Advances in Plasma Processes for Polymers

doi:10.3390/books978-3-0365-3915-7

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Advances in Plasma Processes for Polymers

Edited by

June 2022

370 pages

ISBN978-3-0365-3916-4 (Hardback)
ISBN978-3-0365-3915-7 (PDF)

https://doi.org/10.3390/books978-3-0365-3915-7

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This book is a reprint of the Special Issue Advances in Plasma Processes for Polymers that was published in

Chemistry & Materials Science

Engineering

Summary

Polymerized nanoparticles and nanofibers can be prepared using various processes, such as chemical synthesis, the electrochemical method, electrospinning, ultrasonic irradiation, hard and soft templates, seeding polymerization, interfacial polymerization, and plasma polymerization. Among these processes, plasma polymerization and aerosol-through-plasma (A-T-P) processes have versatile advantages, especially due to them being “dry", for the deposition of plasma polymer films and carbon-based materials with functional properties suitable for a wide range of applications, such as electronic and optical devices, protective coatings, and biomedical materials. Furthermore, it is well known that plasma polymers are highly cross-linked, pinhole free, branched, insoluble, and adhere well to most substrates. In order to synthesize the polymer films using the plasma processes, therefore, it is very important to increase the density and electron temperature of plasma during plasma polymerization.

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Keywords

polytetrafluoroethylene; fluorine depletion; hydrogen plasma; VUV radiation; surface modification; hydrophilic; polyamide; gaseous plasma; water contact angle; XPS; polyamide membranes; surface modification; magnetron sputtering; TiO₂ + AgO coatings; low-pressure plasma; plasma treatment; polyaniline (PANI); conductive polymer; plasma polymerization; aniline; atmospheric pressure plasma reactor (AP plasma reactor); in-situ iodine (I₂) doping; atmospheric pressure plasma; filler; polylactic acid; polymer composite; polyethylene; surface modification; corona discharge; polyethylene glycol; adhesion; polymer; low-pressure plasma; plasma treatment; surface modification; biomedical applications; additive manufacturing; toluidine blue method; enzymatic degradation; microwave discharge; discharges in liquids; microwave discharge in liquid hydrocarbons; methods of generation; plasma properties; gas products; solid products; plasma diagnostics; plasma modeling; atmospheric pressure plasma; room temperature growth; plasma polymerization; porous polythiophene; conducting polymer; NO₂; gas sensors; ion beam sputtering; polymer; continuum equation; plasma; sublimation; PA6.6; cold plasma; atmospheric pressure plasma; electrical discharges; voltage multiplier; polymers; oleofobization; paper; cellulose; plasma; HMDSO; atmospheric-pressure plasma; solution plasma; plasma polymerization; polymer films; room temperature growth; nanoparticles; surface wettability; graphene oxide; plasma treatment; cyclic olefin copolymer; GO reduction; titanium (Ti) alloys; low-temperature plasma polymerization; plasma-fluorocarbon-polymer; anti-adhesive surface; inflammatory/immunological response; intramuscularly implantation; atmospheric pressure plasma jet; dielectric barrier discharge; piezoelectric direct discharge; surface free energy; test ink; surface activation; allyl-substituted cyclic carbonate; free-radical polymerization; atmospheric-pressure plasma; low-pressure plasma; plasma process; plasma polymerisation; surface modification; plasma deposition; poly(lactic acid); PLA; ascorbic acid; fumaric acid; plasma treatment; grafting; wettability; adhesion; BOPP foil; DCSBD; VDBD; surface wettability; adhesion; ageing; surface functionalization; atmospheric pressure plasmas; glow-like discharge; single pin electrode; plasma deposition; PANI thin film