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手性等离子体液晶金纳米颗粒:自组装成圆二色性响应螺旋层状超结构。

Chiral plasmonic liquid crystal gold nanoparticles: self-assembly into a circular dichroism responsive helical lamellar superstructure.

作者信息

Bhat Sachin A, Rao D S Shankar, Prasad S Krishna, Yelamaggad Channabasaveshwar V

机构信息

Centre for Nano and Soft Matter Sciences (CeNS) P. B. No. 1329, Prof. U. R. Rao Road, Jalahalli Bengaluru 560012 India

Department of Chemistry, Mangalore University Mangalagangotri 574 199 India.

出版信息

Nanoscale Adv. 2021 Feb 19;3(8):2269-2279. doi: 10.1039/d0na01070g. eCollection 2021 Apr 20.

DOI:10.1039/d0na01070g
PMID:36133755
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9419753/
Abstract

Owing to their proven and promising potential in various technological endeavors ranging from catalysis and sensing to invisibility cloaks made from metamaterials, chiral plasmonic superstructures resulting from the directed self-assembly of optically active metal nanoparticles (MNPs) have been pursued intensively in recent years. Several strategic efforts have emerged especially to accomplish advanced nanomaterials assembling into liquid crystalline (LC) helical structures, where MNPs are regularly packed in fluid/frozen arrays/layers or wires (columns). While the helical fluid columnar arrays (molecular wires) showing circular dichroism (CD) have been realized, the discovery of fluid chiral lamellar ordering, where the dielectric and conducting regimes are arranged alternatively, has hitherto remained highly elusive. Herein we report the first examples of monodisperse LC-gold NPs (LC-GNPs) self-assembling into a fluid/frozen lamellar structure exhibiting CD activity. Notably, these new, exceptional LC-GNPs have been realized by simple, hassle-free protocols that involve the room temperature addition of LC dimer-like arylamines to Au(iii), where the amines not only reduce Au(iii) to Au(0) but also bind strongly to the central GNP scaffold. Their molecular structure, mesomorphism, and ability to interact with circularly polarized light have been evidenced unambiguously and could play an important role in realizing metamaterials in the visible region.

摘要

由于其在从催化、传感到超材料隐身衣等各种技术领域中已被证实且颇具潜力,近年来,由光学活性金属纳米颗粒(MNP)定向自组装形成的手性等离子体超结构受到了广泛研究。特别是出现了几项战略举措,以实现先进的纳米材料组装成液晶(LC)螺旋结构,其中MNP规则地排列在流体/冷冻阵列/层或线(柱)中。虽然已经实现了显示圆二色性(CD)的螺旋流体柱状阵列(分子线),但迄今为止,介电和导电区域交替排列的流体手性层状有序的发现仍然非常难以捉摸。在此,我们报告了单分散液晶-金纳米颗粒(LC-GNP)自组装成具有CD活性的流体/冷冻层状结构的首个实例。值得注意的是,这些新型的、特殊的LC-GNP是通过简单、便捷的方案实现的,该方案涉及在室温下将类似液晶二聚体的芳胺添加到Au(iii)中,其中胺不仅将Au(iii)还原为Au(0),还与中心GNP支架强烈结合。它们的分子结构、介晶性以及与圆偏振光相互作用的能力已得到明确证实,并且可能在可见光区域实现超材料方面发挥重要作用。

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