Sub-100ns entangling gates between two strongly coupled transmon qubits

Superconducting qubits are very promising candidates for realizing a fault-tolerant quantum computer. However, implementing two-qubit entangling gates with short gate operation time and high fidelity is still a challenge with superconducting qubits. In this talk, we demonstrate a new type of two-qubit entangling gate, the SWIPHT gate [1], on a coupled-transmon device. The two-transmon system, strongly coupled through a bus resonator, is tuned into the secondary resonance regime, where the effective σ¹_zσ²_z interaction is enhanced due to the coupling to higher levels of the transmons. Unconditional single qubit gates two-transmon systems with strong σ¹_zσ²_z interaction were developed. This allows a SWIPHT CNOT gate with roughly 90 ns gate time. The gate fidelity is extracted by quantum process tomography.

[1] Sophia E. Economou and Edwin Barnes. Phys. Rev. B 91, 161405 (2015)