Materials Research Society, Jan 19, 2001 - Technology & Engineering - 109 pages
In conventional microelectronics, devices are fabricated by lithographic processes. Ultimately, for devices with feature lengths below 100nm, alternative approaches may become necessary. This book focuses on materials issues that relate to the fabrication of nanoelectronics in which the active regions of devices are either molecules or nanoparticles, and self-assembly replaces lithography. The volume is interdisciplinary in nature and features work by a diverse gathering of chemists, physicists, materials scientists and mainstream silicon engineers. Materials of interest include, but are not limited to, organic molecules, carbon nanotubes and semiconductor nanoclusters.
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2000 Materials Research alkanethiol alumina template Appl atoms band bending band gap behavior bias biopolymer capacitance carbon nanotubes carrier CdSe chains Chem chemical Chemistry clusters colloid conductance Coulomb blockade density deposition deposition chemistry Dept dipole dopant doped effect electrical electronic devices electronic structure energy level experimental fabrication Fermi level Figure function I-V characteristics ISBN layer Lett level alignment ligand luminescence M. S. Dresselhaus Materials Research Society measurements metal nanoparticles Molecular Electronics molecular wire molecule monolayer nanocrystals nanoparticles nanoscale negative differential resistance observed optical organic organic/metal interfaces oxide particles Phys plasmon polymer probe quantum dots R. M. Metzger resistance resonant tunneling room temperature sample Science self-assembled self-assembled monolayer semiconductor shown single electron solution spectra spectroscopy substrate surface synthesis Te-doped Bi nanowires technique thin films thiol threshold voltage transport properties undoped vacuum level voltage Volume wire diameter