Overview
Our research focuses on advancing quantum technologies that go beyond classical limits, spanning from fundamental principles to practical applications:
(i) We develop and investigate novel quantum states with diverse properties.
(ii) We explore their applications in quantum sensing, quantum information, and quantum metrology.
Quantum State Engineering and Quantum Information
We develop future quantum technologies based on the quantum states of light. Our work focuses on generating squeezed states, entangled photons, and non-Gaussian states for near-term applications in quantum information processing and learning, with the aim of breaking established limits and demonstrating quantum advantages in the communication and sensing of fields and forces.
Quantum Sensing for Fundamental Physics
From enhancing the sensitivity of gravitational-wave detectors to probing the interface between quantum mechanics and gravity, and extending to the search for dark matter, quantum sensing plays a crucial role in unlocking new frontiers in fundamental physics. These approaches employ unique quantum tools — including squeezing, entanglement, and photon counting — to achieve unprecedented instrumental sensitivity, paving the way toward addressing fundamental challenges, such as reconciling quantum mechanics with general relativity.