Reprint

Electrochemically Engineering of Nanoporous Materials

Edited by
September 2018
158 pages
  • ISBN978-3-03897-268-6 (Paperback)
  • ISBN978-3-03897-269-3 (PDF)

This is a Reprint of the Special Issue Electrochemically Engineering of Nanoporous Materials that was published in

Chemistry & Materials Science
Engineering
Summary

Electrochemical engineering of nanoporous materials is a cost-effective and facile synthesis approach that enables the production of a range of nanoscale materials with controllable dimensions and properties. Recent decades have witnessed extensive research activity into the advanced engineering of nanoporous materials, from fundamental studies to applied science. These nanomaterials offer a set of unique and exclusive advantages for a wealth of applications, including catalysis, energy storage and harvesting, electronics, photonics, sensing, templates, and membranes.

This Special Issue is dedicated to recent research advances in electrochemical engineering of nanoporous materials and their application across several disciplines and research fields. The broad and interdisciplinary applicability of these nanomaterials will be of profound and immediate interest for a broad audience, ranging from physicists, chemists, engineers, materials scientists, bioengineers, and nanomedicine experts.

Format
  • Paperback
License and Copyright
© 2019 by the authors; CC BY license
Keywords
drug delivery; nanoporous anodic alumina; complex pore geometry; release rate; nanotechnology; lithium ion battery; lithium iron phosphate; solvothermal method; micro hollow sphere; porous silicon; drug delivery; electrospinning; poly(ε-caprolactone); supercapacitor; self-doped polyaniline; carbon-nanoparticle film; electropolymerization; cyclic voltammetry; supercapacitor; polymer ionic liquid; ionic liquid; solid electrolyte; photopolymerization; nanoporous alumina templates; antidot arrays; Kerr effect; magnetic anisotropy; magnetic domains; magnetic force microscopy; carbon aerogel; graphitic cluster; metal nanoparticle; oxygen reduction reaction; electro-catalysis; anodization; copper oxides; nanostructures; passivation; nanowires; nanoneedles; band gap; electrosorption; titania nanotubes; nanostructured electrodes; RVC/a-SWCNT composite electrode; capacitive deionization; water purification; desalination technology; n/a

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