Fermions in 2D Optical Lattices: Temperature and Entropy Scales for Observing Antiferromagnetism and Superfluidity

TL;DR

This paper investigates the entropy and temperature constraints necessary to observe antiferromagnetism and superfluidity in 2D optical lattices of fermions, using quantum Monte Carlo simulations to identify key experimental thresholds.

Contribution

It provides the first detailed analysis of entropy limits for observing these phases in 2D Hubbard models and assesses cooling strategies and thermometry methods.

Findings

Entropy per particle ~log(2) suffices to observe charge gap or pairing pseudogap.

Achieving antiferromagnetic or superfluid phases requires reducing entropy by a factor of three.

Adiabatic cooling is ineffective in 2D for reaching the necessary low temperatures.

Abstract

One of the major challenges in realizing antiferromagnetic and superfluid phases in optical lattices is the ability to cool fermions. We determine constraints on the entropy for observing these phases in two-dimensional Hubbard models. We investigate antiferromagnetic correlations in the repulsive model at half filling and superfluidity of s-wave pairs in the attractive case away from half filling using determinantal quantum Monte Carlo simulations that are free of the fermion sign problem. We find that an entropy per particle ~log(2) is sufficient to observe the charge gap in the repulsive Hubbard model or the pairing pseudogap in the attractive case. Observing antiferromagnetic correlations or superfluidity in 2D systems requires a further reduction in entropy by a factor of three or more. In contrast to higher dimensions, we find that adiabatic cooling is not useful to achieve the required low temperatures. We also show that double occupancy measurements are useful for thermometry for temperatures greater than the nearest-neighbor hopping.