ACCU DYNE TEST ™ Bibliography

Provided as an information service by Diversified Enterprises.

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).

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).

1223. Koh, S.K., J.S. Cho, K.H. Kim, S. Han, and Y.W. Beag, “Altering a polymer surface chemical structure by an ion-assisted reaction,” J. Adhesion Science and Technology, 16, 129-142, (2002).

1227. Landete-Ruiz, M.D., J.A. Martinez-Diez, M.A. Rodriguez-Perez, A. Miguel, et al, “Improved adhesion of low-density polyethylene/EVA foams using different surface treatments,” J. Adhesion Science and Technology, 16, 1073-1101, (2002).

1233. McCafferty, E., “Acid-base effects in polymer adhesion at metal surfaces,” J. Adhesion Science and Technology, 16, 239-255, (2002).

1248. Qiu, Y., C. Zhang, Y.J. Hwang, B.L. Bures, and M.G. McCord, “The effect of atmospheric pressure helium plasma treatment on the surface and mechanical properties of ultrahigh-modulus polyethylene fibers,” J. Adhesion Science and Technology, 16, 99-107, (2002).

1249. Qiu, Y., Y.J. Hwang, C. Zhang, B.L. Bures, and M.G. McCord, “Atmospheric pressure helium + oxygen plasma treatment of ultrahigh modulus polyethylene fibers,” J. Adhesion Science and Technology, 16, 449-457, (2002).

1250. Radelczuk, H., L. Holysz, and E. Chibowski, “Comparison of the Lifschitz-van der Waals/acid-base and contact angle hysteresis approaches for determination of solid surface free energy,” J. Adhesion Science and Technology, 16, 1547-1568, (2002).

1260. van Oss, C.J., “Use of the combined Lifschitz-van der Waals and Lewis acid-base approaches in determining the apolar and polar contributions to surface and interfacial tensions and free energies,” J. Adhesion Science and Technology, 16, 669-677, (2002).

1358. Allen, N.L., and A.A.R. Hashem, “The role of negative ions in the propagation of discharges across insulating surfaces,” J. Physics D: Applied Physics, 35, 2551-2557, (2002).

1417. Yializis, A., W. Decker, M.G. Mikhael, and S.A. Pirzada, “Electrode for glow-discharge, atmospheric-pressure plasma treatment,” U.S. Patent 6441553, 2002.

1477. Della Volpe, C., and S. Siboni, “Acid-base behaviour of (polymer) surfaces: Theory,” in Encyclopedia of Surface and Colloid Science, Hubbard, A., ed., Marcel Dekker, 2002.

1478. Della Volpe, C., S. Siboni, and M. Morra, “Comments on some recent papers on interfacial tension and contact angles,” Langmuir, 18, 1441-1444, (2002).

1479. Chehimi, M.M., E. Cabet-Deliry, A. Azioune, and M.L. Abel, “Characterization of acid-base properties of polymers and other materials: Relevance to adhesion science and technology,” Macromolecular Symposia, 178, 169-181, (2002).

1541. Prentice, P., “Corona discharge,” http://www.polytechconsultants.com/corona.htm, 2002.

1576. Greger, R., “Pre-treatment of plastics with low-pressure plasma prior to flocking,” Flock, 7, 107, (2002).

1584. von Arnim, V., T. Stegmaier, D. Praschak, T. Bahners, A. Lunk, et al, “Continuous plasma treatment of textiles under atmospheric pressure,” in Proceedings of the 29th Aachen Textile Conference, DWI an der RWTH Aachen University, 2002.

1636. O'Hare, L.-A., J.A. Smith, S.R. Leadley, B. Parbhoo, A.J. Goodwin, J.F. Watts, “Surface physico-chemistry of corona-discharge-treated poly(ethylene terephthalate) film,” Surface and Interface Analysis, 33, 617, (2002).

1669. Simor, M., J. Rahel, D. Kovacik, A. Zahoranova, M. Mazur, and M. Cernak, “Atmospheric-pressure plasma treatment of nonwovens using surface dielectric barrier discharges,” in 12th Annual International TANDEC Nonwovens Conference Proceedings, TANDEC, 2002.

1684. Gulejova, B., M. Simor, J. Rahel, D. Kovacik, and M. Cernak, “Hydrophilization of polyester nonwoven fabrics by atmospheric nitrogen plasma treatment,” Czech J. Physics, Supplement D, 52, 861-865, (2002).

1737. Efimenko, K., W.E. Wallace, and J. Genzer, “Surface modification of Sylgard 184 poly(dimethyl siloxane) networks by ultraviolet and ultraviolet/ozone treatment,” J. Colloid and Interface Science, 254, 306-315, (2002).

1745. Grace, J.M., L.J. Gerenser, K.D. Sieber, et al, “High-efficiency plasma treatment of polyolefins,” U.S. Patent 6399159, 2002.

2097. van der Leeden, M.C., and G. Frens, “Surface properties of plastic materials in relation to their adhering performance,” Advanced Engineering Materials, 4, 280-289, (2002).

2511. Dreux, F., S. Marais, F. Poncin-Epaillard, M. Metayer, and M. Labbe, “Surface modification by low-pressure plasma of polyamide 12 (PA12): Improvement of the water barrier properties,” Langmuir, 18, 10411-10420, (2002).

2574. Guimond, S., I. Radu, G. Czeremuszkin, and M.R. Wertheimer, “Modification of polyolefins in nitrogen atmospheric pressure glow discharges,” in Proceedings of the 8th International Symposium on High Pressure Low Temperature Plasma Chemistry, 400-404, Puhajarve, Estonia, 2002.

2991. Park, S.-J., K.-S. Cho, and S.-H. Kim, “Surface and adhesion characteristics of polyimide film treated by corona discharge,” Korean Chemical Engineering Research, 40, 613-617, (2002).

240. Millward, J., “Surface treating lab report,” Package Printing, 49, 24-28, (Jan 2002).

260. Nolan, M.D., “Web treatment - going solventless,” Flexible Packaging, 4, 27-30, (Jan 2002).

1391. Podhajny, R.M., “Dealing with ink adhesion on high-slip films,” Paper Film & Foil Converter, 76, (Jan 2002).

2053. Sakhalkar, S.S., K.B. Walters, D.E. Hirt, N.R. Miranda, and W.P. Roberts, “Surface characteristics of LLDPE film containing glycerol monostearate,” J. Plastic Film and Sheeting, 18, 33-43, (Jan 2002).

2099. Shenton, M.J., G.C. Stevens, N.P. Wright, and X. Duan, “Chemical-surface modification of polymers using atmospheric pressure nonequilibrium plasmas and comparisons with vacuum plasmas,” J. Polymer Science Part A: Polymer Chemistry, 40, 95-109, (Jan 2002).

344. Smith, R.E., “Substrate surface energy testing,” Diversified Enterprises, Feb 2002.

1435. Park, Y.W., S. Tasaka, and N. Inagaki, “Surface modification of tetrafluoroethylene-hexafluoropropylene (FEP) copolymer by remote hydrogen, nitrogen, oxygen and argon plasmas,” J. Applied Polymer Science, 83, 1258-1267, (Feb 2002).

2019. Carrino, L., G. Moroni, and W. Polini, “Cold plasma treatment of polypropylene surface: A study on wettability and adhesion,” J. Materials Processing Technology, 121, 373-382, (Feb 2002).

2188. Koltzenburg, T., “Ozone generation: Sherman Treaters/Pillar give the goods,” http://pffc-online.com/news/paper, Feb 2002.

2923. Carrino, L., G. Moroni, and W. Polini, “Cold plasma treatment of polypropylene surface: a study on wettability and adhesion,” J. Materials Processing Technology, 121, 373-382, (Feb 2002).

1214. Guimond, S., I. Radu, G. Czeremuszkin, D.J. Carlsson, and M.R. Wertheimer, “Biaxially oriented polypropylene (BOPP) surface modification by nitrogen atmospheric pressure glow discharge (APGD) and by air corona,” Plasmas and Polymers, 7, 71-88, (Mar 2002).

1372. Guthrie, J.T., “Pretreatments and their effect on the adhesion of coatings,” Surface Coatings Intl. B: Coatings Transactions, 85, 27-33, (Mar 2002).

2063. Poncin-Epaillard, F., and M. Aouinti, “Characterization of CO2 plasma and interactions with polypropylene film,” Plasmas and Polymers, 7, 1-17, (Mar 2002).

821. Pocius, A.V., Adhesion and Adhesives Technology: An Introduction, 2nd Ed., Hanser Gardner, Apr 2002.

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