TY - BOOK ID - 145592494 TI - Advances in Plasma Processes for Polymers PY - 2022 PB - Basel MDPI - Multidisciplinary Digital Publishing Institute DB - UniCat KW - Technology: general issues KW - Chemical engineering KW - polytetrafluoroethylene KW - fluorine depletion KW - hydrogen plasma KW - VUV radiation KW - surface modification KW - hydrophilic KW - polyamide KW - gaseous plasma KW - water contact angle KW - XPS KW - polyamide membranes KW - magnetron sputtering KW - TiO2 + AgO coatings KW - low-pressure plasma KW - plasma treatment KW - polyaniline (PANI) KW - conductive polymer KW - plasma polymerization KW - aniline KW - atmospheric pressure plasma reactor (AP plasma reactor) KW - in-situ iodine (I2) doping KW - atmospheric pressure plasma KW - filler KW - polylactic acid KW - polymer composite KW - polyethylene KW - corona discharge KW - polyethylene glycol KW - adhesion KW - polymer KW - biomedical applications KW - additive manufacturing KW - toluidine blue method KW - enzymatic degradation KW - microwave discharge KW - discharges in liquids KW - microwave discharge in liquid hydrocarbons KW - methods of generation KW - plasma properties KW - gas products KW - solid products KW - plasma diagnostics KW - plasma modeling KW - room temperature growth KW - porous polythiophene KW - conducting polymer KW - NO2 KW - gas sensors KW - ion beam sputtering KW - continuum equation KW - plasma KW - sublimation KW - PA6.6 KW - cold plasma KW - electrical discharges KW - voltage multiplier KW - polymers KW - oleofobization KW - paper KW - cellulose KW - HMDSO KW - atmospheric-pressure plasma KW - solution plasma KW - polymer films KW - nanoparticles KW - surface wettability KW - graphene oxide KW - cyclic olefin copolymer KW - GO reduction KW - titanium (Ti) alloys KW - low-temperature plasma polymerization KW - plasma-fluorocarbon-polymer KW - anti-adhesive surface KW - inflammatory/immunological response KW - intramuscularly implantation KW - atmospheric pressure plasma jet KW - dielectric barrier discharge KW - piezoelectric direct discharge KW - surface free energy KW - test ink KW - surface activation KW - allyl-substituted cyclic carbonate KW - free-radical polymerization KW - plasma process KW - plasma polymerisation KW - plasma deposition KW - poly(lactic acid) KW - PLA KW - ascorbic acid KW - fumaric acid KW - grafting KW - wettability KW - BOPP foil KW - DCSBD KW - VDBD KW - ageing KW - surface functionalization KW - atmospheric pressure plasmas KW - glow-like discharge KW - single pin electrode KW - PANI thin film KW - polytetrafluoroethylene KW - fluorine depletion KW - hydrogen plasma KW - VUV radiation KW - surface modification KW - hydrophilic KW - polyamide KW - gaseous plasma KW - water contact angle KW - XPS KW - polyamide membranes KW - magnetron sputtering KW - TiO2 + AgO coatings KW - low-pressure plasma KW - plasma treatment KW - polyaniline (PANI) KW - conductive polymer KW - plasma polymerization KW - aniline KW - atmospheric pressure plasma reactor (AP plasma reactor) KW - in-situ iodine (I2) doping KW - atmospheric pressure plasma KW - filler KW - polylactic acid KW - polymer composite KW - polyethylene KW - corona discharge KW - polyethylene glycol KW - adhesion KW - polymer KW - biomedical applications KW - additive manufacturing KW - toluidine blue method KW - enzymatic degradation KW - microwave discharge KW - discharges in liquids KW - microwave discharge in liquid hydrocarbons KW - methods of generation KW - plasma properties KW - gas products KW - solid products KW - plasma diagnostics KW - plasma modeling KW - room temperature growth KW - porous polythiophene KW - conducting polymer KW - NO2 KW - gas sensors KW - ion beam sputtering KW - continuum equation KW - plasma KW - sublimation KW - PA6.6 KW - cold plasma KW - electrical discharges KW - voltage multiplier KW - polymers KW - oleofobization KW - paper KW - cellulose KW - HMDSO KW - atmospheric-pressure plasma KW - solution plasma KW - polymer films KW - nanoparticles KW - surface wettability KW - graphene oxide KW - cyclic olefin copolymer KW - GO reduction KW - titanium (Ti) alloys KW - low-temperature plasma polymerization KW - plasma-fluorocarbon-polymer KW - anti-adhesive surface KW - inflammatory/immunological response KW - intramuscularly implantation KW - atmospheric pressure plasma jet KW - dielectric barrier discharge KW - piezoelectric direct discharge KW - surface free energy KW - test ink KW - surface activation KW - allyl-substituted cyclic carbonate KW - free-radical polymerization KW - plasma process KW - plasma polymerisation KW - plasma deposition KW - poly(lactic acid) KW - PLA KW - ascorbic acid KW - fumaric acid KW - grafting KW - wettability KW - BOPP foil KW - DCSBD KW - VDBD KW - ageing KW - surface functionalization KW - atmospheric pressure plasmas KW - glow-like discharge KW - single pin electrode KW - PANI thin film UR - https://www.unicat.be/uniCat?func=search&query=sysid:145592494 AB - 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. ER -