of the gyromagnetic factors that hinders the optimization of the magnetic field orientation. The figures of merit (Rabi frequencies, lifetimes...) can indeed vary by an order of magnitude within a few degrees around the heterostructure plane. We propose to address this issue by confining the holes at the interface of an unstrained, bulk Ge substrate or thick buffer. We model such structures and show that the gyromagnetic anisotropy is indeed considerably reduced. In addition, the Rabi frequencies and quality factors can be significantly improved with respect to strained heterostructures. This extends the operational range of the qubits and shall ease the scale-up to many-qubit systems.
title Hole spin qubits in unstrained Germanium layers
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2506.04977