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Journal of Materials Science

Erschienen in:

01.05.2015 | Original Paper

Underwater discharge plasma-induced coating of poly(acrylic acid) on polypropylene fiber

verfasst von: A. Khlyustova, O. Galmiz, M. Zahoran, A. Brablec, M. Černak

Erschienen in: Journal of Materials Science | Ausgabe 9/2015

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Abstract

An underwater diaphragm discharge generated at atmospheric pressure by high voltage pulses was used for plasma polymerization of acrylic acid and simultaneously for the deposition of polymer coating on polypropylene multifilament fibers. The deposition process was monitored by Fourier transform infrared spectroscopy in combination with scanning electron microscopy. Possible schemes of polymerization are suggested also.

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Inagaki N (1996) Plasma surface modification and plasma polymerization. Tecnomic Publishing, Lancaster

Poncin-Epaillard F, Chevet B, Brosse JC (1994) Modification of isotactic polypropylene by a cold plasma or an electron beam and grafting of the acrylic acid onto these activated polymers. J Appl Polym Sci 53:1291–1306CrossRef

Sellin N, Sinezio J, Campos C (2003) Surface composition analysis of PP films treated by corona discharge. Mater Res 6:163–166CrossRef

Dogue ILJ, Mermilliod N, Boiron G, Staveris S (1995) Improvement of polypropylene film adhesion in multilayers by various chemical surface modifications. Int J Adhes Adhes 15:205–210CrossRef

Dogue ILJ, Forch R, Mermilliod N (1995) Grafting of acrylic acid onto polypropylene—comparison of two pretreatments: γ-irradiation and argon plasma. Nucl Instr Methods Phys Res B 105:164–167CrossRef

Winnik FM, Morneau A, Mika AM, Childs RF, Roig A, Molins E (1998) Polyacrylic acid pore-filled microporous membranes and their use in membrane-mediated synthesis of nanocrystalline ferrihydrite. Can J Chem 76:10–17CrossRef

Gao JZ (2006) A novel technique for wasterwater treatment by contact glow discharge electrolysis. Pak J Biol Sci 9:323–329CrossRef

Khlustova AV, Maximov AI, Subbotkina IN (2010) The electrical discharge action on the wastewater for cleaning. High Temp Mater Proc 14:185–191CrossRef

Dors M, Metel E, Mizeraczyk J (2007) Phenol degradation in water by pulsed streamer corona discharge and Fenton reaction. Int J Plasma Environ Sci Technol 1:76–81

10.

Lu QF, Yu J, Gao JZ (2006) Degradation of 2,4-dichlorophenol by using glow discharge electrolysis. J Hazard Mater 136:526–531CrossRef

11.

Joshi R, Schulze RD, Meyer-Plath A, Friedrich JF (2008) Selective surface modification of poly(propylene) with OH and COOH groups using liquid-plasma systems. Plasma Process Polym 5:695–707CrossRef

12.

Maximov A (2007) Physics, chemistry and application of the AC diaphragm discharge and related discharges in electrolyte solutions. Contrib Plasma Phys 47:111–118CrossRef

13.

Teslenko VS, Drozhzhin AP, Sankin GN (2006) The autocyclic ring breakdown in electrolyte with induced collapse of bubbles. Lett J Technol Phys 32:24–31 (in Russian)

14.

Khlyustova AV, Manakhov AM, Maksimov AI (2009) A scenario of development of low-voltage “underwater” discharge. Surf Eng Appl Electrochem 45:485–488CrossRef

15.

Nikiforov AY, Leys C (2007) Influence of capillary geometry and applied voltage on hydrogen peroxide and OH radical formation in AC underwater electrical discharges. Plasma Sources Sci Technol 16:273–280CrossRef

16.

Yang P, Deng JY, Tai YW (2003) Confined photo-catalytic oxidation: a fast surface hydrophilic modification method for polymeric materials. Polymer 44:7157–7164CrossRef

17.

Malik MA, Ahmed M, Rehman E, Naheed R, Ghaffar A (2003) Synthesis of superabsorbent copolymers by pulsed corona discharges in water. Plasma Polym 8:271–279CrossRef

18.

Siaratta V, Vohrer U, Hegemann D, Muller M, Oehr C (2003) Plasma functionalization of polypropylene with acrylic acid. Surf Coat Technol 174–175:805–810CrossRef

19.

Morent R, De Geyter N, Leys C, Gengembre L, Payen E (2008) Comparison between XPS- and FTIR-analysis of plasma-treated polypropylene film surfaces. Surf Interface Anal 40:597–600CrossRef

20.

Kirwan LJ, Fawell PD, van Brounswijk W (2003) In situ FTIR-ATR examination of poly(acrylic acid) adsorbed onto hematite at low pH. Langmuir 19:5802–5807CrossRef

21.

Choi HS, Kim YS, Zhang Y, Tang S, Myung SW, Shin BS (2004) Plasma-induced graft co-polymerization of acrylic acid onto polyurethane surface. Surf Coat Technol 182:55–64CrossRef

22.

Gornukhina OV, Shikova TG, Ageeva TA, Titov VA, Golubchikov OA (2008) Post-plasma graft co-polymerization of polypropylene and acrylic acid. Chem Chem Technol 51:75–79 (in Russian)

23.

Alavi MHS, Habibi M, Amrollahi R, Afshar Taromi F (2011) A study of plasma polymerization of acrylic acid using APF plasma focus device. J Fusion Energy 30:184–189CrossRef

24.

Golubchikov OA, Gornukhina OV, Vershinina IA, Ageeva TA, Titov VA (2007) The polypropylene materials of medical purpose modificated by acetylsalicylic acid. Chem Chem Technol 50:65–68 (in Russian)

Titel: Underwater discharge plasma-induced coating of poly(acrylic acid) on polypropylene fiber
verfasst von: A. Khlyustova
O. Galmiz
M. Zahoran
A. Brablec
M. Černak
Publikationsdatum: 01.05.2015
Verlag: Springer US
Erschienen in: Journal of Materials Science / Ausgabe 9/2015
Print ISSN: 0022-2461
Elektronische ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-015-8913-4

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