OrbiDynaMIQs | Two-orbital quantum many-body systems: from Kondo dynamics to mediated interactions

Summary
The interaction between localized spins and mobile fermions underlies the transport properties of a large variety of highly correlated materials. Even a single localized spin impurity can dramatically influence the motion of many fermions in its surroundings, giving rise to one of the most remarkable phenomena in quantum many-body physics - the Kondo effect. For a finite density of localized spins, the Kondo effect competes with non-local fermion-mediated Ruderman-Kittel-Kasuya-Yosida (RKKY) interactions, providing the driving force for many intriguing phenomena such as the unconventional superconductivity and the quantum critical behavior of heavy-fermion compounds. Despite decades of investigations, fundamental issues remain concerning the dynamical and spatial properties of the Kondo effect, that are difficult to tackle in electron systems. Further, a detailed understanding of the transition between the single-impurity Kondo problem and a system of interacting impurities is still missing. In OrbiDynaMIQs, I will develop a novel experimental platform for addressing such open questions. Leveraging on recent progress in manipulating single atoms with optical tweezers, I will realize a versatile two-orbital quantum simulator based on ultracold fermionic ytterbium atoms. I will focus on the spin-orbital dynamics of single and multiple localized impurities embedded in one- and two-dimensional itinerant fermion systems. I will then investigate the emergence of RKKY interactions between localized spins, both in few-body and full lattice realizations, taking first steps in exploring a whole new range of spin-correlation phenomena in Kondo systems. The proposed approach capitalizes on the strong interlink between quantum many-body physics and precision measurements with two-electron atoms, and on my experience at the confluence of these fields. It will also facilitate studies of new two-orbital models with enlarged SU(N) symmetries beyond that of spin-1/2 electron systems.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/949438
Start date: 01-05-2021
End date: 30-04-2026
Total budget - Public funding: 1 412 829,00 Euro - 1 412 829,00 Euro
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Original description

The interaction between localized spins and mobile fermions underlies the transport properties of a large variety of highly correlated materials. Even a single localized spin impurity can dramatically influence the motion of many fermions in its surroundings, giving rise to one of the most remarkable phenomena in quantum many-body physics - the Kondo effect. For a finite density of localized spins, the Kondo effect competes with non-local fermion-mediated Ruderman-Kittel-Kasuya-Yosida (RKKY) interactions, providing the driving force for many intriguing phenomena such as the unconventional superconductivity and the quantum critical behavior of heavy-fermion compounds. Despite decades of investigations, fundamental issues remain concerning the dynamical and spatial properties of the Kondo effect, that are difficult to tackle in electron systems. Further, a detailed understanding of the transition between the single-impurity Kondo problem and a system of interacting impurities is still missing. In OrbiDynaMIQs, I will develop a novel experimental platform for addressing such open questions. Leveraging on recent progress in manipulating single atoms with optical tweezers, I will realize a versatile two-orbital quantum simulator based on ultracold fermionic ytterbium atoms. I will focus on the spin-orbital dynamics of single and multiple localized impurities embedded in one- and two-dimensional itinerant fermion systems. I will then investigate the emergence of RKKY interactions between localized spins, both in few-body and full lattice realizations, taking first steps in exploring a whole new range of spin-correlation phenomena in Kondo systems. The proposed approach capitalizes on the strong interlink between quantum many-body physics and precision measurements with two-electron atoms, and on my experience at the confluence of these fields. It will also facilitate studies of new two-orbital models with enlarged SU(N) symmetries beyond that of spin-1/2 electron systems.

Status

SIGNED

Call topic

ERC-2020-STG

Update Date

27-04-2024
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Horizon 2020
H2020-EU.1. EXCELLENT SCIENCE
H2020-EU.1.1. EXCELLENT SCIENCE - European Research Council (ERC)
ERC-2020
ERC-2020-STG