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Temperature control. --- Surface energy. --- Adhesion. --- Dust. --- Charge transfer. --- Control surfaces.
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Temperature control. --- Surface energy. --- Adhesion. --- Dust. --- Control surfaces. --- Meteorite collisions. --- Charge transfer. --- Gas giant planets.
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Nonadiabatic transition is a highly multidisciplinary concept and phenomenon, constituting a fundamental mechanism of state and phase changes in various dynamical processes of physics, chemistry and biology, such as molecular dynamics, energy relaxation, chemical reaction, and electron and proton transfer. Control of molecular processes by laser fields is also an example of time-dependent nonadiabatic transition. In this new edition, the original chapters are updated to facilitate enhanced understanding of the concept and applications. Three new chapters - comprehension of nonadiabatic chemica
Charge exchange. --- Phase transformations (Statistical physics) --- Phase changes (Statistical physics) --- Phase transitions (Statistical physics) --- Phase rule and equilibrium --- Statistical physics --- Electron transfer --- Exchange, Charge --- Transfer, Electron --- Charge transfer --- Collisions (Nuclear physics)
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Mechanism of charge transport in organic solids has been an issue of intensive interests and debates for over 50 years, not only because of the applications in printing electronics, but also because of the great challenges in understanding the electronic processes in complex systems. With the fast developments of both electronic structure theory and the computational technology, the dream of predicting the charge mobility is now gradually becoming a reality. This volume describes recent progresses in Prof. Shuai’s group in developing computational tools to assess the intrinsic carrier mobility for organic and carbon materials at the first-principles level. According to the electron-phonon coupling strength, the charge transport mechanism is classified into three different categories, namely, the localized hopping model, the extended band model, and the polaron model. For each of them, a corresponding theoretical approach is developed and implemented into typical examples.
Materials. --- Organic electrochemistry --- Charge transfer --- Organic electronics --- Carbon compounds --- Chemistry --- Physical Sciences & Mathematics --- Organic Chemistry --- Physical & Theoretical Chemistry --- Electric properties --- Electron transport. --- Organic electronics. --- Chemistry. --- Chemoinformatics. --- Chemistry, Physical and theoretical. --- Semiconductors. --- Optical materials. --- Electronic materials. --- Materials science. --- Theoretical and Computational Chemistry. --- Optical and Electronic Materials. --- Computer Applications in Chemistry. --- Characterization and Evaluation of Materials. --- Material science --- Physical sciences --- Electronic materials --- Optics --- Materials --- Crystalline semiconductors --- Semi-conductors --- Semiconducting materials --- Semiconductor devices --- Crystals --- Electrical engineering --- Electronics --- Solid state electronics --- Chemistry, Theoretical --- Physical chemistry --- Theoretical chemistry --- Chemical informatics --- Chemiinformatics --- Chemoinformatics --- Chemistry informatics --- Information science --- Data processing --- Organic solid state chemistry --- Electrons --- Energy-band theory of solids --- Free electron theory of metals --- Transport theory --- Surfaces (Physics). --- Physics --- Surface chemistry --- Surfaces (Technology) --- Computational chemistry --- Theoretical Chemistry. --- Optical Materials. --- Computational Chemistry. --- Characterization and Analytical Technique. --- Data processing. --- Analysis.
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