Title :
Field emission applications of graphene
Author :
Cole, M.T. ; Milne, W.I. ; Chi Li ; Wei Lei ; Boaping Wang ; Hallam, Toby ; Duesberg, G.S.
Author_Institution :
Dept. of Eng., Cambridge Univ., Cambridge, UK
Abstract :
Graphene has a huge variety of unique optoelectronic properties. Its recent rapid emergence and demonstrable richness in electron transport has been unprecedented. This atomically thin, ordered structure has exceptionally high attainable aspect ratios - potentially higher even than that of carbon nanotubes - whilst defective edge terminations rich in dangling bonds render it superior to metallic nanowires; qualifying graphene as a striking candidate for a variety of field emission applications following the addressing of various challenging fabrication issues. Herein we present a few potential uses of graphene in electron emission applications; specifically in micro-contact printing nanoscale fin electron sources, an edge-emission graphene-based video-rate display, and a highly electron transparent gate electrode capable of flat-band transparency and high beam collimation.
Keywords :
dangling bonds; electrodes; electron field emission; graphene; transparency; C; carbon nanotubes; dangling bonds; edge-emission graphene-based video-rate display; electron emission; electron sources; electron transparent gate electrode; electron transport; field emission; flat-band transparency; high beam collimation; metallic nanowires;; microcontact printing nanoscale; optoelectronic properties; Anodes; Fabrication; Logic gates; Pipelines; Solvents; Substrates; chemical vapour deposition; electron emisison display; electron transparency; field emission; gate electrode; graphene; microprinting;
Conference_Titel :
Vacuum Nanoelectronics Conference (IVNC), 2014 27th International
Conference_Location :
Engelberg
Print_ISBN :
978-1-4799-5306-6
DOI :
10.1109/IVNC.2014.6894827
