Julie V. Macpherson

What is she best known for?

The fields of study she is best known for:

• Redox
• Hydrogen
• Electrochemistry

Her primary scientific interests are in Nanotechnology, Electrode, Analytical chemistry, Carbon nanotube and Scanning electrochemical microscopy. The various areas that Julie V. Macpherson examines in her Nanotechnology study include Platinum and Electron transfer. Her research in the fields of Electrochemistry, Electrolyte and Palladium-hydrogen electrode overlaps with other disciplines such as Pyrolytic carbon.

Her research integrates issues of Microscope, Highly oriented pyrolytic graphite, Amperometry, Nanopore and Conductivity in her study of Analytical chemistry. The study incorporates disciplines such as Nanowire, Radius of curvature and Lateral resolution in addition to Carbon nanotube. Her Scanning electrochemical microscopy study integrates concerns from other disciplines, such as Chemical physics, Ultramicroelectrode, Local density of states and Scanning electron microscope.

Her most cited work include:

• Combined Scanning Electrochemical−Atomic Force Microscopy (274 citations)
• Electrochemistry at carbon nanotubes: perspective and issues. (233 citations)
• A practical guide to using boron doped diamond in electrochemical research (224 citations)

What are the main themes of her work throughout her whole career to date?

Her main research concerns Electrode, Analytical chemistry, Nanotechnology, Electrochemistry and Carbon nanotube. Her research in Electrode intersects with topics in Inorganic chemistry, Diamond and Electron transfer. The Analytical chemistry study combines topics in areas such as Ultramicroelectrode, Microscope, Scanning electron microscope, Scanning electrochemical microscopy and Aqueous solution.

Julie V. Macpherson combines subjects such as Outer sphere electron transfer, Conductivity and Microscopy with her study of Nanotechnology. The concepts of her Electrochemistry study are interwoven with issues in Detection limit, Redox and Metal. Her Carbon nanotube research is multidisciplinary, incorporating perspectives in Substrate, Nanowire and Chemical vapor deposition.

She most often published in these fields:

• Electrode (50.00%)
• Analytical chemistry (39.62%)
• Nanotechnology (37.26%)

What were the highlights of her more recent work (between 2014-2021)?

• Electrode (50.00%)
• Electrochemistry (33.96%)
• Diamond (16.51%)

In recent papers she was focusing on the following fields of study:

Julie V. Macpherson mainly investigates Electrode, Electrochemistry, Diamond, Nanotechnology and Analytical chemistry. Her Electrode research is multidisciplinary, incorporating elements of Inorganic chemistry, Carbon nanotube, Aqueous solution and Electron transfer. Her work on Electrochemical cell as part of general Electrochemistry research is frequently linked to Boron, bridging the gap between disciplines.

Julie V. Macpherson has included themes like Chemical vapor deposition, Doping, Electrolysis and Corrosion in her Diamond study. In general Nanotechnology, her work in Nanopore is often linked to Chemical substance linking many areas of study. Many of her research projects under Analytical chemistry are closely connected to Electron paramagnetic resonance with Electron paramagnetic resonance, tying the diverse disciplines of science together.

Between 2014 and 2021, her most popular works were:

• A practical guide to using boron doped diamond in electrochemical research (224 citations)
• Conductive diamond: synthesis, properties, and electrochemical applications (108 citations)
• Boron Doped Diamond: A Designer Electrode Material for the Twenty-First Century. (65 citations)

In her most recent research, the most cited papers focused on:

• Redox
• Hydrogen
• Electrochemistry

The scientist’s investigation covers issues in Electrode, Nanotechnology, Electrochemistry, Diamond and Analytical chemistry. Her Electrode research integrates issues from Inorganic chemistry, Nanoparticle, Chemical vapor deposition and Electron transfer. Her Nanotechnology research includes elements of Surface modification, Electrocatalyst, Boron doped diamond and Electrode material.

Her Electrochemistry research is multidisciplinary, incorporating perspectives in Capacitive sensing, Doping and Carbon nanotube. The study incorporates disciplines such as Detection limit, Transmission electron microscopy, Material properties and Dopant in addition to Diamond. Her Analytical chemistry research is multidisciplinary, relying on both Redox, Metal and Electrochemical cell.

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