Two-Dimensional Discommensurations: An Extension to McMillan’s Ginzburg–Landau Theory

IF 1.9 Q3 PHYSICS, CONDENSED MATTER

Condensed Matter Pub Date : 2023-09-08 DOI:10.3390/condmat8040100

L. Mertens, Jeroen van den Brink, J. V. Wezel

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Abstract

Charge density waves (CDWs) profoundly affect the electronic properties of materials and have an intricate interplay with other collective states, like superconductivity and magnetism. The well-known macroscopic Ginzburg–Landau theory stands out as a theoretical method for describing CDW phenomenology without requiring a microscopic description. In particular, it has been instrumental in understanding the emergence of domain structures in several CDW compounds, as well as the influence of critical fluctuations and the evolution towards or across lock-in transitions. In this context, McMillan’s foundational work introduced discommensurations as the objects mediating the transition from commensurate to incommensurate CDWs, through an intermediate nearly commensurate phase characterised by an ordered array of phase slips. Here, we extended the simplified, effectively one-dimensional, setting of the original model to a fully two-dimensional analysis. We found exact and numerical solutions for several types of discommensuration patterns and provide a framework for consistently describing multi-component CDWs embedded in quasi-two-dimensional atomic lattices.

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二维反相：麦克米兰金兹堡-朗道理论的扩展

电荷密度波（CDW）深刻影响着材料的电子特性，并与超导性和磁性等其他集合态有着错综复杂的相互作用。众所周知的宏观金兹堡-朗道（Ginzburg-Landau）理论是描述电荷密度波现象而无需微观描述的突出理论方法。特别是，它有助于理解几种 CDW 化合物中出现的畴结构，以及临界波动的影响和向锁定转变或跨越锁定转变的演化。在此背景下，麦克米伦的奠基性工作引入了反相位，将其作为介导从相称到不相称 CDW 过渡的对象，中间的近相称阶段以有序的相位滑移阵列为特征。在此，我们将原始模型的简化、有效的一维设置扩展到完全的二维分析。我们找到了几种不相容模式的精确解和数值解，并提供了一个框架，用于一致地描述嵌入准二维原子晶格中的多组分 CDW。

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