A high-fidelity, two-qubit cross-resonance gate using interference couplers

Abhinav Kandala; Xuan Wei; Srikanth Srinivasan; Easwar M Magesan; Santino Carnevale; George Keefe; Dave Klaus; Oliver E. Dial; David McKay

A high-fidelity, two-qubit cross-resonance gate using interference couplers

ORAL

Abstract

Improving two-qubit gate performance and suppressing crosstalk are major challenges for building fault-tolerant quantum computers. In this talk, we will discuss a novel, fixed-frequency, multi-element coupling architecture for transmon qubits. This architecture features enhanced J exchange interaction strength and intrinsic idle ZZ suppression. We observe no degradation of qubit coherence (T₁,T₂ > 100μs) and measure a J/ZZ ratio greater than 100. Using the cross-resonance interaction we demonstrate a novel 200ns single-pulse CNOT gate and measure a gate fidelity of 99.77% (2.3e-3 gate error) from interleaved randomized benchmarking.

^*We acknowledge support for characterization and calibration from IARPA under Contract No. W911NF-16-0114.

March 18, 2021, 11:54 AM – March 18, 2021, 12:06 PM

Presenters

David McKay
- IBM Quantum

Authors

Abhinav Kandala
- IBM Quantum
- IBM TJ Watson Research Center
Xuan Wei
- IBM Quantum
Srikanth Srinivasan
- IBM Quantum
- IBM TJ Watson Research Center
Easwar M Magesan
- IBM Quantum
- IBM TJ Watson Research Center
Santino Carnevale
- IBM Quantum, IBM T. J. Watson Research Center, Yorktown Heights, NY 10598, USA
- IBM TJ Watson Research Center
- IBM Quantum
George Keefe
- IBM TJ Watson Research Center
- IBM Quantum
Dave Klaus
- IBM TJ Watson Research Center
- IBM Quantum
Oliver E. Dial
- IBM TJ Watson Research Center
- IBM Quantum
- Massachusetts Institute of Technology MIT
David McKay
- IBM Quantum