Engineering Nanoscale Interfaces of Metal/Oxide Nanowires to Control Catalytic Activity

Song, Hee Chan; Lee, Gyu Rac; Jeon, Kiung; Lee, Hyunhwa; Lee, Si Woo; Jung, Yeon Sik; Park, Jeong Young

doi:10.1021/acsnano.0c02347

Cited by 22 publications

(11 citation statements)

References 47 publications

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“…More recently, great efforts have been devoted to enhancing the crystallization degree of mesoporous semiconductor metal oxides while maintaining their highly porous structure by using 1D nanowires as the building blocks due to their good mechanical properties and direct electronic pathways. However, the disordered stacking of nanowires by conventional methods can reduce their exposed active sites and limit their performances. − Although different methods such as the Langmuir–Blodgett (LB) technique and nanotransfer printing have been applied to construct 3D nanostructures assembled from 1D nanowires, they required tedious multistep process and failed to produce metal oxide-based 3D mesoporous nanostructures. − In the previous work, our group reported an interesting synthetic 3D mesoporous nanostructure consisting of multilayer cross-stacked nanowire arrays of Si-doped WO 3 through the coassembly of amphiphilic block copolymers (BCPs) and silicotungstic acid. Different from a typical surfactant-directed sol–gel process in conventional synthesis, the current synthesis involves an unusual self-assembly of organic–inorganic hybrid micelles, resulting in novel topological mesoporous structures, namely, 3D orthogonally cross-stacked nanowire arrays.…”

Section: Introductionmentioning

confidence: 99%

Noble Metal Nanoparticles Decorated Metal Oxide Semiconducting Nanowire Arrays Interwoven into 3D Mesoporous Superstructures for Low-Temperature Gas Sensing

Ren

Xie

et al. 2021

ACS Cent. Sci.

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Mesoporous materials have been extensively studied for various applications due to their high specific surface areas and well-interconnected uniform nanopores. Great attention has been paid to synthesizing stable functional mesoporous metal oxides for catalysis, energy storage and conversion, chemical sensing, and so forth. Heteroatom doping and surface modification of metal oxides are typical routes to improve their performance. However, it still remains challenging to directly and conveniently synthesize mesoporous metal oxides with both a specific functionalized surface and heteroatom-doped framework. Here, we report a one-step multicomponent coassembly to synthesize Pt nanoparticle-decorated Si-doped WO3 nanowires interwoven into 3D mesoporous superstructures (Pt/Si-WO3 NWIMSs) by using amphiphilic poly(ethylene oxide)-block-polystyrene (PEO-b-PS), Keggin polyoxometalates (H4SiW12O40) and hydrophobic (1,5-cyclooctadiene)dimethylplatinum(II) as the as structure-directing agent, tungsten precursor and platinum source, respectively. The Pt/Si-WO3 NWIMSs exhibit a unique mesoporous structure consisting of 3D interwoven Si-doped WO3 nanowires with surfaces homogeneously decorated by Pt nanoparticles. Because of the highly porous structure, excellent transport of carriers in nanowires, and rich WO3/Pt active interfaces, the semiconductor gas sensors based on Pt/Si-WO3 NWIMSs show excellent sensing properties toward ethanol at low temperature (100 °C) with high sensitivity (S = 93 vs 50 ppm), low detection limit (0.5 ppm), fast response–recovery speed (17–7 s), excellent selectivity, and long-term stability.

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Section: Introductionmentioning

confidence: 99%

Noble Metal Nanoparticles Decorated Metal Oxide Semiconducting Nanowire Arrays Interwoven into 3D Mesoporous Superstructures for Low-Temperature Gas Sensing

Ren

Xie

et al. 2021

ACS Cent. Sci.

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“…In addition, taking advantage of the diverse choices in the deposition materials, a heterogeneous catalyst system can be introduced from two or more choices. In summary, by a synergistic combination of BCP nanopatterning with transfer printing method, on-demand designed catalyst systems can be architectured by varying the pattern density and catalyst materials. , …”

Section: Block Copolymer Nanopatterning For Nonsemiconductor Applicat...mentioning

confidence: 99%

“…In summary, by a synergistic combination of BCP nanopatterning with transfer printing method, on-demand designed catalyst systems can be architectured by varying the pattern density and catalyst materials. 86,87 Bicontinuous 3D structures, such as gyroid and doublediamond (DD) structures, are promising materials for catalysts, because of their large specific surface area and uniform pore size throughout the film. 88,89 Moreover, the bicontinuous structure can contain large amounts of electrolytes and reactants that easily penetrate the inner space.…”

Section: Block Copolymer Nanopatterning For Nonsemiconductor Applicat...mentioning

confidence: 99%

Block Copolymer Nanopatterning for Nonsemiconductor Device Applications

Yang

Choi

Han

et al. 2022

ACS Appl. Mater. Interfaces

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Block copolymer (BCP) nanopatterning has emerged as a versatile nanoscale fabrication tool for semiconductor devices and other applications, because of its ability to organize well-defined, periodic nanostructures with a critical dimension of 5–100 nm. While the most promising application field of BCP nanopatterning has been semiconductor devices, the versatility of BCPs has also led to enormous interest from a broad spectrum of other application areas. In particular, the intrinsically low cost and straightforward processing of BCP nanopatterning have been widely recognized for their large-area parallel formation of dense nanoscale features, which clearly contrasts that of sophisticated processing steps of the typical photolithographic process, including EUV lithography. In this Review, we highlight the recent progress in the field of BCP nanopatterning for various nonsemiconductor applications. Notable examples relying on BCP nanopatterning, including nanocatalysts, sensors, optics, energy devices, membranes, surface modifications and other emerging applications, are summarized. We further discuss the current limitations of BCP nanopatterning and suggest future research directions to open up new potential application fields.

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“…Interface modification is an effective way to achieve high stability and efficient carrier transport of composite materials. Changing the interface coupling mode, [ 112–115 ] enhancing the interfacial force, [ 116–118 ] and increasing the effective sites of the interface [ 119,120 ] are all feasible approaches in the process of physical or chemical synthesis of materials to modify the interface.…”

Section: Catalytic Optimization Strategies By Microwavementioning

confidence: 99%

Microwave‐Positioning Assembly: Structure and Surface Optimizations for Catalysts

Xiao

Huo²,

Guan³

et al. 2022

Small Structures

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As an innovative synthesis and modification method for nanomaterials, microwave‐positioning assembly exhibits various advantages like low power consumption, oriented growth, and precise doping in preparing and modifying catalysts, mainly owing to the superhot characteristics under microwave irradiation. There are different types of microwave‐positioning assembly mechanisms accounting for the controlling design of the composition, structure, surface chemical state, interface bonding, and some other factors of the catalyst. This review summarizes the recent achievements on the research progress of microwave‐assisted synthesis and modification of new catalysts with the improved performances in various catalytic reactions. The problems and developments of this method in future catalyst design are simply prospected.

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Engineering Nanoscale Interfaces of Metal/Oxide Nanowires to Control Catalytic Activity

Cited by 22 publications

References 47 publications

Noble Metal Nanoparticles Decorated Metal Oxide Semiconducting Nanowire Arrays Interwoven into 3D Mesoporous Superstructures for Low-Temperature Gas Sensing

Noble Metal Nanoparticles Decorated Metal Oxide Semiconducting Nanowire Arrays Interwoven into 3D Mesoporous Superstructures for Low-Temperature Gas Sensing

Block Copolymer Nanopatterning for Nonsemiconductor Device Applications

Microwave‐Positioning Assembly: Structure and Surface Optimizations for Catalysts

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