Metrological characterisation of non-Gaussian entangled states of superconducting qubits

TL;DR

This paper demonstrates the experimental measurement of non-Gaussian entangled states in a superconducting qubit processor, revealing significant metrological gains and advancing quantum sensing capabilities.

Contribution

It reports the first experimental measurement of the nonlinear squeezing parameter and Fisher information for non-Gaussian entangled states in a superconducting quantum processor.

Findings

Achieved a metrological gain of nearly 10 dB over the standard quantum limit.

Measured the nonlinear squeezing parameter (NLSP) for non-Gaussian states.

Demonstrated high multiparticle entanglement in a 19-qubit system.

Abstract

Multipartite entangled states are significant resources for both quantum information processing and quantum metrology. In particular, non-Gaussian entangled states are predicted to achieve a higher sensitivity of precision measurements than Gaussian states. On the basis of metrological sensitivity, the conventional linear Ramsey squeezing parameter (RSP) efficiently characterises the Gaussian entangled atomic states but fails for much wider classes of highly sensitive non-Gaussian states. These complex non-Gaussian entangled states can be classified by the nonlinear squeezing parameter (NLSP), as a generalisation of the RSP with respect to nonlinear observables, and identified via the Fisher information. However, the NLSP has never been measured experimentally. Using a 19-qubit programmable superconducting processor, here we report the characterisation of multiparticle entangled states generated during its nonlinear dynamics. First, selecting 10 qubits, we measure the RSP and the NLSP by single-shot readouts of collective spin operators in several different directions. Then, by extracting the Fisher information of the time-evolved state of all 19 qubits, we observe a large metrological gain of 9.89$^{+0.28}_{-0.29}$ dB over the standard quantum limit, indicating a high level of multiparticle entanglement for quantum-enhanced phase sensitivity. Benefiting from high-fidelity full controls and addressable single-shot readouts, the superconducting processor with interconnected qubits provides an ideal platform for engineering and benchmarking non-Gaussian entangled states that are useful for quantum-enhanced metrology.