Gold nanoshells with varying morphologies through templated surfactant‐assisted seed‐growth method

Plasmonic nanoparticles exhibit dramatic changes in optical properties depending on their spatial organization. Therefore, the ability to precisely control their assembly structure is important for both fundamental understanding and practical applications. In this personal account, we describe a tem...

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Published inBulletin of the Korean Chemical Society Vol. 45; no. 6; pp. 486 - 494
Main Authors Lee, Sunghee, Lee, Soyun, Hwang, Soojin, Park, So‐Jung
Format Journal Article
LanguageEnglish
Published Weinheim Wiley‐VCH Verlag GmbH & Co. KGaA 01.06.2024
대한화학회
Subjects
metal nanoshell
optical magnetism
plasmonic
SERS
synthesis
화학
Online AccessGet full text
ISSN1229-5949
0253-2964
1229-5949
DOI10.1002/bkcs.12845

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Abstract Plasmonic nanoparticles exhibit dramatic changes in optical properties depending on their spatial organization. Therefore, the ability to precisely control their assembly structure is important for both fundamental understanding and practical applications. In this personal account, we describe a templated surfactant‐assisted seed‐growth method to synthesize core–shell‐type gold nanoparticle assemblies with controllable surface morphologies and optical properties. This approach provides a simple procedure for simultaneous growth and assembly of metal nanoparticles on polymer templates, producing well‐defined nanostructures such as spiky nanoshells and raspberry‐like metamolecules with useful and interesting optical properties, such as strong and uniform surface‐enhanced Raman scattering and metamaterial properties. We discuss the factors that control the morphology and collective properties, describe the design rules acquired from the system, and suggest future directions of this research area. The synthetic approach reviewed in this paper offers an alternative strategy to typical self‐assembly methods for controlled assembly of metal nanoparticles. This method, based on templated seed‐mediated metal growth, produces various types of metal nanoshells such as continuous or spiky nanoshells, as well as raspberry‐like metamolecules with unique optical properties, including strong and distance‐independent SERS, heterogeneity‐driven quadrupole‐enhanced SERS, and strong magnetic resonances with broad extinction spectra. This account discusses the factors that control the morphology and optical properties and suggests future directions in this field.
AbstractList Plasmonic nanoparticles exhibit dramatic changes in optical properties depending on their spatial organization. Therefore, the ability to precisely control their assembly structure is important for both fundamental understanding and practical applications. In this personal account, we describe a templated surfactant‐assisted seed‐growth method to synthesize core–shell‐type gold nanoparticle assemblies with controllable surface morphologies and optical properties. This approach provides a simple procedure for simultaneous growth and assembly of metal nanoparticles on polymer templates, producing well‐defined nanostructures such as spiky nanoshells and raspberry‐like metamolecules with useful and interesting optical properties, such as strong and uniform surface‐enhanced Raman scattering and metamaterial properties. We discuss the factors that control the morphology and collective properties, describe the design rules acquired from the system, and suggest future directions of this research area. The synthetic approach reviewed in this paper offers an alternative strategy to typical self‐assembly methods for controlled assembly of metal nanoparticles. This method, based on templated seed‐mediated metal growth, produces various types of metal nanoshells such as continuous or spiky nanoshells, as well as raspberry‐like metamolecules with unique optical properties, including strong and distance‐independent SERS, heterogeneity‐driven quadrupole‐enhanced SERS, and strong magnetic resonances with broad extinction spectra. This account discusses the factors that control the morphology and optical properties and suggests future directions in this field.
Plasmonic nanoparticles exhibit dramatic changes in optical properties depending on their spatial organization. Therefore, the ability to precisely control their assembly structure is important for both fundamental understanding and practical applications. In this personal account, we describe a templated surfactant‐assisted seed‐growth method to synthesize core–shell‐type gold nanoparticle assemblies with controllable surface morphologies and optical properties. This approach provides a simple procedure for simultaneous growth and assembly of metal nanoparticles on polymer templates, producing well‐defined nanostructures such as spiky nanoshells and raspberry‐like metamolecules with useful and interesting optical properties, such as strong and uniform surface‐enhanced Raman scattering and metamaterial properties. We discuss the factors that control the morphology and collective properties, describe the design rules acquired from the system, and suggest future directions of this research area.
Plasmonic nanoparticles exhibit dramatic changes in optical properties depending on their spatial organization. Therefore, the ability to precisely control their assembly structure is important for both fundamental understanding and practical applications. In this personal account, we describe a templated surfactant‐assisted seed‐growth method to synthesize core–shell‐type gold nanoparticle assemblies with controllable surface morphologies and optical properties. This approach provides a simple procedure for simultaneous growth and assembly of metal nanoparticles on polymer templates, producing well‐defined nanostructures such as spiky nanoshells and raspberry‐like metamolecules with useful and interesting optical properties, such as strong and uniform surface‐enhanced Raman scattering and metamaterial properties. We discuss the factors that control the morphology and collective properties, describe the design rules acquired from the system, and suggest future directions of this research area. Plasmonic nanoparticles exhibit dramatic changes in optical properties depending on their spatial organization. Therefore, the ability to precisely control their assembly structure is important for both fundamental understanding and practical applications. In this personal account, we describe a templated surfactant-assisted seed-growth method to synthesize core–shell-type gold nanoparticle assemblies with controllable surface morphologies and optical properties. This approach provides a simple procedure for simultaneous growth and assembly of metal nanoparticles on polymer templates, producing well-defined nanostructures such as spiky nanoshells and raspberry-like metamolecules with useful and interesting optical properties, such as strong and uniform surface-enhanced Raman scattering and metamaterial properties. We discuss the factors that control the morphology and collective properties, describe the design rules acquired from the system, and suggest future directions of this research area. KCI Citation Count: 0
Author Lee, Soyun
Hwang, Soojin
Lee, Sunghee
Park, So‐Jung
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Notes Dedicated to Professor Sung‐Jin Kim's achievements and contributions to scientific societies in Korea.
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Snippet Plasmonic nanoparticles exhibit dramatic changes in optical properties depending on their spatial organization. Therefore, the ability to precisely control...
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SubjectTerms metal nanoshell
optical magnetism
plasmonic
SERS
synthesis
화학
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Title Gold nanoshells with varying morphologies through templated surfactant‐assisted seed‐growth method
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