Visualizing the Effect of Partial Oxide Formation on Single Silver Nanoparticle Electrodissolution

Sundaresan, Vignesh; Monaghan, Joseph W.; Willets, Katherine A.

doi:10.1021/acs.jpcc.7b11824

Cited by 85 publications

(112 citation statements)

References 41 publications

(53 reference statements)

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“…[10] We also tracked the spatial origin of the scattering as a function of time and potential and found that NPs undergo either isotropic or anisotropic dissolution, due to the heterogeneous formation of Ag x O y layers on the particle surfaces. [10] We also tracked the spatial origin of the scattering as a function of time and potential and found that NPs undergo either isotropic or anisotropic dissolution, due to the heterogeneous formation of Ag x O y layers on the particle surfaces.…”

Section: Resultsmentioning

confidence: 99%

“…For example, surface oxides on Ag NPs can reduce SERS signals by damping the plasmondriven electromagnetic field enhancements near the particle surface. [10] Recently, we showed how nanoscale heterogeneity of surface oxide layers impacts the kinetics and morphology of single Ag NPs during electrodissolution using dark-field microscopy. [10] Recently, we showed how nanoscale heterogeneity of surface oxide layers impacts the kinetics and morphology of single Ag NPs during electrodissolution using dark-field microscopy.…”

Section: Introductionmentioning

confidence: 99%

“…[8,9] Surface oxide layers also impact the electrochemical behavior of Ag NPs, affecting both their performance as electrodes as well as their electrodissolution kinetics during silver oxidation. [10] Electrochemical studies at the single particle level are of great interest because they reveal particle-to-particle heterogeneity and provide an understanding of the underlying mechanisms that may be hidden in ensemble electrochemical measurements. [10] Electrochemical studies at the single particle level are of great interest because they reveal particle-to-particle heterogeneity and provide an understanding of the underlying mechanisms that may be hidden in ensemble electrochemical measurements.…”

Section: Introductionmentioning

confidence: 99%

“…[10] Recently, we showed how nanoscale heterogeneity of surface oxide layers impacts the kinetics and morphology of single Ag NPs during electrodissolution using dark-field microscopy. [10] Electrochemical studies at the single particle level are of great interest because they reveal particle-to-particle heterogeneity and provide an understanding of the underlying mechanisms that may be hidden in ensemble electrochemical measurements. [11][12][13] Several other groups have also studied the oxidation of single Ag NPs using electrochemical, optical, and correlated electrochemical-optical methods .…”

Section: Introductionmentioning

confidence: 99%

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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: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Monitoring Simultaneous Electrochemical Reactions with Single Particle Imaging

2018

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“…[14] Although spectroscopic information is attainable,m uch of the work in the literature has focusedo nt he intensity of the scattered light from individual particles and its alteration during the course of their oxidation.T his allows the processes to be dynamically monitored and yields potentiali nsighti nto the reaction kinetics at the nanoscale. [15][16][17] Further development of holographict echniquest oe nable NP tracking in three dimensions has enabled the simultaneous in situ tracking of particlesadjacentt oa nd at an electrochemical interface. [18][19][20] Elsewhere, the trackingo fN P trajectories is aw ell-established techniquef or studies into areas including single NP growth or single NP reactions using as ingle NP spectrometer.…”

Section: Introductionmentioning

confidence: 99%

Coupled Optical and Electrochemical Probing of Silver Nanoparticle Destruction in a Reaction Layer

et al. 2018

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The oxidation of silver nanoparticles is induced to occur near to, but not at, an electrode surface. This reaction at a distance from the electrode is studied through the use of dark‐field microscopy, allowing individual nanoparticles and their reaction with the electrode product to be visualized. The oxidation product diffuses away from the electrode and oxidizes the nanoparticles in a reaction layer, resulting in their destruction. The kinetics of the silver nanoparticle solution‐phase reaction is shown to control the length scale over which the nanoparticles react. In general, the new methodology offers a route by which nanoparticle reactivity can be studied close to an electrode surface.

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Electrochemistry and Optical Microscopy

Kanoufi

2021

Encyclopedia of Electrochemistry

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Electrochemistry exploits local current heterogeneities at various scales ranging from the micrometer to the nanometer. The last decade has witnessed unprecedented progress in the development of a wide range of electroanalytical techniques allowing to reveal and quantify such heterogeneity through multiscale and multifonctionnal operando probing of electrochemical processes. However most of these advanced electrochemical imaging techniques, employing scanning probes, suffer from either low imaging throughput or limited imaging size. In parallel, optical microscopies, which can image a wide field of view in a single snapshot, have made considerable progress in terms of sensitivity, resolution and implementation of detection modes. Optical microscopies are then mature enough to propose, with basic bench equipment, to probe in a non destructive way a wide range of optical (and therefore structural) properties of a material in situ, in real time: under operating conditions. They offer promising alternative strategies for quantitative high-resolution imaging of electrochemistry. The first sections recall the optical properties of materials and how they can be probed optically. They discuss fluorescence, Raman, surface plasmon resonance, scattering or refractive index. Then the different optical microscopes used to image electrochemical processes are examined along with some strategies to extract quantitative electrochemical information from optical images. Finally the last section reviews some examples of in situ imaging, at micro-to nanometer resolution, and quantification of electrochemical processes ranging from solution diffusion to the conversion of molecular interfaces or solids.]

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Visualizing the Effect of Partial Oxide Formation on Single Silver Nanoparticle Electrodissolution

Cited by 85 publications

References 41 publications

Monitoring Simultaneous Electrochemical Reactions with Single Particle Imaging

Monitoring Simultaneous Electrochemical Reactions with Single Particle Imaging

Coupled Optical and Electrochemical Probing of Silver Nanoparticle Destruction in a Reaction Layer

Electrochemistry and Optical Microscopy

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