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2 results

  • 8 - The Hubbard Model

  • from Part IV - Optical Lattices
  • Hui Zhai, Tsinghua University, Beijing
  • Book:
    Ultracold Atomic Physics
    Published online:
    30 January 2021
    Print publication:
    25 February 2021, pp 247-284

  • Summary

    1. Introduce quantum phase transition in the Bose-Hubbard model.

    2. Emphasize vanishing energy scales and universality at the quantum critical point.

    3. Introduce microscopic theories to describe the quantum phase transition, and explicitly show the vanishing of energy scales and the critical exponents.

    4. Illustrate the emergent Lorentz symmetry and the Higgs mode at the quantum critical point of the Bose-Hubbard model with the particle-hole symmetry.

    5. Discuss an experimental probe of the superfluid to the Mott insulator phase transition.

    6. Show that the repulsive and the attractive Fermi-Hubbard models are related by the particle-hole symmetry.

    7. Discuss the origin of antiferromagnetic order in the repulsive Fermi-Hubbard model at half-filling.

    8. Introduce the enlarged $SO(4)$ symmetry of the Fermi-Hubbard model at half-filling and zero spin imbalance and its physical concequence.

    9. Introduce important unsolved challenge issues in the Fermi-Hubbard model.

    10. Introduce the concept of eigenstate thermalization hypothesis and many-body localization as opposite to thermalization.

    11. Introduce a few metrics to characterize the many-body localization.

    12. Emphasize the role of entanglement entropy in characterizing quantum thermalization, and discuss how to measure entanglement entropy in ultracold atom systems.

  • 5 - The Fermi Liquid

  • from Part III - Degenerate Fermi Gases
  • Hui Zhai, Tsinghua University, Beijing
  • Book:
    Ultracold Atomic Physics
    Published online:
    30 January 2021
    Print publication:
    25 February 2021, pp 155-171

  • Summary

    1. Introduce density distribution and momentum distribution of non-interacting Fermi gas.

    2. Discuss the transport property of a Fermi gas through a quantum point contact.

    3. Discuss Fermi surface as a key of a non-interacting Fermi gas and its generalization to a Fermi liquid.

    4. Introduce the effective mass and the quasi-particle residue as two key parameters of the Fermi liquid.

    5. Introduce the self-energy and the universal relations between the effective mass, the quasi-particle residue and the self-energy.

    6. Discuss Fermi polaron as an example of the Fermi liquid, and show these universal relations with this example.

    7. Discuss the divergence of the effective mass and vanishing of quasi-particle residue when Fermi liquid description fails.

    8. Introduce the radio-frequency spectroscopy and how it measures the polaron energy and the quasi-particle residue.

    9. Summarize different spectroscopy measurements in ultracold atomic systems.