High throughput electrochemically driven metal microprinting with multicapillary droplet cell

“…Aside from corrosion research, the MCC technique has also been successfully applied to investigate other interesting aspects, such as electrodeposition of pure metal (e.g., Cu − and Ni , ), surface modification, electrochemical machining, − electrocatalyst materials screening, ,,− localized anodizing, , and thin-film properties characterization. ,, Furthermore, a multiparallel microcell and devices with an automatic test function ,, have been developed to achieve high-throughput localized electrochemical characterization, opening a new paradigm of electrochemical analysis.…”

Small-Area Techniques for Micro- and Nanoelectrochemical Characterization: A Review

“…Aside from corrosion research, the MCC technique has also been successfully applied to investigate other interesting aspects, such as electrodeposition of pure metal (e.g., Cu − and Ni , ), surface modification, electrochemical machining, − electrocatalyst materials screening, ,,− localized anodizing, , and thin-film properties characterization. ,, Furthermore, a multiparallel microcell and devices with an automatic test function ,, have been developed to achieve high-throughput localized electrochemical characterization, opening a new paradigm of electrochemical analysis.…”

Small-Area Techniques for Micro- and Nanoelectrochemical Characterization: A Review

“…Various numerical approaches have been developed during the last three decades to complement experimental understandings of biomembranes. While all atomic (AA) modeling techniques are still progressing in terms of developing more efficient computational algorithms, more accurate force fields and advanced sampling techniques, [20][21][22][23][24] many biological phenomena are still not in the accessible range of AA approaches. Coarsegraining AA systems can significantly reduce the degrees of freedom and accelerate system dynamics to model higher lengths and longer time scales.…”

Coarse-grained molecular simulation of extracellular vesicle squeezing for drug loading

“…24 Bilal et al performed area selective aluminum anodization and nickel/copper electrodeposition using a Sf-MDC fabricated by a 3D printer. [25][26][27] In addition, the conventional Sf-MDC is long in the vertical direction, with the result that it is difficult to equip it to a microscope, and it is difficult to precisely control the measured area. In this paper, a novel configuration of an Sf-MDC was fabricated using a 3D printer, equipped with an optical microscope, and local electrochemical measurements were performed to investigate the size of the Si related precipitates on the electrochemical behavior of an aluminum alloy.…”

Local Electrochemical Measurements by 3D Printed Sf-MDC Equipped with Optical Microscope