<i>Ex Situ</i> and <i>in Situ</i> Surface Plasmon Monitoring of Temperature-Dependent Structural Evolution in Galvanic Replacement Reactions at a Single-Particle Level

Park, Youngchan; Lee, Chanhyoung; Ryu, Soojung; Song, Hyunjoon

doi:10.1021/acs.jpcc.5b05541

Cited by 17 publications

(18 citation statements)

References 47 publications

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“…In the past, we have shown (as subsequently confirmed by others) that the behavior observed in single-nanoparticle trajectories is a result of a two-step mechanism: There is a precursor step in the galvanic transformation of the nanoparticle, which involves the stochastic nucleation of a void (collection of Ag vacancies) on the surface of the Ag nanoparticle. The waiting time signifies the period before a void larger than a critical size is nucleated in the nanoparticle. Following the formation of a critical void in a nanoparticle, rapid galvanic exchange takes place across the bulk of the nanoparticle, limited only by the mass transport of depositing Au 3+ ions and/or dissolving Ag + ions.…”

Section: Methodssupporting

confidence: 57%

The Ligand Shell as an Energy Barrier in Surface Reactions on Transition Metal Nanoparticles

Smith

Jain

2016

J. Am. Chem. Soc.

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Transition metal nanoparticles, including those employed in catalytic, electrocatalytic, and photocatalytic conversions, have surfaces that are typically coated with a layer of short or long-chain ligands. There is little systematic understanding of how much this ligand layer affects the reactivity of the underlying surface. We show for Ag nanoparticles that a surface-adsorbed thiol layer greatly impedes the kinetics of an ionic chemical reaction taking place on the Ag surface. The model reaction studied is the galvanic exchange of Ag with Au(3+) ions, the kinetics of which is measured on individual thiol-coated nanoparticles using in situ optical scattering spectroscopy. We observe a systematic lowering of the reactivity of the nanoparticle as the chain length of the thiol is increased, from which we deduce that the ligand layer serves as an energy barrier to the transport of incoming/outgoing reactive ions. This barrier effect can be decreased by light irradiation, resulting from weakened binding of the thiol layer to the metal surface. We find that the influence of the surface ligand layer on reactivity is much stronger than factors such as nanoparticle size, shape, or crystallinity. These findings provide improved understanding of the role of ligand or adsorbates in colloidal catalysis and photocatalysis and have important implications for the transport of reactants and ions to surfaces and for engineering the reactivity of nanoparticles using surface passivation.

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Section: Methodssupporting

confidence: 57%

The Ligand Shell as an Energy Barrier in Surface Reactions on Transition Metal Nanoparticles

Smith

Jain

2016

J. Am. Chem. Soc.

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“…Noble metal (gold and silver) nanoparticles have proven to be an effective route to increase the light-harvesting capability in solar cells due to their localized surface plasmon resonance effects (LSPR). By adjusting the shape and size of the metal nanoparticles, the characteristic wavelength of the plasmon effect can be changed [28][29][30], thereby improving light absorption, carrier generation, and power conversion efficiency; this has been successfully used to improve the PCEs of solar cells [31][32][33][34][35][36].…”

Section: Introductionmentioning

confidence: 99%

Efficiency Improvement of MAPbI3 Perovskite Solar Cells Based on a CsPbBr3 Quantum Dot/Au Nanoparticle Composite Plasmonic Light-Harvesting Layer

et al. 2020

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We demonstrate a method to enhance the power conversion efficiency (PCE) of MAPbI3 perovskite solar cells through localized surface plasmon (LSP) coupling with gold nanoparticles:CsPbBr3 hybrid perovskite quantum dots (AuNPs:QD-CsPbBr3). The plasmonic AuNPs:QD-CsPbBr3 possess the features of high light-harvesting capacity and fast charge transfer through the LSP resonance effect, thus improving the short-circuit current density and the fill factor. Compared to the original device without Au NPs, a 27.8% enhancement in PCE of plasmonic AuNPs:QD-CsPbBr3/MAPbI3 perovskite solar cells was achieved upon 120 μL Au NP solution doping. This improvement can be attributed to the formation of surface plasmon resonance and light scattering effects in Au NPs embedded in QD-CsPbBr3, resulting in improved light absorption due to plasmonic nanoparticles.

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“…14 Apart from the morphology, the composition of nanoparticles also inuences their catalytic property. Various AgAu bimetallic hollow nanostructures such as nanosphere, 15,16 nanocubes, [17][18][19] nanowires, 20 nanorods, 14 nanotubes, 21 nanoshells, 22 nanobowls, 23 and nanoframes 24 are highly efficient in various catalytic reactions such as the reduction of nitrophenol, 14 degradation of methylene blue, 25 aniline oxidation, 24 and oxidation of various organic molecules. 26 Zheng et al compared Au nano boxes with their hollow counterpart "nanocages" and reported them as catalytically more active.…”

Section: Introductionmentioning

confidence: 99%

Core–shell Au@AuAg nano-peanuts for the catalytic reduction of 4-nitrophenol: critical role of hollow interior and broken shell structure

2020

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Ex Situ and in Situ Surface Plasmon Monitoring of Temperature-Dependent Structural Evolution in Galvanic Replacement Reactions at a Single-Particle Level

Cited by 17 publications

References 47 publications

The Ligand Shell as an Energy Barrier in Surface Reactions on Transition Metal Nanoparticles

The Ligand Shell as an Energy Barrier in Surface Reactions on Transition Metal Nanoparticles

Efficiency Improvement of MAPbI3 Perovskite Solar Cells Based on a CsPbBr3 Quantum Dot/Au Nanoparticle Composite Plasmonic Light-Harvesting Layer

Core–shell Au@AuAg nano-peanuts for the catalytic reduction of 4-nitrophenol: critical role of hollow interior and broken shell structure

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