Thermodynamics of the disordered Hubbard model from numerical linked-cluster expansions
ORAL
Abstract
The interplay of disorder and strong correlations in quantum many-body
systems remains an open question despite much progress that has been
made in recent years with ultracold atoms in optical lattices to better
understand phenomena such as many-body localization or the effect of
disorder on Mott metal-insulator transitions. Here we utilize the numerical
linked-cluster expansion technique, extended to deal with disordered
quantum lattice models in the thermodynamic limit, and study exact
thermodynamic properties of the disordered Fermi-Hubbard model on
the square lattice. We consider box distributions for the disorder in the
hopping amplitude as well as in the onsite energy or the interaction
strength and explore how the system properties evolve as the strength
of the disorder changes. We compare our results with those obtained
from determinant quantum Monte Carlo simulations on finite clusters
and discuss the potential applications of the results to experiments with
cold fermionic atoms on optical lattices.
systems remains an open question despite much progress that has been
made in recent years with ultracold atoms in optical lattices to better
understand phenomena such as many-body localization or the effect of
disorder on Mott metal-insulator transitions. Here we utilize the numerical
linked-cluster expansion technique, extended to deal with disordered
quantum lattice models in the thermodynamic limit, and study exact
thermodynamic properties of the disordered Fermi-Hubbard model on
the square lattice. We consider box distributions for the disorder in the
hopping amplitude as well as in the onsite energy or the interaction
strength and explore how the system properties evolve as the strength
of the disorder changes. We compare our results with those obtained
from determinant quantum Monte Carlo simulations on finite clusters
and discuss the potential applications of the results to experiments with
cold fermionic atoms on optical lattices.
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Presenters
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Jacob Park
San Jose State University
Authors
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Jacob Park
San Jose State University
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Richard Theodore Scalettar
University of California, Davis, Univ of California - Davis, Department of Physics, University of California, Davis
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Ehsan Khatami
Department of Physics and Astronomy, San Jose State Unversity, San Jose State University, Physics, San Jose State University