Realization of High-Fidelity CZ and ZZ-Free iSWAP Gates with a Tunable Coupler

High-fidelity two-qubit gates at scale are a key requirement to realize the full promise of quantum computation and simulation. The advent and use of coupler elements to tunably control two-qubit interactions has improved operational fidelity in many-qubit systems by reducing parasitic coupling and frequency crowding issues. Nonetheless, two-qubit gate errors still limit the capability of near-term quantum applications. The reason, in part, is that the existing framework for tunable couplers based on the dispersive approximation does not fully incorporate three-body multilevel dynamics, which is essential for addressing coherent leakage to the coupler and parasitic longitudinal (ZZ) interactions during two-qubit gates. Here, we present a systematic approach that goes beyond the dispersive approximation to exploit the engineered level structure of the coupler and optimize its control. Using this approach, we experimentally demonstrate CZ and ZZ-free iSWAP gates with two-qubit interaction fidelities of 99.76 +/- 0.07% and 99.87 +/- 0.23%, respectively, which are close to their T-1 limits.

Automated summary

High-fidelity two-qubit gates are crucial for quantum computation and simulation, but current frameworks do not fully address three-body multilevel dynamics. A new systematic approach is presented to optimize control and achieve CZ and ZZ-free iSWAP gates with high fidelity. Experimental results show interaction fidelities close to T-1 limits.