Graph-theoretical chirality measure and chirality–property relations for chemical structures with multiscale mirror asymmetries

IF 2.8 4区 化学 Q2 CHEMISTRY, ANALYTICAL
Chirality Pub Date : 2024-06-10 DOI:10.1002/chir.23678
Minjeong Cha, Jessica Ma, Ji-Young Kim, Emine Sumeyra Turali Emre, Nicholas A. Kotov
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Abstract

Chirality is an essential geometric property unifying small molecules, biological macromolecules, inorganic nanomaterials, biological microparticles, and many other chemical structures. Numerous chirality measures have attempted to quantify this geometric property of mirror asymmetry and to correlate these measures with physical and chemical properties. However, their utility has been widely limited because these correlations have been largely notional. Furthermore, chirality measures also require prohibitively demanding computations, especially for chiral structures comprised of thousands of atoms. Acknowledging the fundamental problems with quantification of mirror asymmetry, including the ambiguity of sign-variable pseudoscalar chirality measures, we revisit this subject because of the significance of quantifying chirality for quantitative biomimetics and describing the chirality of nanoscale materials that display chirality continuum and scale-dependent mirror asymmetry. We apply the concept of torsion within the framework of differential geometry to the graph theoretical representation of chiral molecules and nanostructures to address some of the fundamental problems and practical limitations of other chirality measures. Chiral gold clusters and other chiral structures are used as models to elaborate a graph-theoretical chirality (GTC) measure, demonstrating its applicability to chiral materials with different degrees of chirality at different scales. For specific cases, we show that GTC provides an adequate description of both the sign and magnitude of mirror asymmetry. The direct correlations with macroscopic properties, such as chiroptical spectra, are enhanced by using the hybrid chirality measures combining parameters from discrete mathematics and physics. Taking molecular helices as an example, we established a direct relation between GTC and optical activity, indicating that this chirality measure can be applied to chiral metamaterials and complex chiral constructs.

Abstract Image

具有多尺度镜像不对称的化学结构的图论手性度量和手性-属性关系。
手性是统一小分子、生物大分子、无机纳米材料、生物微粒和许多其他化学结构的基本几何特性。许多手性测量方法都试图量化这种镜像不对称的几何特性,并将这些测量方法与物理和化学特性联系起来。然而,由于这些相关性在很大程度上是名义上的,因此其实用性受到了广泛限制。此外,手性测量还需要进行高得令人望而却步的计算,特别是对于由数千个原子组成的手性结构。我们认识到镜像不对称性量化的基本问题,包括符号可变伪标量手性测量的模糊性,因此我们重新探讨了这一主题,因为量化手性对于定量生物仿生学和描述显示手性连续性和尺度依赖性镜像不对称性的纳米材料的手性具有重要意义。我们将微分几何框架内的扭转概念应用于手性分子和纳米结构的图论表示,以解决其他手性度量方法的一些基本问题和实际限制。我们以手性金簇和其他手性结构为模型,阐述了图论手性(GTC)度量,证明它适用于不同尺度、不同手性程度的手性材料。在特定情况下,我们证明 GTC 能够充分描述镜像不对称的符号和大小。通过使用结合离散数学和物理学参数的混合手性度量,增强了与宏观特性(如自旋光谱)的直接相关性。以分子螺旋为例,我们建立了 GTC 与光学活性之间的直接关系,表明这种手性度量可用于手性超材料和复杂的手性结构。
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来源期刊
Chirality
Chirality 医学-分析化学
CiteScore
4.40
自引率
5.00%
发文量
124
审稿时长
1 months
期刊介绍: The main aim of the journal is to publish original contributions of scientific work on the role of chirality in chemistry and biochemistry in respect to biological, chemical, materials, pharmacological, spectroscopic and physical properties. Papers on the chemistry (physiochemical, preparative synthetic, and analytical), physics, pharmacology, clinical pharmacology, toxicology, and other biological aspects of chiral molecules will be published.
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