Real-time preparation and verification of nonstabilizer states

Abstract

Entanglement lies at the heart of quantum information science, serving as a key resource for quantum communication, computation, and metrology. Consequently, high-precision entangled state preparation and efficient verification are essential for practical quantum technologies. Quantum state verification (QSV) has recently gained much attention as an efficient and experiment-friendly approach for verifying entangled states. In this work, we experimentally demonstrate a QSV protocol for verifying three-qubit nonstabilizer W state via a modified homogeneous strategy. Notably, our implementation extends QSV beyond its standard role by integrating the state preparation process, thus guiding and validating the real-time generation of high-fidelity target states. Specifically, we realize the efficient verification with a favorable scaling of the required number of copies versus infidelity as -1.39, outperforming the standard quantum limit of -2. Meanwhile, a fidelity of 97.07( 0.26)\% via direct estimation is achieved using only 9 measurement settings and 104 samples, which is independently confirmed by quantum state tomography to be 98.58( 0.12)\% with approximately 106 measurements. This work presents the first experimental demonstration of QSV actively assisted with state preparation, establishing it as a powerful and resource-efficient alternative to full tomography for real-time quantum state engineering.