Quantum gates and algorithms using a 2D array of Cs neutral atom qubits.

POSTER

Abstract

We present our recent progress on implementing high fidelity two qubit gates using time optimal gate protocols in a two-dimensional atomic qubit array. To prepare the quantum register, laser cooled Cs atoms are loaded into a blue-detuned optical lattice, which is constructed from cross-hatched lines. We rearrange the atoms using optical tweezers to deterministically load atoms into targeted sites. We used top-hat shaped laser beams to perform simultaneous atom addressing for controlled phase gates via the Rydberg interaction. Short range mid-circuit transport is used to optimize gate operations for single and two qubit gates. Using this hardware, we implement a variational quantum eigensolver algorithm to estimate ground state energies of the Lipkin-Meshkov-Glick model.

*Work supported by DoE award DE-SC0019465, NSF Award 2210437, NSF Award 2016136 for the QLCI center Hybrid Quantum Architectures and Networks, and the U.S. Department of Energy Office of Science National Quantum Information Science Research Centers.

Publication: 1)Jandura, S. & Pupillo, G. Time-optimal two- and three-qubit gates for Rydberg atoms. Quantum 6, 712 (2022).
2) M. J. Cervia, A. B. Balantekin, S. N. Coppersmith, C. W. Johnson, P. J. Love, C. Poole, K. Robbins, and M. Saffman, Lipkin model on a quantum computer, Phys. Rev. C 104, 024305 (2021).

Presenters

  • Ravikumar Chinnarasu

    • University of Wisconsin-Madison

Authors

  • Ravikumar Chinnarasu

    • University of Wisconsin-Madison

  • Linipun Phuttitarn

    • University of Wisconsin - Madison

  • Cody Poole

    • University of Wisconsin-Madison

  • Jacob Scott

    • University of Wisconsin - Madison

  • Arian M Noori

    • University of Wisconsin-Madison

  • Kais Jooya

    • University of Wisconsin-Madison

  • Trent Graham

    • University of Wisconsin - Madison

  • Mark Saffman

    • University of Wisconsin - Madison, Infleqtion, Inc.