In Situ Optical Monitoring of the Electrochemical Conversion of Dielectric Nanoparticles: From Multistep Charge Injection to Nanoparticle Motion

Lemineur, Jean‐François; Noël, Jean‐Marc; Courty, Alexa; Ausserré, Dominique; Combellas, Catherine; Kanoufi, Frédéric

doi:10.1021/jacs.0c02071

Cited by 44 publications

(76 citation statements)

References 88 publications

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“…We focus here on the reverse reaction, and study the EC reduction of CTAB-capped AgX ionic colloidal NPs into metallic Ag NPs. If earlier single silver-based ionic NP (AgO or AgX) studies suggest that this conversion is reversible but may be incomplete 29 or proceed to completion, 33,34 the conversion rate seems to depend on whether Brownian colloids in solution (<0.1s) 29,33 or CTABcapped AgX NPs immobilized on an electrode (>1s) 34 are considered. The difference may be due to the NP size, composition or capping agent, 35 but also to its interaction with the electrode surface 29b and its mobility (Brownian vs surfacebound).…”

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confidence: 99%

Revealing the sub-50 ms electrochemical conversion of silver halide nanocolloids by stochastic electrochemistry and optical microscopy

et al. 2020

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Revealing the sub-50 ms electrochemical conversion of silver halide nanocolloids by stochastic electrochemistry and optical microscopy

et al. 2020

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“…A linear relationship between the NP volume and the backgroundsubtracted intensity was demonstrated in previous work. 41 Thanks to such empirical law, the size of the NP is accessible throughout the potential sweep. The relationship between the BALM intensity and the volume of electrodeposited Ag NPs determined by SEM (Figure 4a, same location for SEM and BALM) is also linear and comparable but actually less sensitive, than that observed previously (slope <I BALM >- 41 Indeed, the condition for light extinction from the AR absorbing layer strongly depends on the Au layer thickness which is ~ 5nm.…”

Section: Quantitative Analyses and Sensitivitymentioning

confidence: 99%

“…41 Thanks to such empirical law, the size of the NP is accessible throughout the potential sweep. The relationship between the BALM intensity and the volume of electrodeposited Ag NPs determined by SEM (Figure 4a, same location for SEM and BALM) is also linear and comparable but actually less sensitive, than that observed previously (slope <I BALM >- 41 Indeed, the condition for light extinction from the AR absorbing layer strongly depends on the Au layer thickness which is ~ 5nm. Slight variation, from batch to batch, of this thickness is thus expected inducing both changes in the signal-to-noise ratio and in the extent of constructive or destructive (extinction) interferences and therefore in .…”

Section: Quantitative Analyses and Sensitivitymentioning

confidence: 99%

“…By optimizing the gold layer thickness as well as the video acquisition parameters, NPs <10 nm were observed. 41 It is also important to point out that the optical setup (a classical inverted microscope, a white LED and a standard 8-bit color CCD camera) is quite common. Then, there are still rooms for improving the optoelectrochemical setup and thus having a better sensitivity, which could theoretically reach nanometer scale vertical resolution.…”

Section: Resolution and Sensitivitymentioning

confidence: 99%

“…Electrochemical cells were machined in house from plastic, as reported previously. 41 The UME was lithographed directly from the gold layer deposited on the glass substrate.…”

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The promise of antireflective gold electrodes for optically monitoring the electro-deposition of single silver nanoparticles

et al. 2018

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The interest in nano-objects has recently dramatically increased in all fields of science, and electrochemistry is no exception. As a consequence, in situ and operando visualization of electrochemical processes is needed at the nanoscale. Herein, we propose a new interferometric microscopy based on an antireflective thin metal electrode layer. The technique is coupled to electrochemistry in a model example: the electro-deposition of Ag metallic nanoparticles (NPs). This challenges the current opto-electrochemical methods and even those relying on nano-impact detection. Indeed, the sensitivity allows the dynamic in situ visualization of the electrochemical growth and dissolution of individual Ag NPs, whose size was tracked dynamically down to 15 nm in diameter. The use of microelectrodes provides interesting quantitative analysis of the NPs, from optically resolved arrays of single NPs to condensed arrays of (unresolved) NPs. Particularly, the optical analysis of all the individual NPs allows the reconstruction of optical voltammograms similar to the electrochemical ones. Finally, the NP dissolution-redeposition is also investigated.

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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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In Situ Optical Monitoring of the Electrochemical Conversion of Dielectric Nanoparticles: From Multistep Charge Injection to Nanoparticle Motion

Cited by 44 publications

References 88 publications

Revealing the sub-50 ms electrochemical conversion of silver halide nanocolloids by stochastic electrochemistry and optical microscopy

Revealing the sub-50 ms electrochemical conversion of silver halide nanocolloids by stochastic electrochemistry and optical microscopy

The promise of antireflective gold electrodes for optically monitoring the electro-deposition of single silver nanoparticles

Electrochemistry and Optical Microscopy

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