Quantum entanglement is a fundamental and distinctive aspect of quantum physics, characterized by correlations between spatially separated particles. This phenomenon is central to major advancements in quantum computing, communication, and information processing. However, detecting and characterizing complex entanglement, particularly in multipartite and high-dimensional systems, remains a significant challenge.
  This project aims to develop advanced variational quantum algorithms to efficiently identify and analyze entanglement structures in complex quantum systems. Building on prior successes in bipartite systems, the research seeks to extend these methods to more general and scalable settings.
  By integrating algorithm design, theoretical modeling, numerical simulation, and experimental implementation on quantum hardware, the project aspires to deepen our understanding of entanglement and support the development of emerging quantum technologies. Collaboration with researchers in foundational quantum physics will further broaden the scientific relevance and impact of the project.