ACCU DYNE TEST ™ Bibliography
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2902. Gao, L., and T.J. McCarthy, “Contact angle hysteresis explained,” Langmuir, 22, 6234-6237, (Jun 2006).
A view of contact angle hysteresis from the perspectives of the three-phase contact line and of the kinetics of contact line motion is given. Arguments are made that advancing and receding are discrete events that have different activation energies. That hysteresis can be quantified as an activation energy by the changes in interfacial area is argued. That this is an appropriate way of viewing hysteresis is demonstrated with examples.
2008. Gao, S., and Y. Zeng, “Surface modification of ultrahigh molecular weight polyethylene fibers by plasma treatment I: Improving surface adhesion,” J. Applied Polymer Science, 47, 2065-2071, (Mar 1993).
117. Garbassi, F., E. Occhiello, F. Polato, and A. Brown, “Surface effect of flame treatments on polypropylene (Part 2),” J. Materials Science, 22, 1450-1456, (1987).
116. Garbassi, F., E. Occhiello, and F. Polato, “Surface effect of flame treatments on polypropylene (Part 1),” J. Materials Science, 22, 207-212, (1987).
1268. Garbassi, F., M. Morra, E. Occhiello, L. Barino, and R. Scordamaglia, “Dynamics of macromolecules: A challenge for surface analysis,” Surface and Interface Analysis, 14, 585-589, (Oct 1989).
118. Garbassi, F., M. Morra, and E. Occhiello, Polymer Surfaces: From Physics to Technology, John Wiley & Sons, Nov 1997.
119. Garbassi, F., and E. Occhiello, “Surface modification,” in Concise Polymeric Materials Encyclopedia, Salamone, J.C., ed., 1542-1543, CRC Press, Aug 1998.
1861. Garbassi, F., and E. Occhiello, “Surface modification of PAN fibers by plasma polymerization,” J. Adhesion Science and Technology, 13, 65-78, (1999).
120. Gardon, J.L., “Relationship between cohesive energy densities of polymers and Zisman's critical surface tensions (notes),” J. Physical Chemistry, 67, 1935-1936, (1963).
121. Gardon, J.L., “Critical review of concepts common to cohesive energy density, surface tension, tensile strength, heat of mixing, interfacial tension, and butt joint strength,” J. Colloid and Interface Science, 59, 582-596, (1977).
462. Gardon, J.L., “The influence of polarity upon the solubility parameter concept,” J. Paint Technology, 38, 43, (1966).
2224. Gatenby, A., “CSC Scientific blog: Surface tension by DuNouy rings or Wilhelmy plates - which to choose?,” http://www.cscscientific.com/csc-scientific-blog/bid/45263/, Aug 2010.
2226. Gatenby, A., “CSC Scientific blog: Surface tension and interfacial tension,” http://www.cscscientific.com/csc-cientific-blog/bid/25530/, Nov 2008.
2227. Gatenby, A., “CSC Scientific blog: Having trouble performing a DuNouy ring test in thick samples?,” http://www.cscscientific.com/csc-cientific-blog/bid/49737/, Nov 2010.
2228. Gatenby, A., “CSC Scientific blog: How does surface tension relate to viscosity?,” http://www.cscscientific.com/csc-cientific-blog/52996/, Jan 2011.
2259. Gatenby, A., “CSC Scientific blog: Why calibrate a CSC DuNouy tensiometer?,” http://www.cscscientific.com/csc-cientific-blog/bid/66987/, Sep 2011.
2298. Gatenby, A., “CSC Scientific blog: Which type of tensiometer do I need?,” http://www.cscscientific.com/csc-cientific-blog/bid/72800/, Dec 2011.
2475. Gatenby, A., “CSC Scientific blog: What are the primary conditions affecting surface tension?,” http://cscscientific.com/csc-cientific-blog/bid/85407/, Sep 2013.
2592. Gatenby, A., “CSC Scientific blog: How are consistency, surface tension, and viscosity different?,” http://www.cscscientific.com/csc-cientific-blog/bid/102345/how-are..., Feb 2014.
2652. Gatenby, A., “CSC Scientific blog: Should you move to 'actual' surface tension?,” http://www.cscscientific.com/csc-cientific-blog/should-you-convert-..., Sep 2016.
2791. Gatenby, A., “Surface tension - rings, bubbles, drops, and plates,” https://www.cscscientific.com/csc-cientific-blog/surface-tension..., Feb 2019.
2915. Gatenby, A., “CSC Scientific blog: A beginner's guide to surface tension, surfactants and micelles,” https://www.cscscientific.com/csc-scientific-blog/a-beginners-guide..., Oct 2022.
1889. Gatenholm, P., C. Bonnerup, and E. Wallstrom, “Wetting and adhesion of water-borne printing inks on surface-modified polyolefins,” J. Adhesion Science and Technology, 4, 817-827, (1990).
1767. Gavrilov, N.V., V.N. Mizgulin, R. Stinnett, and A.V. Kondyurin, “Modification of polymer films of PE, PTFE, PC, PI by pulse ion beams,” Khimicheskaya Fizika i Mesoskopiya, 1, 39-47, (1999).
463. Gaydos, J., E. Moy, and A.W. Neumann, “Reply to 'On the existence of an equation of state for interfacial free energies' (letter),” Langmuir, 6, 888-892, (1990).
1597. Gaydos, J., and A.W. Neumann, “The dependence of contact angles on drop size and line tension,” J. Colloid and Interface Science, 76, 120+, (1987).
2411. Geibart, D., “Method of surface preparation using plasma in air,” U.S. Patent 6476342, Nov 2002.
122. Geitner, W., “Flame treatment effect on OPP,” AIMCAL News, 14, (Aug 2001).
2722. Geng, X., Q. Qiang, J. Zhao, J. Yang, and Z. Wang, “The effect of TiO2 morphology on the surface modification of poly(ethylene terephthalate) for electroless plating,” J. Adhesion Science and Technology, 29, 705-715, (2015).
In this study, a surface modification of the poly (ethylene terephthalate) (PET) film using TiO2 photocatalytic treatment was investigated. In order to enhance the adhesion strength between the PET film and the electroless copper film, the effects of TiO2 crystal forms, TiO2 particle sizes, and TiO2 content, as well as treatment condition, upon the surface contact angle, surface characterization, and adhesion strength were investigated. Anatase TiO2 with a particle size of 5 nm had a high catalytic activity and dispersibility in aqueous solution. After the optimal photocatalytic treatment, the surface contact angle of the PET film decreased from 84.4° to 19.8°, and the surface roughness of the PET film increased from 36 to 117 nm. The adhesion strength between the PET film and the electroless copper film reached 0.89 KN m−1. X-ray photoelectron spectroscopy analyses indicated the carbonyl group was formed on the PET surface after photocatalytic treatment, and the surface hydrophilicity was improved. Consequently, TiO2 photocatalytic treatment is an environmentally friendly and effective method for the surface modification of the PET film.
1447. Gengenbach, T.R., X. Xie, R.C. Chatelier, and H.J. Griesser, “Evolution of the surface composition and topography of perfluorinated polymers following ammonia-plasma treatment,” J. Adhesion Science and Technology, 8, 305-328, (1994) (also in Plasma Surface Modification of Polymers: Relevance to Adhesion, M. Strobel, C.S. Lyons, and K.L. Mittal, eds., p. 123-146, VSP, Oct 1994).
123. Gengler, P., “The role of dielectrics in corona treating,” Converting, 8, 62-66, (Jun 1990).
124. Gengler, P., “Corona treating equipment for the flexographic printer,” Flexo, 18, 36-38, (Mar 1993).
2331. Gent, A.N., and J. Schultz, “Effect of wetting liquids on the strength of adhesion of visoelastic materials,” in Recent Advances in Adhesion, Lee, L.-H., ed., 253-268, Gordon and Breach, 1973.
894. Genuario, L., “Corona treatment,” Label & Narrow Web Industry, 7, 58-64, (Oct 2002).
1109. Genuario, L., “Surface treatment,” Label and Narrow Web, 10, 50-56, (Jan 2005).
125. George, G.A., “Surface modification and analysis of ultra-high modulus polyethylene fibres for composites,” in Polymer Surfaces and Interfaces II, Feast, W.J., H.S. Munro, and R.W. Richards, eds., 161-202, John Wiley & Sons, Apr 1993.
826. Gerenser, L.J., “XPS studies of in situ plasma-modified polymer surfaces,” in Plasma Surface Modification of Polymers: Relevance to Adhesion, Strobel, M., C.S. Lyons, and K.L. Mittal, eds., 43-64, VSP, Oct 1994.
1744. Gerenser, L.J., “X-Ray photoemission study of plasma modified polyethylene surfaces,” J. Adhesion Science and Technology, 1, 303-318, (1987).
126. Gerenser, L.J., J.F. Elman, M.G. Mason, and J.M. Pochan, “ESCA studies of corona-discharge-treated polyethylene surfaces by use of gas-phase derivatization,” Polymer, 26, 1162-1166, (1985).
127. Gerenser, L.J., J.M. Pochan, J.F. Elman, and M.G. Mason, “Effect of corona discharge treatment of poly(ethylene terephthalate) on the adsorption characteristics of the fluorosurfactant Zonyl FSC as studied via ESCA and surface energy measurements,” Langmuir, 2, 765-770, (1987).
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