Analytical expression for $π$-ton vertex contributions to the optical conductivity

arXiv - PHYS - Strongly Correlated Electrons Pub Date : 2024-09-17 DOI:arxiv-2409.11158

Juraj Krsnik, Anna Kauch, Karsten Held

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Abstract

Vertex corrections from the transversal particle-hole channel, so-called $\pi$-tons, are generic in models for strongly correlated electron systems and can lead to a displaced Drude peak (DDP). Here, we derive the analytical expression for these $\pi$-tons, and how they affect the optical conductivity as a function of correlation length $\xi$, fermion lifetime $\tau$, temperature $T$, and coupling strength to spin or charge fluctuations $g$. In particular, for $T\rightarrow T_c$, the critical temperature for antiferromagnetic or charge ordering, the dc vertex correction is algebraic $\sigma_{VERT}^{dc}\propto \xi \sim (T-T_c)^{-\nu}$ in one dimension and logarithmic $\sigma_{VERT}^{dc}\propto \ln\xi \sim \nu \ln (T-T_c)$ in two dimensions. Here, $\nu$ is the critical exponent for the correlation length. If we have the exponential scaling $\xi \sim e^{1/T}$ of an ideal two-dimensional system, the DDP becomes more pronounced with increasing $T$ but fades away at low temperatures where only a broadening of the Drude peak remains, as it is observed experimentally. Further, we find the maximum of the DPP to be given by the inverse lifetime: $\omega_{DDP} \sim 1/\tau$. These characteristic dependencies can guide experiments to evidence $\pi$-tons in actual materials.

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π$吨顶点对光传导性贡献的分析表达式

来自横向粒子-空穴通道的顶点修正，即所谓的$\pi$-ton，是强相关电子系统模型中的通用修正，并可能导致德鲁德峰值（DDP）的移位。在这里，我们推导出了这些$\pi$-吨的分析表达式，以及它们如何影响光导率作为相关长度$\xi$、费米子寿命$\tau$、温度$T$以及自旋或电荷波动耦合强度$g$的函数。特别是，对于反铁磁或电荷有序的临界温度 $T\rightarrow T_c$，直流顶点修正是代数的、直流顶点校正在一维中是代数的$\sigma_{VERT}^{dc}\propto \xi \sim (T-T_c)^{-\nu}$ ，在二维中是对数的$\sigma_{VERT}^{dc}\propto \lnxi \sim \nu \ln (T-T_c)$。这里，$\nu$ 是相关长度的临界指数。如果我们有理想二维系统的指数缩放 $\xi \sim e^{1/T}$，那么 DDP 会随着 $T$ 的增加而变得更加明显，但在低温下会逐渐消失，此时只剩下德鲁德峰值的扩大，正如实验所观察到的那样。此外，我们发现 DPP 的最大值由反寿命给出：$\omega_{DDP}.\sim 1/\tau$。这些特征依赖性可以指导实验来证明实际材料中的 $\pi$-吨。

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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arXiv - PHYS - Strongly Correlated Electrons

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