Longitudinal and Nonlinear Coupling for High-Fidelity Readout of a Superconducting Qubit
Can Wang, Feng-Ming Liu, He Chen, Yi-Fei Du, Chong Ying, Jianwen Wang, Yong-Heng Huo, Cheng-Zhi Peng, Xiaobo Zhu, Ming-Cheng Chen, Chao‐Yang Lu, Jian-Wei Pan
Abstract
Despite the significant progress in superconducting quantum computation over the past years, quantum state measurement still lags nearly an order of magnitude behind quantum gate operations in speed and fidelity. The main challenge is that the strong coupling and readout signal used to probe the quantum state may also introduce additional channels which may cause qubit state transitions. Here, we design a novel architecture to implement the long-sought longitudinal interaction scheme between qubits and resonators. This architecture not only provides genuine longitudinal interaction by eliminating residual transversal couplings, but also introduces proper nonlinearity to the resonator that can further minimize decay error and measurement-induced excitation error. Combined with the multilevel readout protocol, we achieved a measurement fidelity of 99.8% in 202 ns without requiring any first-stage amplification. This highlights its potential as a highly promising architecture for superconducting qubit measurement.