Entanglement Detection with Variational Quantum Interference: Theory and Experiment
Abstract
Entanglement detection serves as a fundamental task in quantum information science, playing a critical role in quantum benchmarking and foundational studies. As the number of controllable qubits continues to increase, there emerges a pressing demand for scalable and robust entanglement detection protocols that can maintain high detection capability while requiring minimal resources. By integrating the positive partial transposition criterion with variational quantum interference, we develop an entanglement detection protocol that requires moderate classical and quantum computation resources. Numerical simulations demonstrate that this protocol attains high detection capability using only shallow quantum circuits, outperforming several widely-used entanglement detection methods. The protocol also exhibits strong resilience to circuit noise, ensuring its applicability across different physical platforms. Experimental implementation on a linear optical platform successfully identifies entanglement in a three-qubit mixed state that cannot be detected by conventional entanglement witnesses. Drawing upon the full potential of quantum and classical resources, our protocol paves a new path for efficient entanglement detection.