The interplay between quantum magnetism and strong correlation in geometrically frustrated materials

量子磁性与几何受挫材料中强相关性之间的相互作用

• 批准号: 355396-2008
• 负责人: Hopkinson, John
• 金额: $ 1.14万
• 依托单位: Brandon University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2008
• 资助国家: 加拿大
• 起止时间: 2008-01-01 至 2009-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=402508
• 关键词: interplay; between; quantum; magnetism; strong

An important goal of research, driving the development of new materials, is the discovery of the physical mechanisms behind novel phenomena. In many interesting materials, the collective properties of the electrons and their spins (intrinsic angular momentum vectors associated to the electron) vary greatly from the expectations of single particle physics, leading to observable emergent properties. Such materials are referred to as strongly correlated materials, as, if the spin at one site points in a particular direction, the direction of the spin at a neighbouring site is highly correlated with the first. Materials where the electrostatic interactions energetically favour the alignment of neighbouring spins are referred to as ferromagnets (like the bar magnet on a fridge). Antiferromagnets are more common, and favour the antialignment of neighbouring spins. If a lattice of spins is made of equilateral triangles or tetrahedra, and the bonds of the lattice have antiferromagnetic interactions, the spins cannot all antialign with their neighbours. This leads to there being many equal energy or degenerate states and the spin structure doesn't know which arrangement to choose. Materials with magnetic lattices built of corner-shared triangles and tetrahedra are referred to as geometrically frustrated materials. The goal of this program is to explain and predict exotic properties of new materials which may arise due to the frustration of the magnetic interactions between spins, particularly those which may arise due to quantum effects. This work is motivated by the discovery of new low spin (and therefore highly quantum mechanical) magnetically frustrated materials, both metallic and insulating. This work will consider magnetic systems which do not order to very low temperatures and ask what properties of such materials are generic to all frustrated lattices. This program will investigate the possibility that some materials that have not yet been classified as frustrated materials, yet have also not been understood theoretically, may additionally fall into this class of materials. These issues will be addressed through the use of a variety of numerical and analytic theoretical techniques.

推动新材料开发的一个重要研究目标是发现新现象背后的物理机制。 在许多有趣的材料中，电子及其自旋（与电子相关的固有角动量矢量）的集体性质与单粒子物理学的预期有很大差异，导致可观察到的涌现性质。 这种材料被称为强相关材料，因为如果一个位置的自旋指向特定方向，则相邻位置的自旋方向与第一个位置高度相关。 静电相互作用在能量上有利于相邻自旋对齐的材料被称为铁磁体（就像冰箱上的条形磁铁）。 反铁磁体更常见，并且有利于相邻自旋的反排列。 如果一个自旋晶格是由等边三角形或四面体组成的，并且晶格中的键具有反铁磁相互作用，那么这些自旋不可能都与它们的邻居反排列。 这导致存在许多等能量或简并态，并且自旋结构不知道选择哪种排列。 具有由角共享三角形和四面体构建的磁晶格的材料被称为几何阻挫材料。 该计划的目标是解释和预测新材料的奇异特性，这些特性可能是由于自旋之间的磁相互作用的挫折而产生的，特别是那些可能由于量子效应而产生的特性。 这项工作的动机是发现新的低自旋（因此高度量子力学）磁阻挫材料，包括金属和绝缘材料。 这项工作将考虑磁系统，不为了非常低的温度，并询问这些材料的属性是通用的所有挫折晶格。 该计划将调查一些尚未被归类为挫折材料的材料，但理论上也没有被理解的可能性，也可能属于这类材料。 这些问题将通过使用各种数值和分析理论技术来解决。