Prof. Dr Luigi Amico
The Quantum Physics group investigates quantum matter for quantum technology. We study quantum correlations and entanglement in many-body theory, with specific applications to quantum gases spatially confined in low-dimensional structures, atomtronics, mesoscopic networks, and superconducting circuits. In close contact with experiments, we conceive quantum devices and sensors characterised by enhanced control and flexibility of their operating conditions. At the same time, we investigate fundamental aspects of the quantum phases of matter.
Prof. Dr Leandro Aolita
The Quantum Algorithms group focuses on quantum computation theory and applications, with emphasis on the development of quantum algorithms for complex optimisations, machine learning, and many-body system simulations. We are interested in both practical primitives for near-term devices and advanced procedures for future, fully-fledged universal quantum computers. We explore hybrid classical-quantum approaches, neural- and tensor- networks, imaginary-time evolution, quantum signal processing, error correction and mitigation, computational complexity, verification and benchmarking, and quantum-circuit compiling, etc.
Prof. Dr Stefano Carrazza
The simulation and control of quantum systems requires the development of dedicated software. The Quantum Middleware group focuses on implementing the code libraries required for efficient quantum algorithms design, classical simulation of quantum computation, and control of quantum devices. The main area of research for the group is the development of Qibo, an open-source software for quantum computing.
Dr James A. Grieve
The Quantum Communications group is focused on developing quantum communication devices for tomorrow’s networks by building systems that can operate in the real world, outside of the lab. Our research includes the translation of bench-top experiments into chip-scale systems, designing and building entangled photon sources and single photon emitters for next-generation quantum networks. To address near-term challenges in private communication, we also develop quantum key distribution systems, using quantum entanglement to enable ultra-secure communication over fibre and free-space links.
Prof. Dr Andy Lütken
The Quantum Computation group will build and operate the first quantum computer in the region, using superconducting circuits at nearly zero temperature, where quantum correlations survive thermal fluctuations. Qubits, computer architecture and control circuits are being designed in collaboration with other groups at QRC and will be produced in our own on-site quantum foundry.
Dr Rene Reimann
The Quantum Sensing group is interested in fundamental studies and technology development of optomechanical sensors. The group’s main experimental research line addresses levitated particle sensors under ultra-high vacuum conditions. Levitation and vacuum provide a high level of system isolation, enabling us to probe and use quantum mechanical effects. Our systems are promising candidates for high-end inertial sensors, sensing of minute torques and forces, and chemical sensing, among others. Due to stability demands of real-world sensors, an extension of our research to more robust clamped optomechanical setups is possible.