Litcius/Paper detail

Electric field manipulation enhanced by strong spin-orbit coupling: promoting rare-earth ions as qubits

Zheng Liu, Ye-Xin Wang, Yu-Hui Fang, Si-Xue Qin, Zhe-Ming Wang, Shang-Da Jiang, Song Gao

2020National Science Review39 citationsDOIOpen Access PDF

Abstract

Abstract Quantum information processing based on magnetic ions has potential for applications as the ions can be modified in their electronic properties and assembled by a variety of chemical methods. For these systems to achieve individual spin addressability and high energy efficiency, we exploited the electric field as a tool to manipulate the quantum behaviours of the rare-earth ion which has strong spin-orbit coupling. A Ce:YAG single crystal was employed with considerations to the dynamics and the symmetry requirements. The Stark effect of the Ce3+ ion was observed and measured. When demonstrated as a quantum phase gate, the electric field manipulation exhibited high efficiency which allowed up to 57 π/2 operations before decoherence with optimized field direction. It was also utilized to carry out quantum bang-bang control, as a method of dynamic decoupling, and the refined Deutsch-Jozsa algorithm. Our experiments highlighted rare-earth ions as potentially applicable qubits because they offer enhanced spin-electric coupling which enables high-efficiency quantum manipulation.

Topics & Concepts

QubitTrapped ion quantum computerIonElectric fieldPhysicsQuantum decoherenceQuantum computerQuantumField (mathematics)Atomic physicsSpin (aerodynamics)Coupling (piping)Stark effectQuantum informationMagnetic fieldQuantum dotSymmetry (geometry)Quantum chemicalPhase (matter)Quantum systemQuantum logicQuantum mechanicsQuantum sensorChemical physicsVariety (cybernetics)Quantum simulatorMaterials scienceCondensed matter physicsQuantum dynamicsEnergy (signal processing)Spin engineeringQuantum technologyMagnetism in coordination complexesQuantum Computing Algorithms and ArchitectureQuantum chaos and dynamical systems