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Low dephasing and robust micromagnet designs for silicon spin qubits

N. I. Dumoulin Stuyck, F. A. Mohiyaddin, R. Li, M. Heyns, B. Govoreanu, I. P. Radu

2021Applied Physics Letters23 citationsDOIOpen Access PDF

Abstract

Using micromagnets to enable electron spin manipulation in silicon qubits has emerged as a very popular method, enabling single-qubit gate fidelities larger than 99.9%. However, these micromagnets also apply stray magnetic field gradients onto the qubits, making the spin states susceptible to electric field noise and limiting their coherence times. We describe here a magnet design that minimizes qubit dephasing, while allowing for fast qubit control and addressability. Specifically, we design and optimize magnet dimensions and positions relative to the quantum dots, minimizing dephasing from magnetic field gradients. The micromagnet-induced dephasing rates with this design are up to three orders of magnitude lower than state-of-the-art implementations, allowing for long coherence times. This design is robust against fabrication errors and can be combined with a wide variety of silicon qubit device geometries, thereby allowing exploration of coherence limiting factors and novel upscaling approaches.

Topics & Concepts

DephasingQubitCoherence (philosophical gambling strategy)Coherence timePhysicsQuantum computerSpin engineeringSpin (aerodynamics)Magnetic fieldQuantum decoherenceQuantumCondensed matter physicsSiliconNoise (video)Quantum informationField (mathematics)MagnetQuantum mechanicsRobustness (evolution)Electronic engineeringControlled NOT gateElectric fieldQuantum technologyLimitingQuantum gateQuantum metrologyOptoelectronicsElectronQuantum sensorMagnetometerSpin polarizationQuantum and electron transport phenomenaMagnetic properties of thin filmsChemical and Physical Properties of Materials
Low dephasing and robust micromagnet designs for silicon spin qubits | Litcius