Strongly correlated ultracold fermions in two-dimensional tailored optical potentials: pairing, superfluidity and disorder
ScoutFermi2D
Finanziamento del: European Commission
Calls: H2020 – MSCA – IF – 2015
Data inizio: 2016-08-22 Data fine: 2019-08-21
Budget totale: EUR 168.277,20 Quota INO del budget totale: EUR 168.277,20
Responsabile scientifico: Responsabile scientifico per INO: Scazza Francesco
Calls: H2020 – MSCA – IF – 2015
Data inizio: 2016-08-22 Data fine: 2019-08-21
Budget totale: EUR 168.277,20 Quota INO del budget totale: EUR 168.277,20
Responsabile scientifico: Responsabile scientifico per INO: Scazza Francesco
Principale Organizzazione/Istituzione/Azienda assegnataria: CNR – Istituto Nazionale di Ottica (INO)
altre Organizzazione/Istituzione/Azienda coinvolte:
Abstract: Two-dimensional fermionic systems exhibit some of the most remarkable phenomena in modern physics, combining fundamental aspects with a high technological impact. T
Their peculiar and rich behavior arises from the interplay between quantum statistics, dimensionality and strong interactions, which also makes their theoretical treatment extremely challenging.
This project proposes to explore the physics of strongly correlated fermions in different two-dimensional (2D) landscapes with an ultracold gas of lithium atoms trapped in optical potentials.
Ultracold quantum gases are in fact the ideal platform for approaching open problems in condensed matter theory and also an exciting toolbox for the search for novel synthetic phases of matter.
The project aims to study fermionic superfluidity across the two-dimensional BEC-BCS crossover, unveiling its special nature by implementing advanced probing techniques such as high-resolution imaging and Bragg spectroscopy and suitable transport measurements that will reliably identify the transition to the superfluid regime.
The investigation of first and second sound will be complemented by the study of the coherent Josephson tunneling between two weakly coupled 2D superfluids, a strong evidence of macroscopic phase coherence.
By adding disorder, we propose to address the debated metal- and superconductor-to-insulator transitions in a pure controllable fashion, providing new insights into longstanding debates.
Finally, we propose to realize three-components Fermi gases with controllable interactions, enhancing their stability in 2D.
This will allow for approaching more exotic topics such as color superfluidity and trimer formation, linking our research to quantum-chromodynamics (QCD).
An experimental machine has been already set up for the requirements imposed by these goals.
The successful realization of the proposed experiments will shed new light on the intriguing and interdisciplinary field of 2D strongly correlated fermions.
Their peculiar and rich behavior arises from the interplay between quantum statistics, dimensionality and strong interactions, which also makes their theoretical treatment extremely challenging.
This project proposes to explore the physics of strongly correlated fermions in different two-dimensional (2D) landscapes with an ultracold gas of lithium atoms trapped in optical potentials.
Ultracold quantum gases are in fact the ideal platform for approaching open problems in condensed matter theory and also an exciting toolbox for the search for novel synthetic phases of matter.
The project aims to study fermionic superfluidity across the two-dimensional BEC-BCS crossover, unveiling its special nature by implementing advanced probing techniques such as high-resolution imaging and Bragg spectroscopy and suitable transport measurements that will reliably identify the transition to the superfluid regime.
The investigation of first and second sound will be complemented by the study of the coherent Josephson tunneling between two weakly coupled 2D superfluids, a strong evidence of macroscopic phase coherence.
By adding disorder, we propose to address the debated metal- and superconductor-to-insulator transitions in a pure controllable fashion, providing new insights into longstanding debates.
Finally, we propose to realize three-components Fermi gases with controllable interactions, enhancing their stability in 2D.
This will allow for approaching more exotic topics such as color superfluidity and trimer formation, linking our research to quantum-chromodynamics (QCD).
An experimental machine has been already set up for the requirements imposed by these goals.
The successful realization of the proposed experiments will shed new light on the intriguing and interdisciplinary field of 2D strongly correlated fermions.