Reprint

Ion and Molecule Transport in Membrane Systems

Edited by
August 2021
368 pages
  • ISBN978-3-0365-1359-1 (Hardback)
  • ISBN978-3-0365-1360-7 (PDF)

This book is a reprint of the Special Issue Ion and Molecule Transport in Membrane Systems that was published in

Biology & Life Sciences
Chemistry & Materials Science
Medicine & Pharmacology
Summary
Membranes play an enormous role in our life. Biological cell membranes control the fluxes of substances in and out of cells. Artificial membranes are widely used in numerous applications including “green” separation processes in chemistry, agroindustry, biology, medicine; they are used as well in energy generation from renewable sources. They largely mimic the structure and functions of biological membranes. The similarity in the structure leads to the similarity in the properties and the approaches to study the laws governing the behavior of both biological and artificial membranes. In this book, some physico-chemical and chemico-physical aspects of the structure and behavior of biological and artificial membranes are investigated.
Format
  • Hardback
License
© by the authors
Keywords
ion exchange membranes; profiled membranes; corrugated membranes; electrodialysis; reverse electrodialysis; membrane capacitive deionization; hydrodynamic; mass transfer; thermal pressing; 3D printing; acid whey; electrodialysis; pulsed electric field; demineralization; scaling; lactic acid removal; electrodialysis; reverse electrodialysis; ion exchange membrane; profiled membrane; CFD; pressure drop; mass transfer; structural mechanics; fluid-structure interaction; whey; electrodialysis; pulsed electric field; pulsed electrodialysis reversal; fouling; electrodialysis with filtration membrane (EDFM); triple size-selective separation; glucose uptake; bioassay-guided validation; bioactive peptides; ion exchange membranes; electro-convective instability; overlimiting current; concentration polarisation; particle tracking; biomimetic membrane; ion pair amphiphile; cholesterol; molecular dynamics; water permeation; air-pollutant nanoparticle; coarse-grained model; interaction; molecular dynamics simulation; pulmonary surfactant monolayer; PP membrane; O2 plasma; TiO2 nanoparticles; UV treatment; hydrophilicity; biopolymer electrolyte membranes; XRD analysis; FTIR study; Morphology; Impedance study; EDLC fabrication; LaPO4: Ce; Tb; ionic liquid; supported liquid membrane; photoluminescence; hyperbranched polymer; crosslinking; alkaline fuel cells; ionic conductivity; water swelling; ion-exchange membranes; ion-exchange particles; heterogeneity; electrokinetics; current–voltage curves; ion-exchange membrane; Fujifilm; Neosepta; phosphate transport; limiting current density; voltammetry; zinc–air battery; separator; hydroxide exchange membrane; anion-exchange membrane; ionic channel; polyphenylene oxide; polymer inclusion membrane; ionic liquids; volatile fatty acids (VFAs); acetic acids; hexanoic acids; anomalous water diffusion; computer simulations; ion channel gating; molecular dynamics; nano-size water pore; physico-chemical properties of confined water; protein-water interactions; TRPV1 channel permeability for water; water dynamics; water H-bonding; NETs; inner nuclear membrane; outer nuclear membrane; nuclear envelope; polymer blends; impedance study; dielectric properties; electric modulus study; loss tangent peaks; ion transport parameters; Trukhan model; salinity gradient power; reverse electrodialysis; concentration difference; electrolyte composition; n/a; n/a