En Ning Saw scite author profile

The increasing interest in producing bimetallic nanoparticles and utilizing them in modern technologies sets the demand for fast and affordable characterization of these materials. To date Scanning Transmission Electron Microscopy (STEM) coupled to energy dispersive X-ray spectroscopy is usually used to determine the size and composition of alloy nanoparticles, which is time-consuming and expensive. Here electrochemical single nanoparticle analysis is presented as an alternative approach to infer the particle size and composition of alloy nanoparticles, directly in a dispersion of these particles. As a proof of concept, 14 nm sized AgAu alloy nanoparticles are analyzed using a combination of chronoamperometric single nanoparticle analysis and cyclic voltammetry ensemble studies. It is demonstrated that the size, the alloying and the composition can all be inferred using this approach. Thus, the electrochemical characterization of single bimetallic alloy nanoparticles is suggested here as a powerful and convenient complement or alternative to TEM characterization of alloy nanoparticles.

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Nano Impact Electrochemistry: Effects of Electronic Filtering on Peak Height, Duration and Area

Kanokkanchana

Saw

Tschulik

2018

ChemElectroChem

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What was the biggest surprise?When analyzingt he currentr esponse of commercial potentiostats, we realized that most of them employ surprisingly strong low pass filtering. This is usually appropriate in electrochemistry.H owever, in nanoimpact studies, currents ignals of low amplitude ( nA) and short duration ( ms) are concerned. Hence, shape and duration of collision peaks may be significantly altered, which may causem isinterpretationo fr eaction mechanisms and extraction of incorrect kinetic information.Invited for this month'sc over picturei st he group of Prof. Dr.K ristinaT schulik from Ruhr University Bochum( Germany). The cover picture shows the alteration of ac urrent signal caused by the electronic filtering implemented in potentiostats. These filter effects are uncovereda nd as imple method is provided for electrochemists to test and validate their experimental setup. This is particularly important for transients ingle-entity electrochemistry,w hich requires low current measurements at high time resolution. Read the full text of the Articleat10.1002/celc.201800738.

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High-Density Droplet Microarray of Individually Addressable Electrochemical Cells

et al. 2017

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Microarray technology has shown great potential for various types of high-throughput screening applications. The main read-out methods of most microarray platforms, however, are based on optical techniques, limiting the scope of potential applications of such powerful screening technology. Electrochemical methods possess numerous complementary advantages over optical detection methods, including its label-free nature, capability of quantitative monitoring of various reporter molecules, and the ability to not only detect but also address compositions of individual compartments. However, application of electrochemical methods for the purpose of high-throughput screening remains very limited. In this work, we develop a high-density individually addressable electrochemical droplet microarray (eDMA). The eDMA allows for the detection of redox-active reporter molecules irrespective of their electrochemical reversibility in individual nanoliter-sized droplets. Orthogonal band microelectrodes are arranged to form at their intersections an array of three-electrode systems for precise control of the applied potential, which enables direct read-out of the current related to analyte detection. The band microelectrode array is covered with a layer of permeable porous polymethacrylate functionalized with a highly hydrophobic-hydrophilic pattern, forming spatially separated nanoliter-sized droplets on top of each electrochemical cell. Electrochemical characterization of single droplets demonstrates that the underlying electrode system is accessible to redox-active molecules through the hydrophilic polymeric pattern and that the nonwettable hydrophobic boundaries can spatially separate neighboring cells effectively. The eDMA technology opens the possibility to combine the high-throughput biochemical or living cell screenings using the droplet microarray platform with the sequential electrochemical read-out of individual droplets.

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En Ning Saw

Time-resolved impact electrochemistry for quantitative measurement of single-nanoparticle reaction kinetics

Electrochemistry at single bimetallic nanoparticles – using nano impacts for sizing and compositional analysis of individual AgAu alloy nanoparticles

Nano Impact Electrochemistry: Effects of Electronic Filtering on Peak Height, Duration and Area

High-Density Droplet Microarray of Individually Addressable Electrochemical Cells

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