Tuning multiple single-hole spin qubit in silicon above fault tolerant threshol
ORAL
Abstract
Hole-spin qubits hosted by quantum dots in group-IV semiconductors are very promising candidates for large-scale quantum computing. Measuring single hole spin qubit in Si-MOS devices, we have recently demonstrated that they exhibit regions of insensitivity to charge noise called ‘’sweetlines’’. Remarquably, such regions show increased driving efficiency, and exhibit record-breaking Rabi quality factors up to 1200.
Leveraging on the electric dependence of the sweetline position, we present here their alignment in multiple qubits hosted in a natural silicon nanowire device. In this configuration, we performed randomized benchmarking experiments on both qubits individually, achieving fidelities well above 99%, even with qubits living in noisy electric and magnetic environment.
Leveraging on the electric dependence of the sweetline position, we present here their alignment in multiple qubits hosted in a natural silicon nanowire device. In this configuration, we performed randomized benchmarking experiments on both qubits individually, achieving fidelities well above 99%, even with qubits living in noisy electric and magnetic environment.
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Presenters
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Vivien Schmitt
CEA Grenoble
Authors
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Vivien Schmitt
CEA Grenoble
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Marion Bassi
CEA Grenoble, Delft University of Technology, QuTech and Kavli Institute of Nanoscience, Delft University of Technology
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Esteban Rodriguez
CEA Grenoble
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Boris Brun-Barriere
CEA Grenoble
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Simon Zihlmann
CEA Grenoble
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Lorenzo Mauro
CEA Grenoble
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Benoit Bertrand
CEA LETI Grenoble, Université Grenoble Alpes, CEA-Leti, Grenoble, CEA grenoble, CEA Grenoble
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Heimanu Niebojewski
CEA LETI Grenoble, Université Grenoble Alpes, CEA-Leti, Grenoble, CEA grenoble, CEA Grenoble
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Romain Maurand
CEA Grenoble
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Yann-Michel Niquet
CEA Grenoble
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Xavier Jehl
CEA Grenoble
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Silvano De Franceschi
CEA Grenoble