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Controlling Synthetic Spin-Orbit Coupling in a Silicon Quantum Dot with Magnetic Field

Xin Zhang, Yuan Zhou, Rui-Zi Hu, Rong-Long Ma, Ming Ni, Ke Wang, Gang Luo, Gang Cao, Gui-Lei Wang, Peihao Huang, Xuedong Hu, Hong-Wen Jiang, Hai-Ou Li, Guang-Can Guo, Guo-Ping Guo

2021Physical Review Applied25 citationsDOIOpen Access PDF

Abstract

Tunable synthetic spin-orbit coupling (SSOC) is one of the key challenges in various quantum systems, such as ultracold atomic gases, topological superconductors, and semiconductor quantum dots. Here we experimentally demonstrate controlling the SSOC by investigating the anisotropy of spin-valley resonance in a silicon quantum dot. As we rotate the applied magnetic field in plane, we find a striking nonsinusoidal behavior of resonance amplitude that distinguishes SSOC from the intrinsic spin-orbit coupling (ISOC), and associate this behavior with the previously overlooked in-plane transverse magnetic field gradient. Moreover, by theoretically analyzing the experimentally measured SSOC field, we predict the quality factor of the spin qubit could be optimized if the orientation of the in-plane magnetic field is rotated away from the traditional working point.

Topics & Concepts

Condensed matter physicsCoupling (piping)Magnetic fieldPhysicsQubitQuantum dotSpin (aerodynamics)Field (mathematics)Quantum computerSiliconQuantumTrapped ion quantum computerSpin engineeringQuantum point contactRotating magnetic fieldAnisotropyResonance (particle physics)AmplitudeMagnetic anisotropyQuality (philosophy)Orientation (vector space)Quantum opticsFerromagnetic resonanceInductive couplingSpin echoMagnetic resonance force microscopyMagnetostaticsQuantum entanglementQuantum sensorQuantum mechanicsQuantum informationMagnetometerQuantum dot laserFree induction decayQuantum and electron transport phenomenaTopological Materials and PhenomenaSemiconductor Quantum Structures and Devices
Controlling Synthetic Spin-Orbit Coupling in a Silicon Quantum Dot with Magnetic Field | Litcius