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Experimental Study of the Optical Qubit on the 435-nm Quadrupole Transition in the 171Yb+ Ion

I. V. Zalivako, I. A. Semerikov, A. S. Borisenko, Mikhail Aksenov, K. Yu. Khabarova, N. Kolachevsky

2021Journal of Experimental and Theoretical Physics Letters20 citationsDOI

Abstract

Ultracold ions provide one of the most promising platforms for quantum computing and make it possible to reach record coherence times, the fidelity of preparation and readout operations, and single- and two-qubit operations. Encoding quantum information in an optical qubit based on the $$^{2}{{S}_{{1/2}}}(F = 0,{{m}_{F}} = 0)$$ → $$^{2}{{D}_{{3/2}}}(F = 2,{{m}_{F}} = 0)$$ quadrupole transition in the 171Yb+ ion at a wavelength of 435.5 nm, which has potential advantages over similar systems in the scaling of the number of qubits and their sensitivity to fluctuations of the magnetic field, is proposed and experimentally studied. The proposed optical qubit in ytterbium is compared to other most widespread types of ion qubits. Experimental results on the implementation of the Pauli-X single-qubit operation are given. The fidelity of the operation is 96% after correction to the error of preparation and readout and is limited by the temperature of the ion.

Topics & Concepts

QubitCoherence (philosophical gambling strategy)PhysicsQuadrupoleIonPhase qubitFlux qubitQuantum computerQuantum informationCoherence timeAtomic physicsTrapped ion quantum computerFidelityQuantum mechanicsQuantumQuantum error correctionComputer scienceTelecommunicationsQuantum Information and CryptographyCold Atom Physics and Bose-Einstein CondensatesQuantum optics and atomic interactions
Experimental Study of the Optical Qubit on the 435-nm Quadrupole Transition in the 171Yb+ Ion | Litcius