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Main Authors: Ungerer, Jann H., Pally, Alessia, Bosco, Stefano, Kononov, Artem, Sarmah, Deepankar, Lehmann, Sebastian, Thelander, Claes, Maisi, Ville F., Scarlino, Pasquale, Loss, Daniel, Baumgartner, Andreas, Schönenberger, Christian
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2405.10796
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author Ungerer, Jann H.
Pally, Alessia
Bosco, Stefano
Kononov, Artem
Sarmah, Deepankar
Lehmann, Sebastian
Thelander, Claes
Maisi, Ville F.
Scarlino, Pasquale
Loss, Daniel
Baumgartner, Andreas
Schönenberger, Christian
author_facet Ungerer, Jann H.
Pally, Alessia
Bosco, Stefano
Kononov, Artem
Sarmah, Deepankar
Lehmann, Sebastian
Thelander, Claes
Maisi, Ville F.
Scarlino, Pasquale
Loss, Daniel
Baumgartner, Andreas
Schönenberger, Christian
contents Qubits require a compromise between operation speed and coherence. Here, we demonstrate a compromise-free singlet-triplet (ST) qubit, where the qubit couples maximally to the driving field while simultaneously coupling minimally to the dominant noise sources. The qubit is implemented in a crystal-phase defined double-quantum dot in an InAs nanowire. Using a superconducting resonator, we measure the spin-orbit interaction (SOI) gap, the spin-photon coupling strength and the qubit decoherence rate as a function of the in-plane magnetic-field orientation. We demonstrate a spin qubit sweet spot maximizing the dipolar coupling and simultaneously minimizing the decoherence. Our theoretical description postulates phonons as the most likely dominant noise source. The compromise-free sweet spot originates from the SOI suggesting that it is not restricted to this material platform, but might find applications in any material with SOI. These findings pave the way for enhanced engineering of these nanomaterials for next-generation qubit technologies.
format Preprint
id arxiv_https___arxiv_org_abs_2405_10796
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A coherence sweet spot with enhanced dipolar coupling
Ungerer, Jann H.
Pally, Alessia
Bosco, Stefano
Kononov, Artem
Sarmah, Deepankar
Lehmann, Sebastian
Thelander, Claes
Maisi, Ville F.
Scarlino, Pasquale
Loss, Daniel
Baumgartner, Andreas
Schönenberger, Christian
Mesoscale and Nanoscale Physics
Materials Science
Quantum Physics
Qubits require a compromise between operation speed and coherence. Here, we demonstrate a compromise-free singlet-triplet (ST) qubit, where the qubit couples maximally to the driving field while simultaneously coupling minimally to the dominant noise sources. The qubit is implemented in a crystal-phase defined double-quantum dot in an InAs nanowire. Using a superconducting resonator, we measure the spin-orbit interaction (SOI) gap, the spin-photon coupling strength and the qubit decoherence rate as a function of the in-plane magnetic-field orientation. We demonstrate a spin qubit sweet spot maximizing the dipolar coupling and simultaneously minimizing the decoherence. Our theoretical description postulates phonons as the most likely dominant noise source. The compromise-free sweet spot originates from the SOI suggesting that it is not restricted to this material platform, but might find applications in any material with SOI. These findings pave the way for enhanced engineering of these nanomaterials for next-generation qubit technologies.
title A coherence sweet spot with enhanced dipolar coupling
topic Mesoscale and Nanoscale Physics
Materials Science
Quantum Physics
url https://arxiv.org/abs/2405.10796