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Nanoscale Interface for Organic Electronics
This book treats the important issues of interface control in organic devices in a wide range of applications that cover from electronics, displays, and sensors to biorelated devices. This book is composed of three parts: Part 1, Nanoscale interface; Part 2, Molecular electronics; Part 3, Polymer electronics.
The Physical Properties of Organic Monolayers
Ch. 5. Dielectric relaxation phenomena. 5.1. Rotational Debye Brownian motion model. 5.2. Relaxation process at an air-water interface. 5.3. Determination of dielectric relaxation time. 5.4. Summary. References -- ch. 6. Chiral phase separation. 6.1. Elastic energy and Bragg-Williams mixing energy. 6.2. Chiral phase separation. 6.3. Discrete one-dimensional CPS solution. 6.4. Summary. 6.5. Appendix. References -- ch. 7. Nonlinear effects. 7.1. SOS in orientational order parameters for C[symbol] monolayers. 7.2. Chirality representation. 7.3. SHG-CD effect. 7.4. SHG-MDC measuring system. 7.5. Quantum mechanical analysis of photoisomerization. 7.6. Summary. References -- ch. 8. Thermally-stimulated current. 8.1. Thermally-stimulated current. 8.2. Depolarization due to thermal stimulation. 8.3. TSC experiment. 8.4. Phase transition. 8.5. Thermodynamics approach to monolayers. 8.6. Summary. References -- ch. 9. Electronic properties at MIM interfaces. 9.1. Tunneling current and electronic device applications. 9.2. Nanometric interfacial electrostatic phenomena in ultrathin films. 9.3. I-V characteristic. 9.4. Summary. References.
Maxwell Displacement Current And Optical Second-harmonic Generation In Organic Materials: Analysis And Application For Organic Electronics
The probing and modeling of carrier transport in materials is a fundamental research subject in electronics and materials science. According to the Maxwell electromagnetic field theory, there are two kinds of currents, i.e., conduction current and Maxwell displacement current (MDC). The conduction current flows when electronic charges, e.g., electrons and holes, are conveyed in solids, whereas MDC is the transient current that is generated due to the change of electric flux density. The source of conductive current is charged particles, i.e., electrons, holes, ions, etc., and the source of MDC is also the charged particles. It is therefore anticipated that we can probe and model carrier tran...
Polyimides and other high temperature polymers
Annotation Containing 32 peer-reviewed papers, this volume documents the proceedings of the international symposium of the same name (held under the aegis of the Materials Science and Technology Conferences) in December of 2001. Devoted to research into high-temperature polymers, the papers are organized into sections dealing with synthesis, properties, and bulk characterization in the first half and surface modification, interfacial or adhesion aspects, and applications in the second. Annotation (c)2003 Book News, Inc., Portland, OR (booknews.com).
Polyimides and Other High Temperature Polymers: Synthesis, Characterization and Applications
This volume chronicles the proceedings of the Third International Symposium on Polyimides and Other High Temperature Polymers: Synthesis, Characterization, and Applications, held in Orlando, December 17-19, 2003. This volume is divided into three parts. Part 1. “Synthesis, Properties and Bulk Characterization”; Part 2 “Hybrids and Composites” and Part 3 “Applications and General Papers”. The topics covered include: Synthesis, characterization and processing (including some novel approaches) of a variety of polyimides and other high temperature polymers; structure-property relationships; hybrids and nanocomposites using these materials and their characterization, properties and applications; segmental dynamics in polyimide materials; photoalignable polyimides; photoconductivity and photosensitivity of polyimides; ultrafiltration membranes from polyetherimide; polyimide as a tunneling barrier; polymer materials for nonlinear optical applications; alignment of SWNTs in rigid-rod polymer compositions; surface modification of polyimide; adhesion of Cu to polyimide surfaces; and polyimide erosion in a low Earth orbit space environment.
Energy Efficiency and Renewable Energy Through Nanotechnology
Reflecting the rapid growth of nanotechnology research and the potential impact of the growing energy crisis, Energy Efficiency and Renewable Energy Through Nanotechnology provides comprehensive coverage of cutting-edge research in the energy-related fields of nanoscience and nanotechnology, which aim to improve energy efficiency and the generation of renewable energy. Energy Efficiency and Renewable Energy Through Nanotechnology tightly correlates nanotechnology with energy issues in a general, comprehensive way that makes it not only suitable as a desk reference for research, but also as a knowledge resource for the non-expert general public. Readers will find Energy Efficiency and Renewable Energy Through Nanotechnology useful in a variety of ways, ranging from the creation of energy policy, to energy research development, and to education in nanotechnology and its application to energy-related problems. It can also be used as a primary or supplementary textbook for energy-related courses for advanced undergraduate and graduate students.
Electrical and Geometrical Properties of Organic Monolayers
This book addresses the physical mechanisms involved in the characteristic electrical properties and the geometrical structures that are observed from dipolar monolayers composed of organic molecules by using dielectric physics, electrostatics, the physics of liquid crystal, and soft matter physics. The orientational order parameters, introduced to quantify the orientational structures of monolayers, guide us towards this goal. Dielectric polarizations are spontaneously generated from monolayers because of their orientational structures, and electrostatic energies due to these dielectric polarizations play a key role in forming the geometrical structures that are observed from monolayers. Free energy minimization is a powerful tool to understand the physical mechanisms that stabilize these geometrical structures because of the soft matter nature of monolayers. The approach makes this book unique among the literatures of monolayers.
