Silicon quantum devices are maturing from academic single- and two-qubit devices to industrially-fabricated dense quantum-dot (QD) arrays, increasing operational complexity and the need for better pulsed-gate and readout techniques. We perform gate-voltage pulsing and gate-based reflectometry measurements on a dense 2×2 array of silicon quantum dots fabricated in a 300-mm-wafer foundry. Utilizing the strong capacitive couplings within the array, it is sufficient to monitor only one gate electrode via high-frequency reflectometry to establish single-electron occupation in each of the four dots and to detect single-electron movements with high bandwidth. A global top-gate electrode adjusts the overall tunneling times, while linear combinations of side-gate voltages yield detailed charge stability diagrams. To test for spin physics and Pauli spin blockade at finite magnetic fields, we implement symmetric gate-voltage pulses that directly reveal bidirectional interdot charge relaxation as a function of the detuning between two dots. Charge sensing within the array can be established without the involvement of adjacent electron reservoirs, important for scaling such split-gate devices towards longer 2×N arrays. Our techniques may find use in the scaling of few-dot spin-qubit devices to large-scale quantum processors.
@article{arxiv.2012.04791,
title = {Gate reflectometry in dense quantum dot arrays},
author = {Fabio Ansaloni and Heorhii Bohuslavskyi and Federico Fedele and Torbjørn Rasmussen and Bertram Brovang and Fabrizio Berritta and Amber Heskes and Jing Li and Louis Hutin and Benjamin Venitucci and Benoit Bertrand and Maud Vinet and Yann-Michel Niquet and Anasua Chatterjee and Ferdinand Kuemmeth},
journal= {arXiv preprint arXiv:2012.04791},
year = {2023}
}