ACCU DYNE TEST ™ Bibliography
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208. Lanauze, J.A., and D.L. Myers, “Ink adhesion on corona-treated polyethylene studied by chemical derivatization of surface functional groups,” J. Applied Polymer Science, 40, 595-611, (1990).
211. Lavielle, L., J. Schultz, and K. Nakajima, “Acid-base surface properties of modified poly(ethylene terephthalate) films and gelatin: relationship to adhesion,” J. Applied Polymer Science, 42, 2825-2831, (1991).
215. Lee, L.-H., “Relationship between surface wettability and glass transition temperature of high polymers,” J. Applied Polymer Science, 12, 719-730, (1968).
248. Moshonov, A., and Y. Avny, “The use of acetylene glow discharge for improving adhesive bonding of polymeric films,” J. Applied Polymer Science, 25, 771-781, (1980).
263. Occhiello, E., M. Morra, G. Morini, F. Garbassi, and P. Humphrey, “Oxygen-plasma-treated polypropylene interfaces with air, water, and epoxy resins, Part I. Air and water,” J. Applied Polymer Science, 42, 551-559, (1991).
264. Occhiello, E., M. Morra, G. Morini, F. Garbassi, and P. Humphrey, “Oxygen-plasma-treated polypropylene interfaces with air, water, and epoxy resins, Part II. Epoxy resins,” J. Applied Polymer Science, 42, 2045-2052, (1991).
269. Olafsen, K., A. Stori, and D.A. Tellefsen, “Grafting of acrylic acid onto corona-treated polyethylene surfaces,” J. Applied Polymer Science, 46, 1673-1676, (1992).
272. Onyiriuka, E.C., “The effects of high-energy radiation on the surface chemistry of polystyrene: a mechanistic study,” J. Applied Polymer Science, 47, 2187-2194, (1993).
277. Owens, D.K., and R.C. Wendt, “Estimation of the surface free energy of polymers,” J. Applied Polymer Science, 13, 1741-1747, (1969).
278. Owens, D.K., “Mechanism of corona-induced self-adhesion of polyethylene film,” J. Applied Polymer Science, 19, 265-271, (1975).
279. Owens, D.K., “The mechanism of corona and ultraviolet light-induced self-adhesion of poly(ethylene terephthalate) film,” J. Applied Polymer Science, 19, 3315-3326, (1975).
307. Sakata, I., M. Morita, H. Furuichi, and Y. Kawaguchi, “Improvement of plybond strength of paperboard by corona treatment,” J. Applied Polymer Science, 42, 2099-2104, (1991).
308. Sakata, I., M. Morita, N. Tsurata, and K. Morita, “Activation of wood surface by corona treatment to improve adhesive bonding,” J. Applied Polymer Science, 49, 1251-1258, (1993).
319. Schonhorn, H., and R.H. Hansen, “Surface treatment of polymers for adhesive bonding,” J. Applied Polymer Science, 11, 1461-1473, (1967).
322. Schonhorn, H., and R.H. Hansen, “Surface treatment of polymers, II. Effectiveness of fluorination as a surface treatment for polyethylene,” J. Applied Polymer Science, 12, 1231-1237, (1968).
324. Schonhorn, H., and F.W. Ryan, “Surface crosslinking of polyethylene and adhesive joint strength,” J. Applied Polymer Science, 18, 235-243, (1974).
376. Wang, L.-H., and R.S. Porter, “The surface orientation of polystyrene measured by liquid contact angle,” J. Applied Polymer Science, 28, 1439-1445, (1983).
394. Yagi, T., A.E. Pavlath, and A.G. Pittman, “Grafting fluorocarbons to polyethylene in glow discharge,” J. Applied Polymer Science, 27, 4019-4028, (1982).
440. Cho, D.L., P.M. Claesson, C.-G. Golander, and K. Johansson, “Structure and surface properties of plasma polymerized acrylic acid layers,” J. Applied Polymer Science, 41, 1373-1390, (1990).
461. Gagnon, D.R., and T.J. McCarthy, “Polymer surface reconstruction by diffusion of organic functional groups from and to the surface,” J. Applied Polymer Science, 29, 4335-4340, (1984).
481. Hollahan, J.R., and G.L. Carlson, “Hydroxylation of polymethylsiloxane surfaces by oxidizing plasmas,” J. Applied Polymer Science, 14, 2499-2508, (1970).
537. Morita, M., N. Tsurata, and K. Morita, “Activation of wood surface by corona treatment to improve adhesive bonding,” J. Applied Polymer Science, 49, 1251-1258, (Aug 1993).
591. Vogel, S.L., and H. Schonhorn, “Adhesion of evaporated films onto polyethylene and poly(tetrafluorethylene): importance of surface crosslinking,” J. Applied Polymer Science, 23, 495+, (1979).
687. Ulren, L., and T. Hjertberg, “Adhesion between aluminum and copolymers of ethylene and vinyltrimethoxysilane,” J. Applied Polymer Science, 37, 1269-1285, (1989).
689. Sessler, G.M., J.E. West, F.W. Ryan, and H. Schonhorn, “Increase of gold-teflon FEP joint strength by electron bombardment,” J. Applied Polymer Science, 17, 3199-3209, (1973).
823. Toyama, M., T. Ito, H. Nukatsuka, and M. Ikeda, “Studies on tack of pressure-sensitive adhesive tapes: On the relationship between pressure-sensitive adhesion and surface energy of adherents,” J. Applied Polymer Science, 17, 3495-3502, (Nov 1973).
938. Iyengar, Y., and D.E. Erickson, “Role of adhesive-substrate compatability in adhesion,” J. Applied Polymer Science, 11, 2311-2324, (1967).
957. Jingxin, L., and L. Xia, “Surface graft polymerization of 2-hydroxyethyl methacrylate onto low-density polyethylene film through corona discharge in air,” J. Applied Polymer Science, 81, 2881-2887, (Sep 2001).
966. Suezer, S., A. Argun, O. Vatansever, and O. Aral, “XPS and water contact angle measurements on aged and corona treated PP,” J. Applied Polymer Science, 74, 1846-1850, (Nov 1999).
976. Ogawa, T., H. Mukai, and S. Osawa, “Effects of functional groups and surface roughness on interfacial shear strength in ultrahigh molecular weight polyethylene fiber/polyethylene system,” J. Applied Polymer Science, 71, 243-249, (Jan 1999).
997. Foldes, E., A. Toth, E. Kalman, E. Fekete, and A. Tomasovszky-Bobak, “Surface changes of corona-discharge-treated polyethylene films,” J. Applied Polymer Science, 76, 1529-1541, (Jun 2000).
1025. Kim, S.R., “Surface modification of polytetrafluoroethylene film by chemical etching, plasma and ion beam treatments,” J. Applied Polymer Science, 77, 1913-1920, (Aug 2000).
1028. Seto, F., Y. Muraoka, T. Akagi, A. Kishida, and M. Akashi, “Surface grafting of poly(vinylamine) onto poly(ethylene) film by corona discharge-induced grafting,” J. Applied Polymer Science, 72, 1583-1587, (Jun 1999).
1030. Yamaguchi, M., “Effect of molecular structure in branched polyethylene on adhesion properties with polypropylene,” J. Applied Polymer Science, 70, 457-463, (Oct 1998).
1038. Seok-Keun, K., P. Sung-Chul, K. Sung-Ryong, et al, “Surface modification of polytetrafluoroethylene by Ar+ irradiation for improved adhesion to other materials,” J. Applied Polymer Science, 64, 1913-1921, (Jun 1997).
1044. Lynch, J.B., P.D. Spence, D.E. Baker, and T.A. Postlethwaite, “Atmospheric pressure plasma treatment of polyethylene via a pulse dielectric barrier discharge: Comparison using various gas compositions versus corona discharge in air.,” J. Applied Polymer Science, 71, 319-331, (Jan 1999).
1266. Belgacem, M.N., P. Bataille, and S. Sapieha, “Effect of corona modification on the mechanical properties of polypropylene/cellulose composites,” J. Applied Polymer Science, 53, 379-385, (Jul 1994).
1269. Guimond, S., and M.R. Wertheimer, “Surface degradation and hydrophobic recovery of polyolefins treated by air corona and nitrogen atmospheric pressure glow discharge,” J. Applied Polymer Science, 94, 1291-1303, (Nov 2004).
The surface degradation and production of low molecular weight oxidized materials (LMWOM) on biaxially oriented polypropylene (BOPP) and low-density polyethylene (LDPE) films was investigated and compared for two different dielectric barrier discharge (DBD) treatment types, namely air corona and nitrogen atmospheric pressure glow discharge (N2 APGD). Contact angle measurements, X-ray photoelectron spectroscopy (XPS), and atomic force microscopy (AFM) analyses were performed in conjunction with rinsing the treated films in water. It is shown that N2 APGD treatments of both polyolefins result in much less surface degradation, therefore, allowing for a significantly higher degree of functionalization and better wettability. Hydrophobic recovery of the treated films has also been studied by monitoring their surface energy (γs) over a period of time extending up to several months after treatment. Following both surface modification techniques, the treated polyolefin films were both found to undergo hydrophobic recovery; however, for N2 APGD modified surfaces, γs ceases to decrease after a few days and attains a higher stable value than in the case of air corona treated films. © 2004 Wiley Periodicals, Inc. J Appl Polym Sci 94: 1291–1303, 2004
https://onlinelibrary.wiley.com/doi/abs/10.1002/app.21134
1271. Farley, J.M., P. Meka, “Heat sealing of semicrystalline polymer films, III. Effect of corona discharge treatment of LLDPE,” J. Applied Polymer Science, 51, 121-131, (Jan 1994).
1275. Lei, J., and X. Liao, “Surface graft copolymerization of 2-hyrdoxyethyl methacrylate onto low-density polyethylene film through corona discharge in air,” J. Applied Polymer Science, 81, 2881-2887, (Sep 2001).
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