What’s so Hot about Electrons in Metal Nanoparticles?

Hartland, Gregory V.; Besteiro, Lucas V.; Johns, Paul; Govorov, Alexander O.

doi:10.1021/acsenergylett.7b00333

Cited by 386 publications

(468 citation statements)

References 182 publications

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“…Silver nanoparticles (NPs) have a wide range of applications, such as catalyzing the photodecomposition of environmental contaminants, [1] selectively oxidizing organic species such as benzene and carbon monoxide, [2,3] serving as substrates for surface-enhanced Raman scattering (SERS), [4] acting as plasmonic photo-catalysts through the generation of hot charge carriers, [5,6] and providing antimicrobial activity. [7] However, a major issue with Ag NPs is the formation of an oxide/hydroxide layer on their surface that results in reduced efficiency in all of the above-mentioned applications.…”

Section: Introductionmentioning

confidence: 99%

Monitoring Simultaneous Electrochemical Reactions with Single Particle Imaging

2018

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Studying multiple simultaneous electrochemical reactions using typical electrochemical methods is challenging, because the measured current is a convolution of concurrent electrochemical reactions. Thus, to monitor multiple simultaneous electrochemical reactions, secondary techniques, such as imaging or spectroscopy are increasingly useful. Herein we use dark-field optical microscopy to visualize the electrodeposition of silver oxide (Ag x O y ) particles using the Ag + ions generated by the concurrent electrodissolution of individual Ag nanoparticles at high anodic potential. We propose that the formation of Ag x O y particles is based on an aggregative growth mechanism, where electrodeposited Ag x O y nanoclusters aggregate over time to form a larger Ag x O y particle. The electrodeposited Ag x O y particles catalyze water oxidation and decrease the local pH, which alters the reaction equilibrium by hindering continued growth of the Ag x O y particles at 1.2 V and consuming the Ag x O y particles and producing Ag + ions at open circuit. Overall the understanding obtained by imaging these reactions is not possible to decode using the measured ensemble current.

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Section: Introductionmentioning

confidence: 99%

Monitoring Simultaneous Electrochemical Reactions with Single Particle Imaging

2018

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“…Co-doping the LSC matrix with Au or Ag nanoparticles is typically resulting in an enhancement of the fluorescence intensity of the luminophore, either organic dyes, [121][122][123][124] semiconductor QDs, [125] or lanthanides complexes, [126] but no speculation on the final contribution to the LSC optical efficiency has been reported. [127] Indeed, while this approach has been successfully employed in many fields, ranging from biosensing [128] to photocatalysis, [129] its practical utilization in LSC technology is challenging due to different reasons: (i) the fine control of the 3D structure of the luminophore-metal nanoparticle adduct is essential to achieve a positive sensitization of the luminophore, [130,131] and it is often negatively counterbalanced by (ii) the rise of charge-transfer [132] and (iii) backenergy transfer processes to the metal nanoparticle. [127] Indeed, while this approach has been successfully employed in many fields, ranging from biosensing [128] to photocatalysis, [129] its practical utilization in LSC technology is challenging due to different reasons: (i) the fine control of the 3D structure of the luminophore-metal nanoparticle adduct is essential to achieve a positive sensitization of the luminophore, [130,131] and it is often negatively counterbalanced by (ii) the rise of charge-transfer [132] and (iii) backenergy transfer processes to the metal nanoparticle.…”

Section: Metal Nanoparticlesmentioning

confidence: 99%

The Renaissance of Luminescent Solar Concentrators: The Role of Inorganic Nanomaterials

Mazzaro

Vomiero

2018

Advanced Energy Materials

123

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While luminescent solar concentrators (LSCs) have a simple architecture—a transparent matrix embedding a luminescent fluorophore coupled with solar cells at the lateral side of the LSC slab—multiple paths for possible light losses exist. These are inherently interconnected, and in the past, limited the interest in this device, due to the gap between the theoretical possibilities and experimental achievements. This gap was a result, primarily, of the optical features of the luminescent dyes, since conventional organic luminophores are affected by limited performance in LSC devices. The rise of a wide portfolio of optically active inorganic nanomaterials in the last decade provides an alternative to organic dyes and has lead to a renaissance in the role of LSCs among the unconventional solar energy conversion devices. This paper reviews the latest results in the development of LSCs based on different classes of nanomaterials, focusing on the specific features and critically analyzing the pros and cons of the proposed structures. Particular attention is devoted to the role of the luminescence properties, e.g., the Stokes shift and the photoluminescence quantum yield, with respect to the performance of the LSC device. Future challenges to the successful employment of these devices for building integrated photovoltaics are also discussed.

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“…This work focuses on the effective e − damping in thin multilayer metal films. Damping is the most critical parameter ultimately determining the quality factor in many optics and plasmonics applications . By combining a mean‐field view with the free e − model, the overall behavior fulfills a parallel combination rule of pure materials coefficients, as here it is tested for Cu/Au and Au/Ag.…”

Section: Geometrical and Damping Data (K = Bilayer Number)mentioning

confidence: 99%

“…Damping is the most critical parameter ultimately determining the quality factor in many optics and plasmonics applications. [25,26] By combining a mean-field view with the free e À model, the overall behavior fulfills a parallel combination rule of pure materials coefficients, as here it is tested for Cu/Au and Au/Ag. Theories linking mesoscopic to microscopic/atomic scales well suit condensed matter investigations such as polarization, dielectric, [27][28][29] flow, [30] and solidstate properties.…”

mentioning

confidence: 99%

Combination Law for Drude–Sommerfeld's Electron Damping in Multilayer Thin Metal Films

Mezzasalma

Janicki

Salamon

et al. 2018

Physica Rapid Research Ltrs

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A combination rule for electron damping in multilayer thin metal films is derived from a mean‐field picture and is applied to optical experimental data. The overall coefficient obeys a parallel law of pure materials damping, true〈γtrue〉 −1=gtrue¯ normalAγ normalA−1+gtrue¯ normalBγ normalB−1 (gtrue¯i<1), chemical specificity being involved by averaging over densities of low energy states in the free electron model. Geometric and static electromagnetic features of single layers couple via small Fermi's energy fractions (αi). An application is developed for thin Cu/Au and Au/Ag films, showing an apparently irregular damping trend in the film thickness (di = 2.5–7.5 nm). The inferred ⟨γ⟩'s agree in both cases with our data when |αi| = 10−2 ÷ 10−3 linearly increases with decreasing di, suggesting a coupling phenomenology that can bring new insights in the optics and plasmonics of nanostructures.

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What’s so Hot about Electrons in Metal Nanoparticles?

Cited by 386 publications

References 182 publications

Monitoring Simultaneous Electrochemical Reactions with Single Particle Imaging

Monitoring Simultaneous Electrochemical Reactions with Single Particle Imaging

The Renaissance of Luminescent Solar Concentrators: The Role of Inorganic Nanomaterials

Combination Law for Drude–Sommerfeld's Electron Damping in Multilayer Thin Metal Films

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