This research line focuses on the study driven-dissipative systems in which quantum phenomena and critical behaviour emerge not despite their dissipative nature, but precisely because of it. This research includes the study of several examples of driven-dissipative phase transitions, and exotic effects such as:
Relevant publications
- Quantum Synchronisation Enabled by Dynamical Symmetries and Dissipation
J. Tindall, C. Sánchez Muñoz, B. Buca, D. Jaksch
New Journal of Physics 22 (1), 013026 (2020) - Symmetries and conservation laws in quantum trajectories: Dissipative freezing
C. Sánchez Muñoz, B. Buca, J. Tindall, A. González-Tudela, D. Jaksch, D. Porras.
Phys. Rev. A 100, 042113 (2019) - Engineering and Harnessing Giant Atoms in High-Dimensional Baths: A Proposal for Implementation with Cold Atoms
A. González-Tudela, C. Sánchez Muñoz, I. Cirac
Phys. Rev. Lett 122, 203603 (2019)
- Topological order and thermal equilibrium in polariton condensates
D. Caputo, D. Ballarini, G. Dagvadorj, C. Sánchez Muñoz, M. De Giorgi, L. Dominici, K. West, L. N.
Pfeiffer, G. Gigli, F. P. Laussy, M. H. Szyma´nska, D. Sanvitto
Nature Materials 17, 145 (2018) - Macroscopic Two-Dimensional Polariton Condensates
D. Ballarini, D. Caputo, C. Sánchez Muñoz, M. De Giorgi, L. Dominici, M. H. Szyma´nska, K. West, L.
N Pfeiffer, G. Gigli, F. P. Laussy and Daniele Sanvitto.
Phys. Rev. Lett. 118, 215301 (2017)
Outreach
This is the video abstract of our paper Quantum Synchronisation Enabled by Dynamical Symmetries and Dissipation, written and presented by Joseph Tindall, and produced by myself.