Henny W. Zandbergen

What is she best known for?

The fields of study she is best known for:

• Quantum mechanics
• Electron
• Oxygen

Her primary areas of investigation include Nanotechnology, Transmission electron microscopy, Superconductivity, Crystallography and Inorganic chemistry. When carried out as part of a general Nanotechnology research project, her work on Nanopore, Graphene and Scanning probe microscopy is frequently linked to work in Chemical imaging, therefore connecting diverse disciplines of study. Henny W. Zandbergen has included themes like Chemical physics, Silicon oxide and Silicon, Thermal oxidation in her Nanopore study.

Her Transmission electron microscopy study combines topics in areas such as Particle, Scanning electron microscope, Optoelectronics, Catalysis and Metallurgy. Her Superconductivity study is related to the wider topic of Condensed matter physics. Her studies in Crystallography integrate themes in fields like Electron diffraction, Phase, Boron and Intermetallic.

Her most cited work include:

• Fabrication of solid-state nanopores with single-nanometre precision. (1072 citations)
• Superlubricity of Graphite (802 citations)
• Superconductivity in Cu x Bi 2 Se 3 and its Implications for Pairing in the Undoped Topological Insulator (640 citations)

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

Her primary scientific interests are in Crystallography, Condensed matter physics, Analytical chemistry, Transmission electron microscopy and Superconductivity. The concepts of her Crystallography study are interwoven with issues in Electron microscope, Electron diffraction and Lattice constant. Her Electron diffraction research includes elements of Superstructure and Neutron diffraction.

Henny W. Zandbergen has researched Condensed matter physics in several fields, including Thin film and Grain boundary. Transmission electron microscopy is the topic of her studies on Nanotechnology and Chemical engineering. Her Superconductivity study focuses on High-temperature superconductivity in particular.

She most often published in these fields:

• Crystallography (32.95%)
• Condensed matter physics (22.06%)
• Analytical chemistry (21.20%)

What were the highlights of her more recent work (between 2009-2021)?

• Transmission electron microscopy (17.48%)
• Nanotechnology (11.75%)
• Analytical chemistry (21.20%)

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

Henny W. Zandbergen mainly investigates Transmission electron microscopy, Nanotechnology, Analytical chemistry, Graphene and Chemical engineering. Her Transmission electron microscopy research integrates issues from Crystallography, Annealing, Hydrogen storage, Nanoreactor and Nanocrystal. Her research in Crystallography intersects with topics in Chemical physics and Zinc, Wurtzite crystal structure.

Her study in the field of Nanopore, Nanoparticle, Nanomaterials and Nanowire is also linked to topics like Spark. Her Analytical chemistry research includes themes of Gas composition, Epitaxy, Platinum, Optoelectronics and Conductivity. Her Graphene study combines topics from a wide range of disciplines, such as Atomic units, Monolayer, Graphite and Nanostructure.

Between 2009 and 2021, her most popular works were:

• Superconductivity in Cu x Bi 2 Se 3 and its Implications for Pairing in the Undoped Topological Insulator (640 citations)
• Atomic-scale electron-beam sculpting of near-defect-free graphene nanostructures. (193 citations)
• Controlling Defects in Graphene for Optimizing the Electrical Properties of Graphene Nanodevices (143 citations)

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

• Quantum mechanics
• Electron
• Oxygen

Henny W. Zandbergen mainly focuses on Transmission electron microscopy, Nanotechnology, Graphene, Nanopore and Chemical engineering. Her studies deal with areas such as Atomic units, Crystallography, Aluminium, Alloy and Aqueous solution as well as Transmission electron microscopy. The study incorporates disciplines such as Delafossite and Stacking in addition to Crystallography.

Her Nanotechnology study incorporates themes from Spectroscopy, Heterojunction and Absorption spectroscopy. Her Graphene research incorporates themes from Scanning transmission electron microscopy, Graphite, Cathode ray and Nanostructure. Her research investigates the link between Nanometre and topics such as Copper that cross with problems in Superconductivity.