ACCU DYNE TEST ™ Bibliography
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101. Foerch, R., J. Izawa, and G. Spears, “Comparative study of the effects of remote nitrogen plasma, remote oxygen plasma, and corona discharge treatments on the surface properties of polyethylene,” J. Adhesion Science and Technology, 5, 549-564, (1991).
102. Foerch, R., G. Kill, and M.J. Walzak, “Plasma surface modification of polyethylene: short-term vs. long-term plasma treatment,” J. Adhesion Science and Technology, 7, 1077-1089, (1993).
195. Kinbara, A., A. Kikuchi, S. Baba, and T. Abe, “Effect of plasma treatment of PTFE substrates on the adhesion characteristics of vacuum-deposited Au films,” J. Adhesion Science and Technology, 7, 457-466, (1993).
218. Lee, L.-H., “Roles of molecular interactions in adhesion, adsorption, contact angle, and wettability,” J. Adhesion Science and Technology, 7, 583-634, (1993) (also in Contact Angle, Wettability and Adhesion: Festschrift in Honor of Professor Robert J. Good, K.L. Mittal, ed., p. 45-96, VSP, Nov 1993).
246. Morra, M., E. Occhiello, and F. Garbassi, “Chemical reactions on plasma-treated polyethylene surfaces,” J. Adhesion Science and Technology, 7, 1051-1063, (1993).
283. Papirer, E., D.Y. Wu, and J. Schultz, “Adhesion of flame-treated polyolefins to styrene butadiene rubber,” J. Adhesion Science and Technology, 7, 343-362, (1993).
438. Chen, K.S., Y. Uyama, and Y. Ikada, “Adhesive-free adhesion of grafted surfaces with different wettabilities,” J. Adhesion Science and Technology, 6, 1023-1035, (1992).
458. Fowkes, F.M., “Role of acid-base interfacial bonding in adhesion,” J. Adhesion Science and Technology, 1, 7-27, (1987).
465. Golander, C.-G., and B.-A. Sultan, “Surface modification of polyethylene to improve its adhesion to aluminum,” J. Adhesion Science and Technology, 2, 125, (1988).
486. Inagaki, N., S. Tasaka, H. Kawai, and Y. Kimura, “Hydrophilic surface modification of polyethylene by NO-plasma treatment,” J. Adhesion Science and Technology, 4, 99-107, (1990).
580. Strobel, J.M., M. Strobel, C.S. Lyons, C. Dunatov, and S.J. Perron, “Aging of air-corona-treated polypropylene film,” J. Adhesion Science and Technology, 5, 119-130, (1991).
581. Strobel, M., C.S. Lyons, J.M. Strobel, and R.S. Kapaun, “Analysis of air-corona-treated polypropylene and polyethylene terephthalate films by contact angle measurement and X-ray photoelectron spectroscopy,” J. Adhesion Science and Technology, 6, 429-443, (1992) (also in Contact Angle, Wettability and Adhesion: Festschrift in Honor of Professor Robert J. Good, K.L. Mittal, ed., p. 493-507, VSP, Nov 1993).
587. Varughese, K.T., P.P. De, and S.K. Sanyal, “Contact angle behavior of poly(vinyl chloride)/epoxidized natural rubber miscible blends,” J. Adhesion Science and Technology, 3, 541-550, (1989).
619. Strobel, M., M.J. Walzak, J.M. Hill, A. Lin, E. Karbshenski, and C.S. Lyons, “A comparison of gas phase methods of modifying polymer surfaces,” J. Adhesion Science and Technology, 9, 365+, (1994).
817. Kim, J.K., H.S. Kim, and D.G. Lee, “Adhesion characteristics of carbon/epoxy composites treated with low- and atmospheric-pressure plasmas,” J. Adhesion Science and Technology, 17, 1751-1771, (2003).
842. Borch, J., “Thermodynamics of polymer-paper adhesion: A review,” J. Adhesion Science and Technology, 5, 523-541, (1991).
958. Cho, D.L., K.H. Shin, W.-J. Lee, and D.-H. Kim, “Improvement of paint adhesion to a polypropylene bumper by plasma treatment,” J. Adhesion Science and Technology, 15, 653-664, (2001).
964. Cho, C.K., B.K. Kim, and C.E. Park, “The aging effects of repeated oxygen plasma treatment on the surface rearrangement and adhesion of LDPE to aluminum,” J. Adhesion Science and Technology, 14, 1071-1083, (2000).
969. Nakamatsu, J., L.F. Delgado-Aparicio, R. Da Silva, and F. Soberon, “Ageing of plasma-treated poly(tetrafluoroethylene) surfaces,” J. Adhesion Science and Technology, 13, 753-761, (1999).
970. Kawabe, M., S. Tasaka, and N. Inagaki, “Effects of nitrogen plasma treatment of pressure-sensitive adhesive layer surfaces on their peel adhesion behaviour,” J. Adhesion Science and Technology, 13, 573-592, (1999).
977. Della Volpe, C., A. Deimichei, and T. Ricco, “Multiliquid approach to the surface free energy determination of flame-treated surfaces of rubber-toughened polypropylene,” J. Adhesion Science and Technology, 12, 1141-1180, (1998).
979. Seung-Goo, L., K. Tae-Jin, and Y. Tae-Ho, “Enhanced interfacial adhesion of ultra-high molecular weight polyethylene (UHMWPE) fibres by oxygen plasma treatment,” J. Adhesion Science and Technology, 12, 731-748, (1998).
983. Xiao, G.Z., “Effects of solvents on the surface properties of oxygen plasma-treated polyethylene and polypropylene films,” J. Adhesion Science and Technology, 11, 655-663, (1997).
989. Strobel, M., M.C. Branch, M. Ulsh, R.S. Kapuan, S. Kirk, and C.S. Lyons, “Flame surface modification of polypropylene film,” J. Adhesion Science and Technology, 10, 515-539, (Jun 1996).
991. Good, R.J., “Contact angle, wetting, and adhesion: A critical review,” J. Adhesion Science and Technology, 6, 1269-1302, (1992) (also in Contact Angle, Wettability and Adhesion: Festschrift in Honor of Professor Robert J. Good, K.L. Mittal, ed., p. 3-36, VSP, Nov 1993).
993. Corn, S., K.P. Vora, M. Strobel, and C.S. Lyons, “Enhancement of adhesion to polypropylene films by chlorotrifluoromethane plasma treatment,” J. Adhesion Science and Technology, 5, 239-245, (1991).
1007. Strobel, M., N. Sullivan, M.C. Branch, V. Jones, J. Park, M. Ulsh, et al., “Gas-phase modelling of impinging flames used for the flame surface modification of polypropylene film,” J. Adhesion Science and Technology, 15, 1-21, (2001).
1042. Zeiler, T., S. Kellermann, and H. Muenstedt, “Different surface treatments to improve the adhesion of polypropylene,” J. Adhesion Science and Technology, 14, 619-634, (2000).
1077. Wu, D.Y., W.S. Gutowski, S. Li, and H.J. Griesser, “Ammonia plasma treatment of polyolefins for adhesive bonding with a cyanoacrylate adhesive,” J. Adhesion Science and Technology, 9, 501-525, (1995).
1194. Banik, I., K.S. Kim, Y.I. Yun, D.H. Kim, C.M. Ryu, and C.E. Park, “Inhibition of aging in plasma-treated high-density polyethylene,” J. Adhesion Science and Technology, 16, 1155-1169, (2002).
1197. Canal, C., R. Molina, E. Bertran, and P. Erra, “Wettability, ageing and recovery process of plasma-treated polyamide 6,” J. Adhesion Science and Technology, 18, 1077-1089, (2004).
The wetting properties of polyamide 6 rods treated with radiofrequency (RF) low-temperature plasma (LTP) using three different non-polymerizing gases (air, nitrogen and water vapour) were determined using the Wilhelmy contact-angle technique. Information on the acidic or basic nature of the ionizable groups generated on the rod surface was obtained using contact-angle titration. The wettability obtained depends on the plasma gas used, and it tends to decrease with time elapsed after the treatment when the samples are kept in an air environment. However, the wettability can be recovered by immersion of the aged samples in water. The degree of recovery depends on the plasma gas used and the highest recovery was obtained with water vapour plasma treated samples. Both ageing and recovery behaviour can be attributed to the reorganisation of hydrophilic groups which tend to reversibly migrate or orient towards the bulk phase depending on the storage conditions, although other factors can also have influence.
1199. Cepeda-Jiminez, C.M., R. Torregrosa-Macia, and J.M. Martin-Martinez, “Surface modifications of EVA copolymers induced by low pressure RF plasmas from different gases and their relation to adhesion properties,” J. Adhesion Science and Technology, 17, 1145-1159, (2003).
1201. Chattopadhyay, S., R.N. Ghosh, T.K. Chaki, and A.K. Bhowmick, “Surface analysis and printability studies on electron beam-irradiated thermoplastic elastomeric films from LDPE and EVA blends,” J. Adhesion Science and Technology, 15, 303-320, (2001).
1204. Chibowski, E., A. Ontiveros-Ortega, and R. Perea-Carpio, “On the interpretation of contact angle hysteresis,” J. Adhesion Science and Technology, 16, 1367-1404, (2002).
1206. Della Volpe, C., and S. Siboni, “Acid-base surface free energies of solids and the definition of scales in the Good-van Oss-Chaudhury theory,” J. Adhesion Science and Technology, 14, 235-272, (2000) (also in Apparent and Microscopic Contact Angles, J. Drelich, J.S. Laskoski, and KL. Mittal, eds., p. 171-208, VSP, Jun 2000).
1207. Della Volpe, C., S. Siboni, D. Maniglio, M. Morra, C. Cassinelli, et al, “Recent theoretical and experimental advancements in the applications of the van Oss-Chaudhury-Good acid-base theory to the analysis of polymer surfaces, II: Some peculiar cases,” J. Adhesion Science and Technology, 17, 1425-1456, (2003).
1209. Dilsiz, N., “Plasma surface modification of carbon fibers: A review,” J. Adhesion Science and Technology, 14, 975-987, (2000).
1211. Drelich, J., J. Nalaskowski, A. Gosiewska, E. Beach, and J.D. Miller, “Long-range attractive forces and energy barriers in de-inking flotation: AFM studies of interactions between polyethylene and toner,” J. Adhesion Science and Technology, 14, 1829-1843, (2000).
1217. Inagaki, N., K. Narushima, and A. Yokoi, “Surface modification of PET films by a combination of vinylphthalimide deposition and Ar plasma irradiation,” J. Adhesion Science and Technology, 18, 1517-1528, (2004).
A new surface modification technique for PET films is proposed. This technique, called VPI modification technique, is a combination of two processes: The first step involves the deposition of vinylphthalimide (VPI) on the PET film surfaces, followed by Ar plasma irradiation of the VPI-covered film surfaces. The VPI modification technique led to large increases in the N/C atom ratio on the PET film surfaces. On the VPI-modified PET film surface, a new Nls peak containing two components due to amide groups as well as imide groups appeared. The Cls signal for the VPI-modified PET film surface also showed a new component due to ketone groups. These changes indicate that VPI reacted with the PET film surfaces to form nitrogen-containing groups. VPI modification made PET film surfaces hydrophilic. The VPI-modified film surfaces showed a decrease in water contact angle from 73 degrees to 48–56 degrees.
1218. Inagaki, N., K. Narushima, Y. Tsutsui, and Y. Ohyama, “Surface modification and degradation of poly(lactic acid) films by Ar-plasma,” J. Adhesion Science and Technology, 16, 1041-1054, (2002).
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