Molecular Electronics

General Subjects.- The role of theory in molecular electronics.- Theoretical Basis of Monoelectronic Input/Output Devices.- Correlated single-electron tunneling via ultrasmall metal particle.- Tunnel electron current dependence on voltage in molecular bridge.- Electronic Properties of Molecular Materials.- Models of extended electron states in proteins.- Electronic instabilities in biological information processing.- Current-voltage characteristics of the bacteriorhodopsin.- Metal to metal intramolecular electron transfer across peptide and protein bridges.- The immobilization of horse radish peroxidase on metal surface.- A Raman spectroscopic study of microtubule protein.- Distant electron transfer in proteins. The role of electrostatic interactions and histidine residues in the electron transfer from myoglobin to cytochrome C.- Molecular Engineering and Molecular Films.- Conducting Langmuir-Blodgett films of mixture of hexadecylbis (ethylenedithio)-TTF and hexadecyl-TCNQ.- Langmuir-Blodgett superlattices, their structure and methods of production.- On the possible use of molecular films for recording and storing information.- Phthalocyanine thin films for molecular electronics.- New highly precise and well defined Langmuir-Blodgett film deposition system.- Monolayer assemblies in the search for ways to engineer on the molecular level.- Solvent permittivity dispersion electrostatic model better fit kinetic data.- X-ray photoelectron spectroscopy study of surface protein orientation.- The new bilayer lipid membrane system: prospects for applications in biomolecular electronic devices.- Neuronet-Like Architecture and New Approaches Computation.- Adaptive behavior in sub-neural microtubule automata.- Spatio-temporal behavior and 1/f-type spectrum of alpha rhythm in brainwave.- Molecular control network.- Fields and vision.- On the biophysical structure of brain-like biocomputers.- Experimental analysis of mechanisms of information fixation by means of molecular neuroprocessor.- Molecular-level neuroelectronics.- Biosensors.- Micro electromechanical actuators based on conducting polymers.- Does nature utilize a common design for photoactive transport and sensor proteins?.- Biosensors and information processes: present state and future projects.- General principles of creating biosensing units based on double-stranded nucleic acid liquid crystals.