Angle-resolved photoemission spectroscopy of a Fermi–Hubbard system

Angle-resolved photoemission spectroscopy (ARPES) measures the single-particle excitations of a many-body quantum system with energy and momentum resolution, providing detailed information about strongly interacting materials 1 . ARPES directly probes fermion pairing, and hence is a natural techniqu...

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Bibliographic Details
Published in:Nature physics 2020-01, Vol.16 (1), p.26-31
Main Authors: Brown, Peter T., Guardado-Sanchez, Elmer, Spar, Benjamin M., Huang, Edwin W., Devereaux, Thomas P., Bakr, Waseem S.
Format: Article
Language:English
Subjects:
639/766/36/1125
639/766/483/3926
Atomic
Classical and Continuum Physics
Complex Systems
Computer simulation
Condensed Matter Physics
Excitation
Fermi gases
Fermions
High temperature
High temperature superconductors
Letter
Mathematical and Computational Physics
Molecular
Monte Carlo simulation
Optical and Plasma Physics
Optical lattices
Photoelectric emission
Photoelectron spectroscopy
Physics
Physics and Astronomy
PHYSICS OF ELEMENTARY PARTICLES AND FIELDS
Quantum theory
Spectroscopy
Spectrum analysis
Superconductivity
Superfluidity
Theoretical
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Summary:Angle-resolved photoemission spectroscopy (ARPES) measures the single-particle excitations of a many-body quantum system with energy and momentum resolution, providing detailed information about strongly interacting materials 1 . ARPES directly probes fermion pairing, and hence is a natural technique to study the development of superconductivity in systems ranging from high-temperature superconductors to unitary Fermi gases. In these systems, a remnant gap-like feature persists in the normal state 2 . Developing a quantitative understanding of these so-called pseudogap regimes may elucidate details about the pairing mechanisms that lead to superconductivity, but this is difficult in real materials partly because the microscopic Hamiltonian is not known. Here, we report on the development of ARPES to study strongly interacting fermions in an optical lattice using a quantum gas microscope. We benchmark the technique by measuring the occupied single-particle spectral function of an attractive Fermi–Hubbard system across the BCS–BEC crossover and comparing the results to those of quantum Monte Carlo calculations. We find evidence for a pseudogap that opens well above the expected critical temperature for superfluidity. This technique may also be applied to the doped repulsive Hubbard model, which is expected to exhibit a pseudogap at temperatures close to those achieved in recent experiments 3 . A technique analogous to angle-resolved photoemission spectroscopy used in materials characterization has been developed for interacting Fermi gases in an optical lattice, providing information on the single-particle excitations in a many-body system.
ISSN:1745-2473
1745-2481
DOI:10.1038/s41567-019-0696-0