Mon premier blog

Carbon Nanotube and Graphene Device Physics by H. S. Philip Wong, Deji Akinwande

Carbon Nanotube and Graphene Device Physics H. S. Philip Wong, Deji Akinwande ebook
Page: 263
Publisher: Cambridge University Press
Format: pdf
ISBN: 0521519055, 9780521519052

Third, my work suggests applications of nanoribbon to future nanoelectronic devices. Nazarpour has extensive experience in advanced carbon nanomaterials such as carbon nanotube and graphene, device physics, materials processing and integration. I have suggested that the combinations of nanoribbons will lead to further interesting physics. These electronic properties are amazingly rich in comparison with those of carbon nanotubes. Recently, nitrogen-doped carbon nanotubes and ZnO NWs have been grown on reduced graphene. In our Special Topic on Graphene, the paper "Peculiar width dependence of the electronic properties of carbon nanoribbons" (Phys. Carbon nanotube and graphene device modeling and simulation. However, most of the This study was conducted by research teams based in the Department of Physics and Astronomy at Seoul National University and from the Samsung Advanced Institute of Technology, South Korea. Graphene, a 2D carbon nanomaterial with a honeycomb-like structure, has been the subject of a considerable interest after being the subject of the 2010 Nobel Prize for Physics. 180] at room temperature, tunable band-gap (for few-layer graphene), high chemical and mechanical stability, low electrical noise, high thermal conductivity, and biocompatibility, have led it to be used in many advanced devices ranging from ultra-capacitors to spintronic devices [181–186]. Trions have been observed in a variety of systems, but surprisingly, in view of their rich prospects for device applications and basic research, not in semiconducting carbon nanotubes (CNTs). Metallic NW-graphene hybrid nanostructures point towards highly efficient and flexible field emission devices.