Mark E. Welland

What is he best known for?

The fields of study he is best known for:

• Quantum mechanics
• Electron
• Semiconductor

The scientist’s investigation covers issues in Nanotechnology, Biophysics, Cantilever, Nanowire and Condensed matter physics. His Nanotechnology study typically links adjacent topics like Solar cell. His Biophysics research incorporates themes from Crystallography, Cytoplasm and Order of magnitude.

His Cantilever research incorporates elements of Conductive atomic force microscopy, Solvation, Deflection, Surface stress and Photothermal spectroscopy. His Nanowire research integrates issues from Phase transition, Mott insulator, Field-effect transistor, Crystallite and Sapphire. His Condensed matter physics study combines topics in areas such as Magnetization, Nanomagnet and Magnetic logic.

His most cited work include:

• Single-Domain Circular Nanomagnets (955 citations)
• Room Temperature Magnetic Quantum Cellular Automata (871 citations)
• An analytical solution to the kinetics of breakable filament assembly (750 citations)

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

His scientific interests lie mostly in Nanotechnology, Optoelectronics, Condensed matter physics, Microscopy and Analytical chemistry. His research integrates issues of Biophysics and Molecule in his study of Nanotechnology. He specializes in Optoelectronics, namely Silicon.

His Condensed matter physics research includes themes of Magnetic domain, Magnetization, Nanomagnet and Magnetic anisotropy. Mark E. Welland has included themes like Conductive atomic force microscopy, Scanning probe microscopy and Quantum tunnelling in his Microscopy study. His study in Scanning probe microscopy is interdisciplinary in nature, drawing from both Scanning tunneling microscope and Scanning capacitance microscopy.

He most often published in these fields:

• Nanotechnology (28.76%)
• Optoelectronics (18.01%)
• Condensed matter physics (15.59%)

What were the highlights of his more recent work (between 2010-2021)?

• Nanotechnology (28.76%)
• Biophysics (8.60%)
• Nanowire (9.41%)

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

Mark E. Welland focuses on Nanotechnology, Biophysics, Nanowire, Fibril and Optoelectronics. His studies in Nanotechnology integrate themes in fields like Chemical physics, Crystallite, Microscopy and Electronics. The study incorporates disciplines such as Biochemistry, Protein aggregation, Peptide, Molecule and Kinetics in addition to Biophysics.

His work deals with themes such as Domain dynamics and Photoconductivity, which intersect with Nanowire. His Optoelectronics study incorporates themes from Field-effect transistor, Dye-sensitized solar cell, Electron-beam lithography and Nano-. He works mostly in the field of Nanostructure, limiting it down to topics relating to Magnetic field and, in certain cases, Condensed matter physics, as a part of the same area of interest.

Between 2010 and 2021, his most popular works were:

• Nucleated polymerization with secondary pathways. I. Time evolution of the principal moments. (220 citations)
• α-Synuclein Senses Lipid Packing Defects and Induces Lateral Expansion of Lipids Leading to Membrane Remodeling (131 citations)
• Binding of the molecular chaperone αB-crystallin to Aβ amyloid fibrils inhibits fibril elongation. (113 citations)

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

• Quantum mechanics
• Electron
• Semiconductor

Mark E. Welland mainly focuses on Nanotechnology, Biophysics, Fibril, Lysozyme and Biochemistry. He integrates many fields in his works, including Nanotechnology and Cytotoxicity. Mark E. Welland combines subjects such as Static electricity, Crystallography, Electrostatics, Kinetics and Peptide with his study of Biophysics.

The various areas that he examines in his Fibril study include Molecule, Elongation, Quartz crystal microbalance and Nucleation. Mark E. Welland has researched Lysozyme in several fields, including Native state and Energy landscape. His work on Plasma protein binding as part of general Biochemistry research is frequently linked to Immunoelectron microscopy, thereby connecting diverse disciplines of science.

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