Title :
Field emission from nanocomposites
Author :
Lerner, Peter ; Miskovsky, N.M. ; Cutler, P.H.
Author_Institution :
CW2F Inc., Ithaca, NY, USA
Abstract :
We study field emission from wide band gap semiconductor-metal nanocomposites. The grains of the wide band gap semiconductor are assumed to be embedded into the layers of metal. Interfacial charge transfer gives rise to metal-induced gap states (MIGS) in the vicinity of the grains. If the density of the semiconductor grains is large, MIGS hybridize with the states in the conduction band of the semiconductor forming a quasi-band. This quasi-band can be populated by the electrons from the metallic matrix through the scattering in the metal-semiconductor composite. The location of the high-lying MIGS in the vicinity of the conduction band of the semiconductor reduces a barrier between these states and the vacuum level. Thus low-threshold field emission from a nanocomposite becomes possible. We support our hypothesis through Monte Carlo simulation of transport through a nanocomposite
Keywords :
Monte Carlo methods; composite materials; conduction bands; electron field emission; nanostructured materials; wide band gap semiconductors; Monte Carlo simulation; conduction band; electron scattering; electron transport; embedded semiconductor grains; interfacial charge transfer; low-threshold field emission; metal-induced gap states; metallic matrix; quasi-band; wide band gap semiconductor-metal nanocomposite; Acceleration; Dielectrics; Electron emission; Gallium nitride; Nanocomposites; Particle scattering; Photonic band gap; Physics; Wave functions; Wide band gap semiconductors;
Conference_Titel :
Vacuum Microelectronics Conference, 2001. IVMC 2001. Proceedings of the 14th International
Conference_Location :
Davis, CA
Print_ISBN :
0-7803-7197-6
DOI :
10.1109/IVMC.2001.939659
