Title :
Metal/insulator heterostructure quantum effect device
Author :
Watanabe, M. ; Suemasu, T. ; Kohno, Y. ; Saitoh, W. ; Asada, M.
Author_Institution :
Dept. of Electr. & Electron. Eng., Tokyo Inst. of Technol., Japan
Abstract :
Metal-insulator (M-I) superlattice is very attractive for ultra-fine, multifunctional and ultrahigh-speed quantum-effect electron devices because of the high carrier density of metal, low dielectric constant of insulator, and remarkable quantum-effect due to very large conduction-band discontinuity (>10 eV) at an M-I heterointerface. And moreover, optical devices using the same material system (metal-insulator and semiconductor heterostructure) is considered to be possible utilizing the optical transition between quantized energy levels in metal or semiconductor quantum wells or boxes embedded in insulator. In order to expand our study to 3-dimensional quantum confinement effect devices using CaF2-CoSi2-Si(111) material system, we have investigated a formation technique of nanometer grains of Si and CoSi 2 embedded in CaF2. In a metal or semiconductor quantum box embedded in insulator barriers a strong 3-dimensional quantum confinement effect can be expected
Keywords :
MIS devices; calcium compounds; cobalt compounds; elemental semiconductors; high-speed optical techniques; nanostructured materials; nanotechnology; photoluminescence; quantum interference devices; resonant tunnelling transistors; semiconductor quantum dots; semiconductor quantum wells; silicon; size effect; CaF2-CoSi2-Si; CaF2-CoSi2-Si(111); carrier density; conduction-band discontinuity; dielectric constant; formation technique; metal/insulator heterostructure quantum effect device; nanometer grains; optical transition; quantized energy levels; quantum confinement effect devices; semiconductor quantum boxes; semiconductor quantum wells; superlattice; ultrahigh-speed quantum-effect electron devices; Charge carrier density; Dielectric constant; Dielectrics and electrical insulation; Electron devices; Metal-insulator structures; Metallic superlattices; Optical devices; Optical materials; Potential well; Semiconductor materials;
Conference_Titel :
Lasers and Electro-Optics Society Annual Meeting, 1995. 8th Annual Meeting Conference Proceedings, Volume 1., IEEE
Conference_Location :
San Francisco, CA
Print_ISBN :
0-7803-2450-1
DOI :
10.1109/LEOS.1995.484522
