ACCU DYNE TEST ™ Bibliography
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2542. Katnani, A.D., A. Knoll, and M.A. Mycek, “Effects of environment and heat treatment on an oxygen plasma-treated polyimide surface and its adhesion to a chromium overcoat,” J. Adhesion Science and Technology, 3, 441-453, (1989).
2784. Kato, Y., F.M. Fowkes, and J.W. Vanderhoff, “Surface energetics of the lithographic printing process,” Industrial & Engineering Chemistry Product Research & Development, 21, 441-450, (1982).
188. Katoh, K., “Change of polypropylene film surface by chromic acid mixture treatment,” J. Applied Polymer Science, 19, 1593-1599, (1975).
1062. Katoh, K., “Contact angle and surface tension measurement,” in Surface and Interfacial Tension: Measurement, Theory, and Applications, Hartland, S., ed., 375-424, Marcel Dekker, 2004.
189. Katoh, K., H. Fujita, and H. Sasaki, “Macroscopic wetting behavior and a method for measuring contact angles,” J. Fluids Engineering, 112, 289-295, (1990).
2634. Katz, S., “With film substrates becoming more popular, corona treatment is increasingly more important,” Label & Narrow Web, 20, 70-72, (Oct 2015).
2883. Katz, S., “Corona treatment,” Label & Narrow Web, 27, 55-57, (Mar 2022).
2444. Kaverman, J., “Causes of adhesion problems #3: Failure to pre-treat,” http://plasticsdecoratingblog.com/?p=71, Aug 2011.
2605. Kaverman, J., “TPE, TPO, TPU present challenges for pad printing,” http://plasticsdecorating.com/?p=498, Feb 2015.
2631. Kaverman, J., “Methods and materials for difficult pad printing operations,” Plastics Decorating, 14-16, (Jan 2016).
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).
681. Kawano, S., et al, “Water base adhesion promoter for polypropylene and method for coating to polypropylene materials using the promoter,” U.S. Patent 6447844, Sep 2002.
1919. Kawasaki, K., “Study of wettability of polymers by sliding of water drop,” J. Colloid Science, 15, 402-407, (Oct 1960).
190. Kawese, T., M. Uchita, T. Fujii, and M. Minagawa, “Acrylic acid grafted polyester surface: surface free energies, FT-IR (ATR), and ESCA characterization,” Textile Research J., 61, 146-152, (1991).
1459. Ke-Chang, G., and Z. Shao-Hua, “Plasma treatment on polytetrafluoroethylene and the adhesion property,” in Antec '88, 1555-1558, Society of Plastics Engineers, Apr 1988.
2383. Kelly, P.T., “Corona-discharge treated release films,” U.S. Patent 4978436, Dec 1990.
2580. Kemppi, A., “Studies on the adhesion between paper and low density polyethylene (PhD thesis),” Abo Akademi, 1997.
897. Kendall, K., “Energy analysis of adhesion,” in Adhesion Science and Engineering: Vol. 1 - The Mechanics of Adhesion; Vol. 2 - Surfaces, Chemistry and Applications, Dillard, D.A., and A.V. Pocius, eds., 77-110(V1), Elsevier, Oct 2002.
502. Kennedy, B.S., and R. Burley, “Dynamic fluid interface displacement and prediction of air entrainment,” J. Colloid and Interface Science, 62, 48-62, (1977).
191. Kenny, J., “Corona treating,” Label & Narrow Web Industry, 3, 30-35, (Nov 1998).
1588. Kersten, H., H. Deutsch, H. Steffan, G.M.W. Kroesen, and R. Hippler, “The energy balance at substrate surfaces during plasma processing,” Vacuum, 63, 385-431, (2001).
1909. Khairallah, Y., F. Arefi, J. Amouroux, D. Leonard, and P. Bertrand, “Surface fluorination of polyethylene films by different glow discharges. Effects of frequency and electrode configuration,” J. Adhesion Science and Technology, 8, 363-381, (1994) (also in Plasma Surface Modification of Polymers: Relevance to Adhesion, M. Strobel, C.S. Lyons, and K.L. Mittal, eds., p. 147-166, VSP, Oct 1994).
1551. Kiddell, P., “Understanding and using pad printing inks,” http://www.padprint1.com/Articles_UnderstandingInks.cfm, 0.
2830. Kiel, A., “Corona vs. plasma treatment,” https://www.3dtllc.com/corona-vs-plasma-treatment/, Aug 2016.
2832. Kiel, A., “Corona treatment systems - overcoming the effects of heat and humidity,” https://www.3dtllc.com/corona-treatment-systems-overcoming-effects-heat-humidity/, Jul 2017.
2833. Kiel, A., “Finding the sweet spot and the right corona treater for polypropylene,” https://www.3dtllc.com/finding-the-sweet-spot-when-corona-treating-polypropylene/, Mar 2020.
192. Kigle-Boeckler, G., “Surface tension measurement (ring method) and characterization of coating materials,” in Surface Phenomena and Additives in Water-Based Coatings and Printing Technology, Sharma, M.H., ed., 269-282, Plenum Press, Feb 1992.
2770. Kilpadi, D.V., and J.E. Lemons, “Surface energy characterization of unalloyed titanium implants,” J. Biomedical Materials Research, 28, 1419-1425, (Dec 1994).
1131. Kim, B.G., E.-H. Son, S.-E. Kim, and J.-C. Lee, “Surface properties of the novel fluoropolymer having extremely low surface energy,” PMSE Preprints, 93, 610-611, (2005).
1221. Kim, B.K., K.S. Kim, C.E. Park, and C.M. Ryu, “Improvement of wettability and reduction of aging effect by plasma treatment of low-density polyethylene with argon and oxygen mixtures,” J. Adhesion Science and Technology, 16, 509-521, (2002).
1222. Kim, B.K., K.S. Kim, K. Cho, and C.E. Park, “Retardaton of the surface rearrangement of O2 plasma-treated LDPE by a two-step temperature control,” J. Adhesion Science and Technology, 15, 1805-1816, (2001).
2427. Kim, C.Y., G. Suranyi, and D.A.I. Goring, “Corona induced bonding of synthetic polymers to cellulose,” J. Polymer Science Part C: Polymer Symposia, 30, 533-542, (1970).
194. Kim, C.Y., J. Evans, and D.A.I. Goring, “Corona-induced autoadhesion of polyethylene,” J. Applied Polymer Science, 15, 1365-1375, (1971).
193. Kim, C.Y., and D.A.I. Goring, “Surface morphology of polyethylene after treatment in a corona discharge,” J. Applied Polymer Science, 15, 1357-1364, (1971).
2543. Kim, J., M.K. Chaudhury, and M.J. Owen, “Hydrophobic recovery of polydimethylsiloxane elastomer exposed to partial electrical discharge,” J. Colloid and Interface Science, 226, 231-236, (Jun 2000).
2330. Kim, J.-S., Y.-K. Kim, and K.-H. Lee, “Effects of atmospheric plasma treatment on the interfacial characteristics of ethylene-vinyl acetate/polyurethane composites,” J. Colloid and Interface Science, 271, 187-191, (Mar 2004).
The surface characteristics of ethylene-vinyl acetate (EVA) were modified by argon, air, and oxygen plasma at atmospheric pressure. The surface energies of the EVA were evaluated by contact angles according to a sessile-drop method and adhesion energy (G(IC)) was estimated by a 180 degrees peel test with polyurethane (PU). After the plasma treatments, the surface free energies (or specific polar component) of the EVA increased about five times compared to that of virgin EVA. The adhesion between the EVA and the PU is significantly improved by the plasma treatment. Especially, Ar/air/O(2) plasma treatment increases G(IC) of EVA/PU up to about 600% compared to that of the sample using virgin EVA.
2055. Kim, J.H., D.S. Shin, M.H. Han, O.W. Kwon, H.K. Lee, et al, “Surface free energy analysis of poly(vinyl alcohol) films having various molecular parameters,” J. Applied Polymer Science, 105, 424-428, (Jul 2007).
The molecular parameters of poly(vinyl alcohol) have enormous effects on its physical and chemical properties. Therefore, the surface characteristics of poly(vinyl alcohol) films are also determined by the molecular parameters. In this study, the dependence of the surface free energy on the molecular weight, degree of saponification, and stereoregularity of poly(vinyl alcohol) films has been evaluated with contact-angle measurements. The surface free energy of poly(vinyl alcohol) films increases with decreases in the syndiotactic dyad content, molecular weight, and degree of saponification. The polar component of the surface energy is not affected by the deviation of the molecular weight and degree of saponification very much. However, it decreases with increases in the syndiotactic dyad content and ranges from 11.64 to 4.35 dyn/cm.
© 2007 Wiley Periodicals, Inc. J Appl Polym Sci 2007 https://onlinelibrary.wiley.com/doi/abs/10.1002/app.26010
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).
2768. Kim, K.-J., S.-B. Lee, and N.W. Han, “Effects of the degree of crosslinking on properties of poly(vinyl acetate) membranes,” Polymer J., 25, 1295-1302, (1993).
2076. Kim, K.S., K.H. Lee, K. Cho, and C.E. Park, “Surface modification of polysulfone ultrafiltration membrane by oxygen plasma treatment,” J. Membrane Science, 199, 135-145, (Apr 2002).
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