Molecular and biomolecular electronics : developed from a symposium sponsored by the Division of Biochemical Technology of the American Chemical Society at the Fourth Chemical Congress of North America (202nd National Meeting of the American Chemical Society), New York, New York, August 25-30, 1991

This work is developed from a symposium sponsored by the Division of Biochemical Technology of the American Chemical Society at the Fourth Chemical Congress of North America (202nd National Meeting of the American Chemical Society), New York City, New York, August 25-30, 1991. It is a comprehensive reivew of molecular and biomolecular electronics, the final stage in miniaturization of computer circuitry that provides promising new methodologies for high-speed signal processing and communication, novel associative and neural architectures, and linear and nonlinear devices and memories. The book includes coverage of quantum electronics, nanoscale semiconductor fabrication, genetic engineering, molecular biophysics, self-assembly and nonlinear optics. Each chapter includes an overview of the fundamental methods and procedures followed by a review of recent research.

• Introduction to molecular and biomolecular electronics, Robert R. Birge
• prospects for semiconductor quantum devices, Mark R. Reed and Alan C. Seabaugh
• the fitness of carbon for computing, Michael Conrad
• molecular electronic transition current density - simple orbital transitions, Laurence A. Nafie
• the quest for D-s-A unimolecular rectifiers and related topics in molecular electronics, Robert M. Metzger
• fundamentals of reliability calculations for molecular devices and photochromic memories, Albert F. Lawrence and Robert R. Birge
• two-photon three-dimensional optical storage memory, A.S. Dvornikov and P.M. Rentzepis
• optimization of materials for second-order nonlinear optical applications, Christopher B. Gorman et al
• the role of intermolecular interactions in molecular electronics - computational design of architectures with large second-order optical nonlinearities, Santo Di Bella et al
• theoretical insight into the design of organic molecules for third-order nonlinear optical applications, Brian M. Pierce
• molecular optoelectronics based on phthalocyanine, Tatsuo Wada et al
• liquid crystals as holographic recording media, Jian Zhang and Michael B. Sponsler
• molecular devices using Langmuir-Blodgett films, O. Albrecht et al
• photoinduced electron transfer and energy transfer in Langmuir-Blodgett films, Masamichi Fujihira
• intelligent biomaterials based on Langmuir-Blodgett monolayer films - biotinylated polymers-streptavidin and biotinylated lipid-steptavidin recogition incorporating photodynamic proteins, K.A. Marx et al
• colloid chemical approach to band-gap engineering and quantum-tailored devices, Janos H. Fendler
• self-assembling bilayer lipid membranes on solid support - building blocks of future biosensors and molecular devices, A. Ottova-Leitmannova et al
• self-assembling tubules from phospholipids, R. Shashidhar and J.M. Schnur
• engineering proteins for electrooptical biomaterials, Patrick S. Stayton et al
• the photochemical reaction cycle of bacteriorhodopsin, Janos K. Lanyi
• bacteriorhodopsin variants for holographic pattern recognition, Norbert Hampp et al
• retinal proteins in photovoltaic devices, Felix T. Hong
• photodiodes based on bateriorhodopsin, George W. Rayfield.