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| Funder | European Commission |
|---|---|
| Recipient Organization | Centre National de la Recherche Scientifique CNRS |
| Country | France |
| Start Date | Sep 01, 2023 |
| End Date | Aug 31, 2028 |
| Duration | 1,826 days |
| Number of Grantees | 2 |
| Roles | Third Party; Coordinator |
| Data Source | European Commission |
| Grant ID | 101076639 |
Topological phases of matter emerge from the interplay between broken symmetries and many-body physics and exhibit many fascinating quantum phenomena.
Ultrafast switching between different topological phases using light pulses holds the promise for disruptive optoelectronic functionalities, like dissipationless and fault-tolerant logical operations.
However, the lack of proper observable being simultaneously sensitive to the local (in momentum-space) topology of the band structure and compatible with time-resolved measurements prevents the real-time monitoring of ultrafast non-equilibrium topological phase transitions.
I will address this fundamental challenge by introducing innovative control and measurement methodologies using tailored light pulses in time-, angle- and polarization-resolved extreme ultraviolet photoemission spectroscopy.
This approach will enable to follow the ultrafast evolution of the electronic band structures local topology, in photoexcited quantum materials.
This will represent a major advance in photoemission spectroscopy, by moving from band structure mapping to accessing the dynamical evolution of the Bloch wavefunction of solids.I will use these novel time- and quantum-state-resolved dichroic observables to investigate the rich non-equilibrium physics underlying ultrafast topological phase transitions occurring on various timescales following impulsive optical excitation using shaped pump pulses: i) during the formation of hybrid light-matter (Floquet-Bloch) states, ii) upon the transient modification of electronic correlations, and iii) following the excitation of coherent phonon modes.
UTOPIQ will deliver a dramatically improved understanding of the interplay between the non-equilibrium behaviour and non-trivial topology in photoexcited quantum materials, while further representing a decisive step towards the development of the field of ultrafast on demand topology.
Universite de Bordeaux; Centre National de la Recherche Scientifique CNRS
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