The aim of our research is to understand novel emerging phenomena of strongly interacting quantum matter in regimes far away from thermal equilibrium.
Quantum Mechanics together with the Principles of Equilibrium
Thermodynamics form the two building blocks of our modern understanding
of condensed matter systems and their interaction with experimental
probes, often sufficiently weak to probe only small deviations from
A fundamental question is whether novel quantum many body phenomena, genuinely different from their thermal low-temperature counterpart, can possibly emerge far away from equilibrium.
Of exquisite theoretical interest until the recent past, this issue
has become an extremely active field of research due to the enormous
progress achieved in the last two decades in preparing, controlling and
probing with high fidelity strongly interacting quantum many body
systems in different non-equilibrium regimes.
The variety of physical settings that have allowed this revolution is extremely wide. Examples include systems as different as ultracold atomic quantum gases, strongly non-linear hybrid light-matter cavity QED systems or correlated electrons under ultra-fast optical excitations.
Motivated by these experimental developments the IPFC Theory of Non-Equilibrium Quantum Matter group addresses fundamental theoretical questions at the interface between quantum statistical physics, condensed matter, atomic physics and quantum optics. Our activity will evolve around few central themes, including:
- Dynamics of Closed Quantum Many Body Systems, their approach to Thermal Equilibrium and the emergence of robust mechanisms for Ergodicity Breakdown, such as Kinetic Constraints or Quenched Random Disorder.
- Universal properties of Dissipative Quantum Phase Transitions and their realisations in quantum simulators based on superconducting CQED circuits.
- Engineering of Novel States of Quantum Matter by means of coupling to Classical and Quantum light.
We are supported by: