Self-Assembled Colloidal Superparticles from Nanorods

Wang, Tie; Zhuang, Jiaqi; Lynch, Jared; Chen, Ou; Wang, Zhongliang; Wang, Xirui; LaMontagne, Derek; Wu, Huimeng; Wang, Zhongwu; Cao, Y. Charles

doi:10.1126/science.1224221

Cited by 336 publications

(370 citation statements)

References 28 publications

(37 reference statements)

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“…Such binary nanoparticle superstructures have been well developed for several metals and chalcogenides but not yet for semiconductor metal oxides. [93][94][95] Experiments on a single-particle assembly have revealed that ordered superstructures produce a high yield of photogenerated charges and have high photoconductivity, which are difficult to achieve using traditional disordered systems consisting of crystalline nanoparticles owing to the inevitable occurrence of charge recombination at the internal interface. The Majima group used singlemolecule, single-particle fluorescence microscopy to show that photogenerated electrons could reach reactive sites over a micrometer distance and are preferentially trapped at the edge of plate-like TiO 2 MCs, in which {101} facets are predominantly exposed.…”

Section: Summary and Perspectivesmentioning

confidence: 99%

Metal oxide mesocrystals with tailored structures and properties for energy conversion and storage applications

Tachikawa

Majima

2014

NPG Asia Mater

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Mesocrystals (MCs) are superstructures with a crystallographically ordered alignment of nanoparticles. Owing to their organized structures, MCs posses some unique characteristics such as a high surface area, pore accessibility, and good electronic conductivity and thermal stability; thus, MCs could be beneficial for many areas of research and application. This review begins with a description of the common synthesis strategies for, and characterization and fundamental properties of metal oxide MCs. Newly developed analytical methods (that is, photoconductive atomic force microscopy and single-molecule, single-particle fluorescence microscopy) for unraveling the charge transport and photocatalytic properties of individual MCs are then introduced. Further, recent developments in the applications of various metal oxide MCs, especially in the fields of energy conversion and storage, are also reviewed. Finally, several perspectives in terms of future research on MCs are highlighted. NPG Asia Materials (2014) 6, e100; doi:10.1038/am.2014.21; published online 16 May 2014 Keywords: energy storage; mesocrystal; metal oxide; photocatalysis; solar energy conversion; superstructure INTRODUCTIONThe self-assembly of nanoparticle building blocks into highly ordered superstructures is one of the actively pursued research topics in materials science and technology. 1-4 Such hierarchical architectures have potentially tunable electronic, optical and magnetic properties, which promise various applications ranging from catalysis to optoelectronics. A mesocrystal (MC), which was first introduced by Cölfen in the early years of 2000s, is defined as a superstructure consisting of nanoparticles on the scale of several hundred nanometers to micrometers. [5][6][7][8][9][10][11] In contrast to the classical mechanism of atom/ ion-mediated growth of a single crystal, the particle-mediated growth mechanisms of MCs are termed as non-classical crystallization (Figure 1). This definition has been developed in recent years, where MCs are defined entirely according to their structures rather than their formation mechanism. 12 In this decade, a variety of MCs of metal oxides (for example, TiO 2 , 13-23 ZnO, [24][25][26][27][28][29][30][31][32][33][34] Among metal oxides, TiO 2 is used in many applications that deal with environmental and energy problems (for example, photodegradation of pollutants, 67 water splitting for H 2 evolution, 68 dyesensitized solar cells 68 and lithium-ion batteries 69 ) owing to its

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Section: Summary and Perspectivesmentioning

confidence: 99%

Metal oxide mesocrystals with tailored structures and properties for energy conversion and storage applications

Tachikawa

Majima

2014

NPG Asia Mater

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“…Because of interest in the diverse properties of plasmonic nanostructures, a variety of methods have been developed to assemble them 12 into two-dimensional (2D) and threedimensional (3D) hierarchical crystalline superlattices, superparticles and superstructures, including DNA-mediated 14,[20][21][22][23] , drying-forced 24,25 , entropically driven 18,26,27 and electrostatic methods 28 . In addition, recent work on plasmonic nanoparticle clusters suggests that these structures can support magnetic dipole resonances 29,30 and Fano lineshapes 31 that are dependent on the cluster size and symmetry.…”

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confidence: 99%

Using nanoscale and mesoscale anisotropy to engineer the optical response of three-dimensional plasmonic metamaterials

2014

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The a priori ability to design electromagnetic wave propagation is crucial for the development of novel metamaterials. Incorporating plasmonic building blocks is of particular interest due to their ability to confine visible light. Here we explore the use of anisotropy in nanoscale and mesoscale plasmonic array architectures to produce noble metal-based metamaterials with unusual optical properties. We find that the combination of nanoscale and mesoscale anisotropy leads to rich opportunities for metamaterials throughout the visible and nearinfrared. The low volume fraction (o5%) plasmonic metamaterials explored herein exhibit birefringence, a skin depth approaching that of pure metals for selected wavelengths, and directionally confined waves similar to those found in optical fibres. These data provide design principles with which the electromagnetic behaviour of plasmonic metamaterials can be tailored using high aspect ratio nanostructures that are accessible via a variety of synthesis and assembly methods.

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“…In summary, the self-assembly of 1D NCs usually takes place under the following situations: (1) substrates driven by evaporation under external field facilitation or template, (2) interface of liquid-liquid and gas-liquid, and (3) solution through specific chemical bond. For example, Wang et al [464] reported the construction of self-assembly from the complex building blocks of CdSe-CdS core-shell nanorods. Their strategy involves the generation of water-dispersible nanorod micelles in mixing a chloroform solution and evaporation of chloroform (Fig.…”

Section: Self-assemblymentioning

confidence: 99%

Understanding of the major reactions in solution synthesis of functional nanomaterials

Wang

2016

Sci. China Mater.

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This review covers the major reactions involved in the solution synthesis of nanomaterials. It was designed to classify the traditional strategies such as precipitation, reduction, seed growth, etching, and so on into two basic processes which are termed as bottom-up and top-down routines. The discussion is focused on the basic mechanism and principles during the nucleation and growth of nanocrystals, especially in the solution system. This review also presents a prediction for how to utilize these intrinsic processes to artificially construct the desired specific and functional nanostructures. We try to describe the most directive and effective way to control the structures of nanocrystals for researchers who can master the major reaction mechanism and grasp the basic technologies in synthetic nanoscience.

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Self-Assembled Colloidal Superparticles from Nanorods

Cited by 336 publications

References 28 publications

Metal oxide mesocrystals with tailored structures and properties for energy conversion and storage applications

Metal oxide mesocrystals with tailored structures and properties for energy conversion and storage applications

Using nanoscale and mesoscale anisotropy to engineer the optical response of three-dimensional plasmonic metamaterials

Understanding of the major reactions in solution synthesis of functional nanomaterials

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