University of Manchester
The scientist’s investigation covers issues in Graphene, Optoelectronics, Electron, Heterojunction and Quantum tunnelling. Graphene is a primary field of his research addressed under Nanotechnology. His work deals with themes such as Thin film, Absorption, Boron nitride, Molybdenum disulfide and Transistor, which intersect with Heterojunction.
His Quantum tunnelling study combines topics from a wide range of disciplines, such as Quasiparticle, Dirac fermion and Elementary particle. He interconnects Atom, Potential applications of graphene and Orders of magnitude in the investigation of issues within Quantum. The concepts of his Graphene nanoribbons study are interwoven with issues in Mechanical strength, Graphene derivatives and Carbon nanotube.
His primary areas of study are Graphene, Condensed matter physics, Optoelectronics, Electron and Nanotechnology. His Graphene research integrates issues from Heterojunction, Quantum tunnelling and Quantum Hall effect. His Condensed matter physics research incorporates themes from Hall effect, Magnetic field and van der Waals force.
His studies deal with areas such as Absorption and Electric field as well as Optoelectronics. His Electron study combines topics in areas such as Magnetic flux quantum, Quasiparticle, Quantum, Dirac fermion and Phonon. His Nanotechnology study integrates concerns from other disciplines, such as Plasmon and Surface plasmon.
His primary areas of investigation include Condensed matter physics, Graphene, Exciton, van der Waals force and Electron. His study on Polariton is often connected to Optical microcavity as part of broader study in Condensed matter physics. His Graphene research is included under the broader classification of Nanotechnology.
His Nanotechnology research is multidisciplinary, relying on both Orders of magnitude and Surface plasmon. The Exciton study combines topics in areas such as Photonics, Monolayer and Photoluminescence. His study in van der Waals force is interdisciplinary in nature, drawing from both Heterojunction and Quantum tunnelling.
His primary scientific interests are in Nanotechnology, Graphene, Surface modification, Plasmon and Surface plasmon. Graphene and Thermal conductivity are frequently intertwined in his study. His Thermal conductivity research is multidisciplinary, incorporating elements of Electrical contacts, Chemical vapor deposition, Impurity and Optical transparency.
His Surface modification research incorporates a variety of disciplines, including Passivation, Biosensor, Orders of magnitude and Surface plasmon resonance.
This overview was generated by a machine learning system which analysed the scientist’s body of work. If you have any feedback, you can contact us here.
Detection of Individual Gas Molecules Absorbed on Graphene
F. Schedin;A. K. Geim;S. V. Morozov;D. Jiang.
arXiv: Materials Science (2006)
Fine Structure Constant Defines Visual Transparency of Graphene
R. R. Nair;P. Blake;P. Blake;A. N. Grigorenko;K. S. Novoselov.
A roadmap for graphene
K. S. Novoselov;Vladimir Falko;L. Colombo;P. R. Gellert.
Detection of individual gas molecules adsorbed on graphene
F. Schedin;A. K. Geim;S. V. Morozov;E. W. Hill.
Nature Materials (2007)
Chiral tunnelling and the Klein paradox in graphene
M. I. Katsnelson;K. S. Novoselov;A. K. Geim.
Nature Physics (2006)
Giant intrinsic carrier mobilities in graphene and its bilayer
S. V. Morozov;K. S. Novoselov;M. I. Katsnelson;F. Schedin.
Physical Review Letters (2008)
Field-effect tunneling transistor based on vertical graphene heterostructures.
L. Britnell;R. V. Gorbachev;R. Jalil;B. D. Belle.
Making graphene visible
P. Blake;E. W. Hill;A. H. Castro Neto;K. S. Novoselov.
Applied Physics Letters (2007)
Strong light-matter interactions in heterostructures of atomically thin films.
Líam Britnell;R. M. Ribeiro;R. M. Ribeiro;A. Eckmann;R. Jalil.
Making graphene visible
P. Blake;K. S. Novoselov;A. H. Castro Neto;D. Jiang.
arXiv: Mesoscale and Nanoscale Physics (2007)
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