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Auteurs principaux: Vaartjes, Arjen, Su, Rocky Yue, O'Neill, Laura A., Steinacker, Paul, Goenka, Gauri, van Blankenstein, Mark R., Yu, Xi, Wilhelm, Benjamin, Jakob, Alexander M., Hudson, Fay E., Itoh, Kohei M., Yang, Chih Hwan, Dzurak, Andrew S., Jamieson, David N., Nurizzo, Martin, Holmes, Danielle, Laucht, Arne, Morello, Andrea
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2511.10978
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author Vaartjes, Arjen
Su, Rocky Yue
O'Neill, Laura A.
Steinacker, Paul
Goenka, Gauri
van Blankenstein, Mark R.
Yu, Xi
Wilhelm, Benjamin
Jakob, Alexander M.
Hudson, Fay E.
Itoh, Kohei M.
Yang, Chih Hwan
Dzurak, Andrew S.
Jamieson, David N.
Nurizzo, Martin
Holmes, Danielle
Laucht, Arne
Morello, Andrea
author_facet Vaartjes, Arjen
Su, Rocky Yue
O'Neill, Laura A.
Steinacker, Paul
Goenka, Gauri
van Blankenstein, Mark R.
Yu, Xi
Wilhelm, Benjamin
Jakob, Alexander M.
Hudson, Fay E.
Itoh, Kohei M.
Yang, Chih Hwan
Dzurak, Andrew S.
Jamieson, David N.
Nurizzo, Martin
Holmes, Danielle
Laucht, Arne
Morello, Andrea
contents Quantum error correction (QEC) requires non-invasive measurements for fault tolerant quantum computing. Deviations from ideal quantum non-demolition (QND) measurements can disturb the encoded information. To address this challenge, we develop a readout protocol for a $D-$dimensional system that, after a single positive outcome, switches to probing only the $D{-}1$ remaining subspace. This adaptive switching strategy minimizes measurement-induced errors by relying on negative-result measurement results that do not perturb the Hamiltonian. We apply the protocol on an 8-dimensional $^{123}{\rm Sb}$ nuclear qudit in silicon, and achieve an increase in the readout fidelity from $(98.93\pm0.07)\%$ to $(99.61\pm0.04)\%$, while reducing threefold the overall readout time. To highlight the broader relevance of measurement-induced errors, we study a 10-dimensional $^{73}{\rm Ge}$ nuclear spin read out through Pauli spin blockade, revealing nuclear spin flips arising from hyperfine and quadrupole interactions. These results unveil the effect of non-ideal QND readout across diverse platforms, and introduce an efficient readout protocol that can be implemented with minimal FPGA logic on existing hardware.
format Preprint
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institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Maximizing the nondemolition nature of a quantum measurement via an adaptive readout protocol
Vaartjes, Arjen
Su, Rocky Yue
O'Neill, Laura A.
Steinacker, Paul
Goenka, Gauri
van Blankenstein, Mark R.
Yu, Xi
Wilhelm, Benjamin
Jakob, Alexander M.
Hudson, Fay E.
Itoh, Kohei M.
Yang, Chih Hwan
Dzurak, Andrew S.
Jamieson, David N.
Nurizzo, Martin
Holmes, Danielle
Laucht, Arne
Morello, Andrea
Quantum Physics
Mesoscale and Nanoscale Physics
Quantum error correction (QEC) requires non-invasive measurements for fault tolerant quantum computing. Deviations from ideal quantum non-demolition (QND) measurements can disturb the encoded information. To address this challenge, we develop a readout protocol for a $D-$dimensional system that, after a single positive outcome, switches to probing only the $D{-}1$ remaining subspace. This adaptive switching strategy minimizes measurement-induced errors by relying on negative-result measurement results that do not perturb the Hamiltonian. We apply the protocol on an 8-dimensional $^{123}{\rm Sb}$ nuclear qudit in silicon, and achieve an increase in the readout fidelity from $(98.93\pm0.07)\%$ to $(99.61\pm0.04)\%$, while reducing threefold the overall readout time. To highlight the broader relevance of measurement-induced errors, we study a 10-dimensional $^{73}{\rm Ge}$ nuclear spin read out through Pauli spin blockade, revealing nuclear spin flips arising from hyperfine and quadrupole interactions. These results unveil the effect of non-ideal QND readout across diverse platforms, and introduce an efficient readout protocol that can be implemented with minimal FPGA logic on existing hardware.
title Maximizing the nondemolition nature of a quantum measurement via an adaptive readout protocol
topic Quantum Physics
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2511.10978