J
Julie V. Macpherson
Researcher at University of Warwick
Publications - 216
Citations - 10724
Julie V. Macpherson is an academic researcher from University of Warwick. The author has contributed to research in topics: Electrode & Scanning electrochemical microscopy. The author has an hindex of 56, co-authored 209 publications receiving 9635 citations. Previous affiliations of Julie V. Macpherson include University of Texas at Austin & Coventry Health Care.
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A practical guide to using boron doped diamond in electrochemical research.
TL;DR: Information is provided on how best to characterise the material properties of the electrode before use and the interplay between boron dopant density, non-diamond-carbon content, grain morphology, surface chemistry and redox couple identity should ideally be considered when interpretating electrochemical data arising from the diamond electrode.
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Combined Scanning Electrochemical−Atomic Force Microscopy
TL;DR: A combined scanning electrochemical microscope (SECM)-atomic force microscope (AFM) is described, which permits the first simultaneous topographical and electrochemical measurements at surfaces, under fluid, with high spatial resolution.
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Electrochemistry at carbon nanotubes: perspective and issues.
TL;DR: This review highlights how the various discrepancies in CNT electrochemistry may have arisen, by taking a historical view of the field and identifying crucial issues that still need to be solved.
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Conductive diamond: synthesis, properties, and electrochemical applications
Nianjun Yang,Siyu Yu,Julie V. Macpherson,Yasuaki Einaga,Hongying Zhao,Guohua Zhao,Greg M. Swain,Xin Jiang +7 more
TL;DR: This review provides an overview of the fundamental properties and highlights recent progress and achievements in the growth of boron-doped (metal-like) and nitrogen and phosphorus- doped (semi-conducting) diamond and hydrogen-terminated undoped diamond electrodes.
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Electrochemical Templating of Metal Nanoparticles and Nanowires on Single-Walled Carbon Nanotube Networks
TL;DR: This approach provided detail on the nucleation and growth mechanisms of Ag and Pt on SWNTs under electrochemical control, and Ag growth was found to be rapid and progressive with an increasing nanoparticle density with time, whereas Pt deposition was characterized by lower nucleation densities and slower growth rates with a tendency for larger particles to be produced over long times.