Functional Nanoporous Materials
With pore sizes up to 100 nm, the term "nanoporous" covers a wide range of material classes. A broad field of applications has arisen from the diversity of unique structures and properties of nanoporous materials. Recent research spans the range from fundamental studies of the behavior of...
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Weinberger, Christian edt Functional Nanoporous Materials Basel, Switzerland MDPI - Multidisciplinary Digital Publishing Institute 2020 1 electronic resource (128 p.) text txt rdacontent computer c rdamedia online resource cr rdacarrier With pore sizes up to 100 nm, the term "nanoporous" covers a wide range of material classes. A broad field of applications has arisen from the diversity of unique structures and properties of nanoporous materials. Recent research spans the range from fundamental studies of the behavior of atoms and molecules in confined space, creative synthetic pathways for novel materials, to applications in high-performance technologies. This Special Issue collects current studies about the progress in the development, characterization, and application of nanoporous materials, including (but not restricted to) mesoporous silica, carbon and metal oxides, porous coordination polymers, metal organic frameworks (MOFs), and covalent organic frameworks (COFs), as well as materials exhibiting hierarchical porosity. Their functionalities show promise for fields such as energy storage/conversion (e.g., photocatalysis and battery electrodes), sensing, catalysis, and their sorption properties for N2, CO2, NOx, or H2O, to name just a few. English History of engineering & technology bicssc mesoporous silica organocatalysis host-guest materials magic-angle spinning NMR (MAS-NMR) nanoporous metal foam nanoshell buckling free vibration strain gradient theory first-order shear deformation theory SERS near-infrared crystal silicon photoluminescence porous silicon photonic crystals hot-spots mesoporous films direct growth esterification material formation porous organic polymers amine modification CO2 separation adsorption mechanism chemisorption of CO2 Birnessite nanoporous metal oxides impedance spectroscopy perovskite solar cell electron selective layer pinhole mesoporous TiO2 evaporation-induced self-assembly dip coating 3-03928-895-4 3-03928-896-2 Tiemann, Michael edt Weinberger, Christian oth Tiemann, Michael oth |
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English |
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Tiemann, Michael Weinberger, Christian Tiemann, Michael |
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Tiemann, Michael Weinberger, Christian Tiemann, Michael |
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HerausgeberIn Sonstige Sonstige |
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Functional Nanoporous Materials |
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Functional Nanoporous Materials |
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Functional Nanoporous Materials |
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Functional Nanoporous Materials |
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Functional Nanoporous Materials |
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Functional Nanoporous Materials |
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Functional Nanoporous Materials |
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functional nanoporous materials |
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MDPI - Multidisciplinary Digital Publishing Institute |
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2020 |
physical |
1 electronic resource (128 p.) |
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3-03928-895-4 3-03928-896-2 |
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Not Illustrated |
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AT weinbergerchristian functionalnanoporousmaterials AT tiemannmichael functionalnanoporousmaterials |
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(CKB)5400000000040588 (oapen)https://directory.doabooks.org/handle/20.500.12854/68675 (EXLCZ)995400000000040588 |
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Functional Nanoporous Materials |
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