Second-Neighbor Hopping Effects in the Two-Dimensional Attractive Hubbard Model

IF 1.9 Q3 PHYSICS, CONDENSED MATTER

Condensed Matter Pub Date : 2023-01-17 DOI:10.3390/condmat8010011

Rodrigo A. Fontenele, Nathan Vasconcelos, N. Costa, T. Paiva, R. R. dos Santos

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Abstract

The emergence of superconductivity (SC) in lattice models, such as the attractive Hubbard one, has renewed interest since the realization of cold-atom experiments. However, reducing the temperature in these experiments is a bottleneck; therefore, investigating how to increase the energy scale for SC is crucial to cold atoms. In view of this, we examine the effects of next-nearest-neighbor hoppings (t′) on the pairing properties of the attractive Hubbard model in a square lattice. To this end, we analyze the model through unbiased Quantum Monte Carlo simulations for fixed density n=0.87, and perform finite-size scaling analysis to the thermodynamic limit. As our main result, we notice that the existence of further hopping channels leads to an enhancement of the pairing correlations, which, in turn, increases the ground-state order parameter Δ. Finally, at finite temperatures, for t′/t≠0, this enhancement of pairing correlations leads to an increase in the critical temperature Tc. That is, the fine-tuning of second-neighbor hoppings increases the energy scales for SC, and may be a route by which cold-atom experiments can achieve such a phase and to help us further understand the nature of this phenomenon.

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二维吸引Hubbard模型中的第二邻居跳跃效应

自冷原子实验实现以来，晶格模型中超导性(SC)的出现重新引起了人们的兴趣，例如吸引人的Hubbard模型。然而，在这些实验中降低温度是一个瓶颈;因此，研究如何提高SC的能量尺度对冷原子来说至关重要。鉴于此，我们研究了次近邻跳跃(t ')对方形晶格中吸引Hubbard模型的配对性质的影响。为此，我们通过无偏量子蒙特卡罗模拟分析了固定密度n=0.87的模型，并对热力学极限进行了有限尺寸的缩放分析。作为我们的主要结果，我们注意到进一步的跳频通道的存在导致配对相关性的增强，这反过来又增加了基态序参数Δ。最后，在有限温度下，当t′/t≠0时，配对相关性的增强导致临界温度Tc的增加。也就是说，第二近邻跳跃的微调增加了SC的能量尺度，并且可能是冷原子实验可以实现这样一个阶段的途径，并帮助我们进一步理解这种现象的本质。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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