Litcius/Paper detail

Spin Readout of a CMOS Quantum Dot by Gate Reflectometry and Spin-Dependent Tunneling

Virginia N. Ciriano-Tejel, Michael A. Fogarty, Simon Schaal, Louis Hutin, Benoit Bertrand, Lisa Ibberson, M. Fernando Gonzalez-Zalba, Jing Li, Yann-Michel Niquet, Maud Vinet, John J.L. Morton

2021PRX Quantum54 citationsDOIOpen Access PDF

Abstract

Silicon spin qubits are promising candidates for realizing large-scale quantum processors, benefitting from a magnetically quiet host material and the prospects of leveraging the mature silicon device fabrication industry. We report the measurement of an electron spin in a singly occupied gate-defined quantum dot, fabricated using CMOS-compatible processes at the 300-mm wafer scale. For readout, we employ spin-dependent tunneling combined with a low-footprint single-lead quantum-dot charge sensor, measured using rf gate reflectometry. We demonstrate spin readout in two devices using this technique, obtaining valley splittings in the range 0.5-0.7 meV using excited-state spectroscopy, and measure a maximum electron-spin relaxation time (T 1 ) of 9 3 s at 1 T. These long lifetimes indicate the silicon-nanowire geometry and fabrication processes employed here show a great deal of promise for qubit devices, while the spin-readout method demonstrated here is well suited to a variety of scalable architectures.

Topics & Concepts

Quantum tunnellingQubitQuantum dotFabricationSpin (aerodynamics)OptoelectronicsReflectometrySiliconMaterials scienceWaferPhysicsCMOSMeasure (data warehouse)Coherence timeCoherence (philosophical gambling strategy)QuantumCondensed matter physicsCommon emitterSilicon on insulatorCharge (physics)ElectronQuantum computerRelaxation (psychology)Range (aeronautics)Laser linewidthQuantum dot laserGallium arsenidePulse (music)Quantum sensorTransistorNanotechnologyQuantum and electron transport phenomenaAdvancements in Semiconductor Devices and Circuit DesignSemiconductor Quantum Structures and Devices