Dynamic Chemistry Interactions: Controlled Single-Entity Electrochemistry

Lu, Si‐Min; Long, Yi‐Tao

doi:10.1021/acs.jpclett.2c00960

Cited by 27 publications

(24 citation statements)

References 56 publications

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“…Furthermore, we expect future possibilities for DAERI to synergize with other advanced characterization techniques, such as single-entity electrochemical techniques. Inspired by recent progress of single-entity electrochemistry, − DAERI may provide molecular structure information in both spatial and temporal dimensions combined with transient electrochemical processes of single cells, single particles, or single molecules at nanoconfined electrode interfaces. The diverse azo-type molecular designs and the high signal strength of azo-enhanced Raman probes can potentially relate single-entity electrochemical effects beyond the narrow enhancement zone of SERS obtained on noble metallic surfaces.…”

Section: Discussionmentioning

confidence: 99%

High-Resolution Low-Power Hyperspectral Line-Scan Imaging of Fast Cellular Dynamics Using Azo-Enhanced Raman Scattering Probes

Tang

Chu

et al. 2022

J. Am. Chem. Soc.

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Small-molecule Raman probes for cellular imaging have attracted great attention owing to their sharp peaks that are sensitive to environmental changes. The small cross section of molecular Raman scattering limits dynamic cellular Raman imaging to expensive and complex coherent approaches that acquire single-channel images and lose hyperspectral Raman information. We introduce a new method, dynamic azo-enhanced Raman imaging (DAERI), to couple the new class of azoenhanced Raman probes with a high-speed line-scan Raman imaging system. DAERI achieved high-resolution low-power imaging of fast cellular dynamics resolved at ∼270 nm along the confocal direction, 75 μW/μm 2 and 3.5 s/frame. Based on the azo-enhanced Raman probes with characteristic signals 10 2 −10 4 stronger than classic Raman labels, DAERI was not restricted to the cellular Raman-silent region as in prior work and enabled multiplex visualization of organelle motions and interactions. We anticipate DAERI to be a powerful tool for future studies in biophysics and cell biology.

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Section: Discussionmentioning

confidence: 99%

High-Resolution Low-Power Hyperspectral Line-Scan Imaging of Fast Cellular Dynamics Using Azo-Enhanced Raman Scattering Probes

Tang

Chu

et al. 2022

J. Am. Chem. Soc.

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“…In selecting material for inclusion in this article, we consider distinct, but related areas, spanning nanopores/pipettes, nanopipette probe microscopy and widefield imaging. These methods are becoming a natural choice for high-throughput single entity nanoelectrochemistry, [7][8][9] where the goal is to detect and analyze, inter alia, single molecules, single cells, and individual particles (and other nanoobjects), as well as to break down the response of complex electrode surfaces and interfaces into a set of simpler elementary features, e.g., terraces, step edges, grain boundaries, etc. Each of the areas we have selected is benefiting from similar developments in experimental capability and analysis tools; there are also efforts to integrate techniques and ideas from each of these areas.…”

Section: Introductionmentioning

confidence: 99%

The new era of high throughput nanoelectrochemistry

Valavanis

Ciocci

et al. 2022

Preprint

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Scanning electrochemical probe microscopies (SEPMs) have played a key role in advancing small-scale electrochemistry. SEPMs use an electrochemical probe (micro/nanoelectrode or pipet) to quantify and map local interfacial fluxes of electroactive species and have found increasingly wide applications. Our contribution to the Fundamental and Applied Reviews in Analytical Chemistry 2019 discussed how advances in SEPMs converged towards nanoscale electrochemical mapping. This inflection in experimental capability has opened up myriad opportunities for SEPMs in many types of systems, from material and energy sciences to the life sciences. The enhancement in the spatial resolution of imaging techniques, and instrumental developments, have resulted in significant increases in the size of electrochemical datasets from a typical experiment and served to speed up measurement throughput. Next generation nanoelectrochemistry will thus see an emphasis on “big data”, its analysis, storage and curation, high throughput analysis and parallelization, “intelligent” instruments and experiments, active control of nanoscale systems, and the integration of nanoelectrochemistry and nanoscale micro(spectro)scopy. For this review article, we focus on recent advances in frontier nanoscale electrochemistry, analysis and imaging techniques that are already addressing some of these key targets, and are well-placed to embrace other aspects in the near future. Our goal is to provide an overview of the present state-of-the-art in high throughput nanoelectrochemistry and imaging, and signpost promising new avenues for nanoscale electrochemical methods.

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“…The emerging field of “single-entity electrochemistry” (SEE) refers to measurement and interpretation of the electrical transient signals generated when a single entity, e.g., a nanoparticle, a single molecule, a droplet, a micelle, or a living cell, undergoes electrochemical processes at suitable interfaces, including micro- and nano-electrodes or -pipets, nanopores, etc. − The technique’s capability to probe a signal from single entities makes it powerful for delivering both individual and statistical information on these entities. This makes it beneficial for a broad range of investigations, including nanoparticle characterizations and dynamic transformations, − agglomeration study, ion diffusion and solvation studies, , detection and identification of single bacteria or viruses, − catalytic activity investigation of single enzymes, detection of conformation changes of a single DNA, single-molecule detection, battery material characterization, and investigation of the catalytic activity of individual nanoparticles. − …”

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confidence: 99%

Electronic Circuit Simulations as a Tool to Understand Distorted Signals in Single-Entity Electrochemistry

Kanokkanchana

Tschulik

2022

J. Phys. Chem. Lett.

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Electrochemical analysis relies on precise measurement of electrical signals, yet the distortions caused by potentiostat circuitry and filtering are rarely addressed. Elucidation of these effects is essential for gaining insights behind sensitive low-current and short-duration electrochemical signals, e.g., in single-entity electrochemistry. We present a simulation approach utilizing the Electrical Simulation Program with Integrated Circuit Emphasis (SPICE), which is extensively used in electronic circuit simulations. As a proof-of-concept, we develop a universal electrical circuit model for single nanoparticle impact experiments, incorporating potentiostat and electronic filter circuitry. Considering these alterations, the experimentally observed transients of silver nanoparticle oxidation were consistently shorter and differently shaped than those predicted by established models. This reveals the existence of additional processes, e.g., migration, partial or asymmetric oxidation. These results highlight the SPICE approach's ability to provide valuable insights into processes occurring during single-entity electrochemistry, which can be applied to various electrochemical experiments, where signal distortions are inevitable.

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Dynamic Chemistry Interactions: Controlled Single-Entity Electrochemistry

Cited by 27 publications

References 56 publications

High-Resolution Low-Power Hyperspectral Line-Scan Imaging of Fast Cellular Dynamics Using Azo-Enhanced Raman Scattering Probes

High-Resolution Low-Power Hyperspectral Line-Scan Imaging of Fast Cellular Dynamics Using Azo-Enhanced Raman Scattering Probes

The new era of high throughput nanoelectrochemistry

Electronic Circuit Simulations as a Tool to Understand Distorted Signals in Single-Entity Electrochemistry

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