Buch, Englisch, 200 Seiten, Format (B × H): 159 mm x 245 mm, Gewicht: 467 g
Buch, Englisch, 200 Seiten, Format (B × H): 159 mm x 245 mm, Gewicht: 467 g
ISBN: 978-0-415-32701-5
Verlag: CRC Press
Nanoporous materials are used widely in industry as adsorbents, particularly for applications where selective adsorption of one fluid component from a mixture is important. Nanoscale structures are of increasing interest for micro- and nanofluidic devices. Computational methods have an important role to play in characterizing, understanding, and designing such materials. Adsorption and Transport at the Nanoscale gives a survey of computational methods and their applications in this burgeoning field.
Beginning with an overview of adsorption and transport phenomena at the nanoscale, this book details several important simulation techniques for characterization and modeling of nanomaterials and surfaces. Expert contributors from Europe, Asia, and the US discuss topics including Monte Carlo simulation for modeling gas adsorption; experimental and simulation studies of aniline in activated carbon fibers; molecular simulation of templated mesoporous materials and adsorption of guest molecules in zeolitic materials; as well as computer simulation of isothermal mass transport in graphitic slit pores. These studies elucidate the chemical and physical phenomena while demonstrating how to perform the simulation techniques, illustrating their advantages, drawbacks, and limitations.
A survey of recent progress in numerical simulation of nanomaterials, Adsorption and Transport at the Nanoscale explains the central role of molecular simulation in characterizing and designing novel materials and devices.
Zielgruppe
Professional
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
Adsorption and Transport at the Nanoscale. Modelling Gas Adsorption in Slit-Pores using Monte Carlo Simulation. Effect of Confinement on Melting in Slit-Shaped Pores: Experimental and Simulation Study of Aniline in Activated Carbon Fibers. Synthesis and Characterization of Templated Mesoporous Materials using Molecular Simulation. Adsorption/Condensation of Xenon in Mesopores Having a Microporous Texture or a Surface Roughness. Molecular Simulation of Adsorption of Guest Molecules in Zeolitic Materials: A Comparative Study of Intermolecular Potentials. Molecular Dynamics Simulations for 1:1 Solvent Primitive Model Electrolyte Solutions. Computer Simulation of Isothermal Mass Transport in Graphite Slit Pores. Simulation Study of Sorption of CO2 and N2 with Application to the Characterization of Carbon Adsorbents. Index.
