Interrogating Charge Storage on Redox Active Colloids via Combined Raman Spectroscopy and Scanning Electrochemical Microscopy

Gossage, Zachary T.; Schorr, Noah B.; Hernández‐Burgos, Kenneth; Hui, Jingshu; Simpson, Burton H.; Montoto, Elena C.; Rodríguez‐López, Joaquín

doi:10.1021/acs.langmuir.7b01121

Cited by 46 publications

(57 citation statements)

References 32 publications

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“…Substrate Preparation: (1) RACs were dispersed in MeCN and dropcasted onto a glass substrate, (2) allowed to dry, (3) and then heated and cooled under ambient conditions. CV on multiple particles allowed us to estimate the diffusion coefficient for charge transfer, D CT , [18,41,42] at 8 10 À11 AE 3 10 À11 cm 2 /s (n = 7) in agreement with previous measurements on RAC monolayers. It was positioned 2.1 mm away from the surface to accommodate the RAC swollen height (~1.3 mm).…”

Section: Scanning Electrochemical Microscopy On Single Racssupporting

confidence: 81%

“…As depicted in Scheme 1, we approached a sharpened SECM probe with an exposed Pt microdisk of 300 nm in radius toward a glass surface containing Scheme 1. [18] We stepped the probe toward the particle in 100 nm increments while using cyclic voltammetry (CV). Substrate Preparation: (1) RACs were dispersed in MeCN and dropcasted onto a glass substrate, (2) allowed to dry, (3) and then heated and cooled under ambient conditions.…”

Section: Scanning Electrochemical Microscopy On Single Racsmentioning

confidence: 99%

“…[12,17,18] Charge hopping on redox-active polymers has been investigated in solution, [19][20][21] as films on modified electrodes, [21,22] and with isolated molecules. Electron transfer at the electrode-particle interface and subsequent charge hopping enables particle electrolysis via the movement of charge between the oxidized (V 2 + ), and the reduced state (V + ).…”

Section: Introductionmentioning

confidence: 99%

“…Electron transfer at the electrode-particle interface and subsequent charge hopping enables particle electrolysis via the movement of charge between the oxidized (V 2 + ), and the reduced state (V + ). [18] We now turn to expanding these single-particle methodologies to evaluate performance-governing characteristics during cycling. [23] Recently, our group introduced spectroelectrochemical and nanoelectrochemical methodologies for evaluating electron transfer on single RAC particles and RAC monolayer assemblies.…”

Section: Introductionmentioning

confidence: 99%

“…battery nanomaterials. [18,[32][33][34][35][36][37] Through SECM feedback imaging, single RACs were located to make contact for direct charge/discharge measurements. To date the majority of these single entity studies has focused on micron-sized particles for ion intercalation.…”

Section: Introductionmentioning

confidence: 99%

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Impact of Charge Transport Dynamics and Conditioning on Cycling Efficiency within Single Redox Active Colloids

et al. 2018

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Redox active colloids (RACs) are flowable suspensions for sizeexclusion redox flow batteries that exchange billions of electrons per particle. Single particle measurements via bulk electrolysis and voltammetry provided an accelerated platform for evaluating the role of state of charge and conditioning on RAC performance. We used scanning electrochemical microscopy to image, isolate, and interrogate RACs (830 nm diameter) with a 300 nm probe. Deep electrolysis of the particles evidenced capacity losses, but this conditioning simultaneously led to increased Coulombic efficiency. On the other hand, shallow cycling using voltammetry for over 150 cycles showed improved charge recovery and gradual changes in the particle's diffusional regimes. Raman spectroelectrochemistry on few RACs confirmed that degradation occurred upon deep cycling but that shallow cycling was not as detrimental, albeit with low capacity access. The methodologies presented herein provide a stepwise viewpoint of the progression of RAC function with cycling, linking bulk behavior with that of individual particles.[a] Z.

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Section: Scanning Electrochemical Microscopy On Single Racssupporting

confidence: 81%

Section: Scanning Electrochemical Microscopy On Single Racsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Impact of Charge Transport Dynamics and Conditioning on Cycling Efficiency within Single Redox Active Colloids

et al. 2018

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Particle Impact Electrochemistry

Alpuche-Avilés

2021

Encyclopedia of Electrochemistry

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Experiments involving collisions between a single entity and the electrode surface have become an active area of research. The electrochemical contribution of individual nanoparticles (NPs), enzymes, and other entities, such as aggregates or agglomerates, can be determined using particle impact experiments. Destructive nanoimpact experiments of materials, such as Ag, and the electrocatalytic amplification (ECA) are used to detect the NP/electrode interactions. This review covers the seminal work, critical theoretical studies, and some recent applications. The applications to electrocatalysis include measurements of electron transfer rate constants on individual nanoparticles. Applications in analytical chemistry have allowed the detection of nonelectroactive species by detecting the collisions of soft materials, e.g. micellar suspensions and proteins have increased the technique's analytical possibilities. With ECA, NPs can be used as tags for the electrochemical detection of bioanalytes such as DNA, proteins, and liposomes. The theory of ECA collisions, including frequency of collision and the size of the electrochemical current transients, are also covered. For nanoimpacts, the charge measured during a NP electrolysis, such as Ag NP, is used to detect the NP. Measurements of NP diameter are possible, but limitations to this analysis are covered. The electron transfer studies to the electrolysis of Ag and of metal oxides are discussed. Finally, key experimental instrumentations are discussed, including instrumentation techniques for the small currents inherent to single NP measurement. The effect of filtering, instrumentations rise time, and sampling frequency are also covered.

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The Joint Center for Energy Storage Research: A New Paradigm of Research, Development, and Demonstration

Carney

Hodge

Trahey

et al. 2018

Advances in Electrochemical Sciences and Engineering

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Interrogating Charge Storage on Redox Active Colloids via Combined Raman Spectroscopy and Scanning Electrochemical Microscopy

Cited by 46 publications

References 32 publications

Impact of Charge Transport Dynamics and Conditioning on Cycling Efficiency within Single Redox Active Colloids

Impact of Charge Transport Dynamics and Conditioning on Cycling Efficiency within Single Redox Active Colloids

Particle Impact Electrochemistry

The Joint Center for Energy Storage Research: A New Paradigm of Research, Development, and Demonstration

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