Benjamin M. Spar scite author profile

Using quantum gas microscopy we study the late-time effective hydrodynamics of an isolated cold-atom Fermi-Hubbard system subject to an external linear potential (a "tilt"). The tilt is along one of the principal directions of the two-dimensional (2D) square lattice and couples mass transport to local heating through energy conservation. We study transport and thermalization in our system by observing the decay of prepared initial density waves as a function of wavelength λ and tilt strength and find that the associated decay time τ crosses over as the tilt strength is increased from characteristically diffusive to subdiffusive with τ ∝ λ 4 . In order to explain the underlying physics we develop a hydrodynamic model that exhibits this crossover. For strong tilts, the subdiffusive transport rate is set by a thermal diffusivity, which we are thus able to measure as a function of tilt in this regime. We further support our understanding by probing the local inverse temperature of the system at strong tilts, finding good agreement with our theoretical predictions. Finally, we discuss the relation of the strongly tilted limit of our system to recently studied 1D models which may exhibit nonergodic dynamics. arXiv:1909.05848v1 [cond-mat.quant-gas]

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Quench Dynamics of a Fermi Gas with Strong Nonlocal Interactions

Guardado-Sanchez

Spar

Schauß

et al. 2021

Phys. Rev. X

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We induce strong nonlocal interactions in a 2D Fermi gas in an optical lattice using Rydberg dressing. The system is approximately described by a t − V model on a square lattice where the fermions experience isotropic nearest-neighbor interactions and are free to hop only along one direction. We measure the interactions using many-body Ramsey interferometry and study the lifetime of the gas in the presence of tunneling, finding that tunneling does not reduce the lifetime. To probe the interplay of nonlocal interactions with tunneling, we investigate the short-time-relaxation dynamics of charge-density waves in the gas. We find that strong nearest-neighbor interactions slow down the relaxation. Our work opens the door for quantum simulations of systems with strong nonlocal interactions such as extended Fermi-Hubbard models.

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Angle-resolved photoemission spectroscopy of a Fermi–Hubbard system

et al. 2019

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Angle-resolved photoemission spectroscopy (ARPES) measures the single-particle excitations of a many-body quantum system with both energy and momentum resolution, providing detailed information about strongly interacting materials [1]. ARPES is a direct probe of fermion pairing, and hence a natural technique to study the development of superconductivity in a variety of experimental systems ranging from high temperature superconductors to unitary Fermi gases. In these systems a remnant gap-like feature persists in the normal state, which is referred to as a pseudogap [2]. A quantitative understanding of pseudogap regimes may elucidate details about the pairing mechanisms that lead to superconductivity, but developing 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 to quantum Monte Carlo calculations. We find evidence for a pseudogap in our system 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].Photoemission spectroscopy measures the occupied single-particle spectral function [1,4,5], which describes the allowed energies for a single-particle excitation with given momentum. ARPES has been used to study the presence of a Fermi surface, the lifetime of quasiparticles, superconducting gaps and their symmetries, and surface states in topological materials [6,7]. It is illustrative to consider some generic features of the spectral function as we introduce interactions. For a non-interacting system with dispersion k , the single-particle excitations are eigenstates of the system implying they have a definite energy and infinite lifetime. The spectral function is a delta function, A(k, ω) = δ(ω − k + µ) where µ is the chemical potential. Turning on weak interactions may create a Fermi liquid state, where the spectral function has a similar form but broadens along the energy axis reflecting the finite lifetime of the quasiparticles. In superconducting systems, more radical changes may occur including the development of a gap separating two disconnected spectral function branches. In weak coupling (BCS) superconductors, the gap vanishes at the critical temperature. However in many strongly-interacting superconducting systems including the high-temperature cuprate superconductors (HTSCs) and the unitary Fermi gas, a depression in the spectral weight at the chemical potential persists in the normal state [2,[8][9][10][11][12][13][14]. These so called pseudogap states might arise from the same pairing mechanism as the superconducting ground states, and developing a better understand...

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Realization of a Fermi-Hubbard Optical Tweezer Array

et al. 2022

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We use lithium-6 atoms in an optical tweezer array to realize an eight-site Fermi-Hubbard chain near half filling. We achieve single site detection by combining the tweezer array with a quantum gas microscope. By reducing disorder in the energy offsets to less than the tunneling energy, we observe Mott insulators with strong antiferromagnetic correlations. The measured spin correlations allow us to put an upper bound on the entropy of 0.26(4) kB per atom, comparable to the lowest entropies achieved with optical lattices. Additionally, we establish the flexibility of the tweezer platform by initializing atoms on one tweezer and observing tunneling dynamics across the array for uniform and staggered 1D geometries.

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Two-Dimensional Programmable Tweezer Arrays of Fermions

et al. 2022

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Benjamin M. Spar

Subdiffusion and Heat Transport in a Tilted Two-Dimensional Fermi-Hubbard System

Quench Dynamics of a Fermi Gas with Strong Nonlocal Interactions

Angle-resolved photoemission spectroscopy of a Fermi–Hubbard system

Realization of a Fermi-Hubbard Optical Tweezer Array

Two-Dimensional Programmable Tweezer Arrays of Fermions

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