Universal quantum control over Rydberg atoms

Abstract: In this paper, the universal quantum control with error correction is applied to the generation of the Greenberger-Horne-Zeilinger (GHZ) states of multiple Rydberg atoms, in which the qubits are encoded on the hyperfine ground levels. Our system is featured with the off-resonant driving fields rather than the strong Rydberg interaction sufficient for blockade. It can closely follow the designed nonadiabatic passage during the time evolution and avoid the unwanted transition by imposing the path-dependent and fast-varying global phase. A general GHZ state of $N$ Rydberg qubits can be prepared in $N-1$ steps, which is found to be robust against both environmental noises and systematic errors. Our protocol therefore provides an avenue towards large-scale entanglement, which is essential for quantum information and quantum computation based on neutral atoms.