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Bibliographic Details
Main Authors: Hamonic, Pierre, Nurizzo, Martin, Nath, Jayshankar, Dartiailh, Matthieu C., El-Homsy, Victor, Fragnol, Mathis, Martinez, Biel, Julliard, Pierre-Louis, Paz, Bruna Cardoso, Ouvrier-Buffet, Mathilde, Filippini, Jean-Baptiste, Bertrand, Benoit, Niebojewski, Heimanu, Bäuerle, Christopher, Vinet, Maud, Balestro, Franck, Meunier, Tristan, Urdampilleta, Matias
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2410.02325
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Table of Contents:
  • Semiconductor quantum dot arrays are a promising platform to perform spin-based error-corrected quantum computation with large numbers of qubits. However, due to the diverging number of possible charge configurations combined with the limited sensitivity of large-footprint charge sensors, achieving single-spin occupancy in each dot in a growing quantum dot array is exceedingly complex. Therefore, to scale-up a spin-based architecture we must change how individual charges are readout and controlled. Here, we demonstrate single-spin occupancy of each dot in a foundry-fabricated array by combining two methods. 1/ Loading a finite number of electrons into the quantum dot array; simplifying electrostatic tuning by isolating the array from the reservoirs. 2/ Deploying multiplex gate-based reflectometry to dispersively probe charge tunneling and spin states without charge sensors or reservoirs. Our isolated arrays probed by embedded multiplex readout can be readily electrostatically tuned. They are thus a viable, scalable approach for spin-based quantum architectures.