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Bell-state tomography in a silicon many-electron artificial molecule

Ross C. C. Leon, Chih Hwan Yang, Jason C. C. Hwang, Julien Camirand Lemyre, Tuomo Tanttu, Wei Huang, Jonathan Y. Huang, Fay E. Hudson, Kohei M. Itoh, Arne Laucht, Michel Pioro-Ladrière, Andre Saraiva, Andrew S. Dzurak

2021Nature Communications26 citationsDOIOpen Access PDF

Abstract

An error-corrected quantum processor will require millions of qubits, accentuating the advantage of nanoscale devices with small footprints, such as silicon quantum dots. However, as for every device with nanoscale dimensions, disorder at the atomic level is detrimental to quantum dot uniformity. Here we investigate two spin qubits confined in a silicon double quantum dot artificial molecule. Each quantum dot has a robust shell structure and, when operated at an occupancy of 5 or 13 electrons, has single spin-[Formula: see text] valence electron in its p- or d-orbital, respectively. These higher electron occupancies screen static electric fields arising from atomic-level disorder. The larger multielectron wavefunctions also enable significant overlap between neighbouring qubit electrons, while making space for an interstitial exchange-gate electrode. We implement a universal gate set using the magnetic field gradient of a micromagnet for electrically driven single qubit gates, and a gate-voltage-controlled inter-dot barrier to perform two-qubit gates by pulsed exchange coupling. We use this gate set to demonstrate a Bell state preparation between multielectron qubits with fidelity 90.3%, confirmed by two-qubit state tomography using spin parity measurements.

Topics & Concepts

QubitQuantum dotPhysicsSiliconQuantum computerQuantumSpin (aerodynamics)Trapped ion quantum computerWave functionOptoelectronicsQuantum tomographyQuantum technologyElectronQuantum point contactSpin statesNanotechnologyQuantum stateValence (chemistry)Quantum gateAtomic physicsCondensed matter physicsNanoscopic scaleQuantum informationHigh fidelityQuantum sensorQuantum mechanicsMolecular physicsMaterials scienceQuantum entanglementBell stateControlled NOT gateParity (physics)Electric fieldValence electronField (mathematics)Quantum and electron transport phenomenaTopological Materials and PhenomenaChemical and Physical Properties of Materials
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