What is she best known for?
The fields of study she is best known for:
- Optics
- Nanotechnology
- Photon
Odile Stéphan mainly focuses on Nanotechnology, Transmission electron microscopy, Carbon nanotube, Electron energy loss spectroscopy and Nanotube.
Her Nanotechnology study combines topics in areas such as Detection limit, Raman scattering and Nonlinear optics.
Her work on High-resolution transmission electron microscopy as part of general Transmission electron microscopy study is frequently linked to Fiber, therefore connecting diverse disciplines of science.
She regularly links together related areas like Graphite in her Carbon nanotube studies.
Her study on Electron energy loss spectroscopy also encompasses disciplines like
- Boron nitride which is related to area like Analytical chemistry and Phenomenological model,
- Molecular physics and related Dielectric and Graphene.
Odile Stéphan interconnects Monolayer, Thin film, Mineralogy and Ceramic in the investigation of issues within Nanotube.
Her most cited work include:
- Aligned Carbon Nanotube Arrays Formed by Cutting a Polymer Resin—Nanotube Composite (1298 citations)
- Mapping surface plasmons on a single metallic nanoparticle (769 citations)
- Doping Graphitic and Carbon Nanotube Structures with Boron and Nitrogen (640 citations)
What are the main themes of her work throughout her whole career to date?
Odile Stéphan mostly deals with Nanotechnology, Electron energy loss spectroscopy, Carbon nanotube, Scanning transmission electron microscopy and Plasmon.
Nanotechnology is closely attributed to Nanometre in her study.
She has researched Electron energy loss spectroscopy in several fields, including Boron nitride, Cathodoluminescence, Molecular physics, Atomic physics and Analytical chemistry.
Her research in Molecular physics focuses on subjects like Dielectric, which are connected to Anisotropy.
Her work in Carbon nanotube tackles topics such as Graphite which are related to areas like Sulfur and Inorganic chemistry.
Her Scanning transmission electron microscopy research is multidisciplinary, incorporating perspectives in Condensed matter physics and Band gap.
She most often published in these fields:
- Nanotechnology (27.80%)
- Electron energy loss spectroscopy (26.97%)
- Carbon nanotube (19.09%)
What were the highlights of her more recent work (between 2015-2021)?
- Condensed matter physics (13.28%)
- Scanning transmission electron microscopy (16.18%)
- Optics (13.28%)
In recent papers she was focusing on the following fields of study:
Her primary areas of study are Condensed matter physics, Scanning transmission electron microscopy, Optics, Electron energy loss spectroscopy and Optoelectronics.
The study incorporates disciplines such as Thin film, Bismuth, Nuclear magnetic resonance and Conductivity in addition to Condensed matter physics.
Odile Stéphan has included themes like Photon, Surface phonon, Heterojunction and Nanostructure in her Scanning transmission electron microscopy study.
Her Electron energy loss spectroscopy research includes elements of Characterization, Molecular physics, Electron energy and Atomic physics.
Her work in the fields of Plasmon overlaps with other areas such as Variable.
Her study in the fields of Surface plasmon under the domain of Plasmon overlaps with other disciplines such as Resonance.
Between 2015 and 2021, her most popular works were:
- Bright UV Single Photon Emission at Point Defects in h-BN. (168 citations)
- Electron Energy Loss Spectroscopy imaging of surface plasmons at the nanometer scale. (67 citations)
- Revisiting Graphene Oxide Chemistry via Spatially-Resolved Electron Energy Loss Spectroscopy (42 citations)
In her most recent research, the most cited papers focused on:
Her main research concerns Scanning transmission electron microscopy, Condensed matter physics, Plasmon, Electron energy loss spectroscopy and Nanotechnology.
The concepts of her Scanning transmission electron microscopy study are interwoven with issues in Optoelectronics, Band gap and High-resolution transmission electron microscopy.
Her Condensed matter physics research is multidisciplinary, relying on both Exchange bias, Thin film and Analytical chemistry.
Her studies deal with areas such as Electron microscope and Nanoscopic scale as well as Plasmon.
She combines subjects such as Oxide, Graphene, Graphene oxide paper, Atomic physics and Electron beam processing with her study of Electron energy loss spectroscopy.
Her research in the fields of Nanoparticle overlaps with other disciplines such as Particle.
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