Fast nuclear-spin gates and electrons-nuclei entanglement of neutral atoms in weak magnetic fields
Abstract
We present fast Rydberg-mediated entanglement involving nuclear spins of divalent atoms with 171Yb as an example. First, we show a nuclear-spin controlled phase gate of an arbitrary phase realizable either with two laser pulses when assisted by Stark shifts, or with three pulses. Second, we propose to create a state (e n + e n )/2 entangled between the electrons~(e) and nuclear spins~(n) of two atoms, where and are two orthogonal Bell states and ce denotes the clock state. For want of a better term, it is called a Super Bell State for it mimics a ``large'' Bell state incorporating three ``smaller'' Bell states. Third, we show a protocol to create a three-atom state (3e n + We GHZn )/2, where n is a nuclear-spin state, We is a W state in the ground-clock state space, and GHZn is the Greenberger-Horne-Zeilinger~(GHZ) state in the nuclear-spin state space. The four protocols possess high intrinsic fidelities, do not require single-site Rydberg addressing, and can be executed with large m in a weak, Gauss-scale magnetic field for they involve Rydberg excitation of both nuclear-spin qubit states in each atom. The latter two protocols can enable measurement-based preparation of Bell, hyperentangled, and GHZ states.
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