Demonstrating two-qubit entangling gates at the quantum speed limit using superconducting qubits

ORAL  · Invited

Abstract

The speed at which quantum entanglement between qubits with short range interactions can be generated is limited by the Lieb-Robinson bound. Introducing longer range interactions relaxes this bound and entanglement can be generated at a faster rate. The speed limit for this has been explicitly found theoretically only for a two-qubit system and under the assumption of negligible single qubit gate time. We have theoretically determined this speed limit for a realistic experimental system. Furthermore, we go on to demonstrate this speed limit experimentally using two superconducting transmon qubits. This development has important implications for large scale quantum computing.

*We thank NIST Boulder for hosting the experiment and the HPC center at Colorado School of Mines for providing computational resources. We acknowledge funding support from the NSF RAISE-TAQS program CCF-1839232, the NSF Triplets program DMR-1747426, the NSF NRT program DGE-2125899, and the W. M. Keck Foundation.

Publication: https://arxiv.org/pdf/2206.07716.pdf - currently under review at Physical Review Letters.

Presenters

  • Meenakshi Singh

    • Colorado School of Mines

Authors

  • Meenakshi Singh

    • Colorado School of Mines

  • Zhexuan Gong

    • Colorado School of Mines - Golden, CO

  • Joel Howard

    • Colorado School of Mines - Golden, CO

  • David P Pappas

    • Rigetti Quantum Computing

  • Alexander Lidiak

    • Colorado School of Mines - Golden, CO

  • Casey Jameson

    • Colorado School of Mines - Golden, CO

  • Bora Basyildiz

    • Colorado School of Mines - Golden, CO

  • Kyle Clark

    • Colorado School of Mines - Golden, CO

  • Tongyu Zhao

    • National Institute of Standards and Technology Boulder

  • Junling Long

    • University of Colorado, Boulder

  • Mustafa Bal

    • Fermilab