Dynamical baryon formation in $SU(n)$ Hubbard Models
ORAL
Abstract
We study post quench dynamics in the repulsive n-color Fermi-Hubbard model,
initialized in a periodic pattern of empty and n-times occupied sites. In any dimension
and for any finite interaction, U>0, this state is proven to relax
to a negative temperature state. However, while for weak interactions, U/J ≤ 1, a
negative temperature Fermi liquid appears, for U/J ≥ 1, quench spectroscopy [1,2] as well as the behavior
of time dependent correlation functions reveal the dynamical formation of heavy and strongly interacting
composite particles. For n=3, in particular, most of the particles are bound to very
heavy spinless 'baryons' (trions), strongly interacting with a dilute background gas of
intermediate mass mobile 'mesons' (doublons) and of light SU(3) fermions. Baryons move
diffusively, with a motion generated by collisions with the mesonic background. Similarly rich
negative temperature states form for any n ≥ 2.
[1] M. Kormos, M. Collura, G. Takács, and P. Calabrese, Nature Physics 13, 246 (2017).
[2] M. Collura, M. Kormos, and G. Takács, Phys. Rev. A 98, 053610 (2018).
initialized in a periodic pattern of empty and n-times occupied sites. In any dimension
and for any finite interaction, U>0, this state is proven to relax
to a negative temperature state. However, while for weak interactions, U/J ≤ 1, a
negative temperature Fermi liquid appears, for U/J ≥ 1, quench spectroscopy [1,2] as well as the behavior
of time dependent correlation functions reveal the dynamical formation of heavy and strongly interacting
composite particles. For n=3, in particular, most of the particles are bound to very
heavy spinless 'baryons' (trions), strongly interacting with a dilute background gas of
intermediate mass mobile 'mesons' (doublons) and of light SU(3) fermions. Baryons move
diffusively, with a motion generated by collisions with the mesonic background. Similarly rich
negative temperature states form for any n ≥ 2.
[1] M. Kormos, M. Collura, G. Takács, and P. Calabrese, Nature Physics 13, 246 (2017).
[2] M. Collura, M. Kormos, and G. Takács, Phys. Rev. A 98, 053610 (2018).
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Publication: M. A. Werner, C. P. Moca, M. Kormos, Ö. Legeza, B. Dóra, and G. Zaránd, to be published
Presenters
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Miklós Antal Werner
Budapest University of Technology and Economics
Authors
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Miklós Antal Werner
Budapest University of Technology and Economics
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Catalin Pascu Moca
Budapest University of Technology and Economics, University of Oradea
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Márton Kormos
MTA-BME Quantum-Dynamics and Correlations Research Group, Eötvös Loránd Research Network (ELKH), BUTE, 1111 Budapest, Budafoki út 8, Hungary, Budapest University of Technology and Economics
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Örs Legeza
Wigner Research Center, Wigner Research Centre for Physics, Budapest, Hungary
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Balázs Dóra
Budapest University of Technology and Economics
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Gergely Zarand
Budapest University of Technology and Economics