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ACCU DYNE TEST ™ Bibliography

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2667. Weiss, D.A., “Effective ink transfer,” Flexo, 41, 68-72, (Oct 2016).

2137. no author cited, “Reliable solutions - corona treatment from simple to sophisticated,” Flexo & Gravure International, 86-87, (Feb 2006).

1281. Schleising, E., “Corona discharge treatment,” FlexoTech, 13, 26, (1997).

80. Dick, F., “How surface tension affects flexographic printing,” in FTA Annual Forum, 1978, Flexographic Technical Association, 1978.

1164. Wolf, R.A., “Atmospheric plasma: a new surface treatment technology for promoting flexographic printing adhesions',” in 2005 FFTA Forum, Flexographic Technical Association, Mar 2005.

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

1491. Derjaguin, B.V., and S.M. Levi, Film Coating Theory, Focal Press, 1943.

1729. Miller, J.D., “Surface chemistry measurements for evaluating coatings formulations,” Franklin International, 2007.

1409. Meiners, S., J. Salge, E. Prinz, and F. Forster, “Surface modification of polymer materials by transient gas discharges at atmospheric pressure,” in 5th International Conference on Plasma Surface Engineering, Garmisch-Partenkirchen, Sep 1996.

1717. Grosse, W., “Process and device for Opto-Dynamic Surface Tension (or surface energy) measurement - ODSTM-1 - for running plastic films or other substrates,” Germany Patent Application DE 195.42.289 A 1, 2000.

2010. Lee, L.-H., “Molecular bonding and adhesion at polymer-metal interfaces,” in Adhesion International 1993, Sharpe, L.H., ed., 305-328, Gordon & Breach, 1993.

2011. Mathieson, I., D.M. Brewis, and I. Sutherland, “Pretreatments of fluoropolymers,” in Adhesion International 1993, Sharpe, L.H., ed., 339-346, Gordon & Breach, 1993.

2012. Baalmann, A., K.D. Vissing, E. Born, and A. Gross, “Surface treatment of polyetheretherketone (PEEK) composites by plasma activation,” in Adhesion International 1993, Sharpe, L.H., ed., 347-356, Gordon & Breach, 1993.

2013. Sutherland, I., R.P. Popat, D.M. Brewis, and R. Calder, “Corona discharge treatment of polyolefins,” in Adhesion International 1993, Sharpe, L.H., ed., 369-380, Gordon and Breach, 1993 (also in J. Adhesion, V. 46, p. 79-88, Sep 1994).

2329. Wu, S., “Polar and nonpolar interactions in adhesion,” in Recent Advances in Adhesion, Lee, L.-H., ed., 45-63, Gordon and Breach, 1973.

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.

1084. Lee, L.-H., “Adhesion and surface-hydrogen-bond components for polymers and biomaterials.,” in Fundamentals of Adhesion and Interfaces, DeMejo, L.P., D.S. Rimai, and L.H. Sharpe, eds., 1-18, Gordon and Breach Science Publ., Jan 2000.

1085. Cheng, F., S.G. Hong, and C.A. Ho, “The adhesion properties of an ozone modified thermoplastic olefin elastomer,” in Fundamentals of Adhesion and Interfaces, DeMejo, L.P., D.S. Rimai, and L.H. Sharpe, eds., 123-138, Gordon and Breach Science Publ., Dec 1999.

975. Matousek, P., G. Kreuger, and O.-D. Hennemann, “Adhesion tests with corona-pretreated plastics,” Gummi Fasern Kunststoffe, 49, 630-631, (1996).

52. Chan, C.-M., Polymer Surface Modification and Characterization, Hanser Gardner, Jan 1994.

389. Wool, R.P., Polymer Interfaces: Structure and Strength, Hanser Gardner, Sep 1994.

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

2213. Wolf, R.A., Plastic Surface Modification: Surface Treatment and Adhesion, Hanser Publications, Feb 2010.

1192. Akishev, Y.S., M.E. Grushin, A.E. Monich, A.P. Napartovich, and N.I. Trushkin, “One-atmosphere argon dielectric-barrier corona discharge as an effective source of cold plasma for the treatment of polymer films and fabrics,” High Energy Chemistry, 37, 286-291, (Sep 2003).

1357. Alemskaya, O., V. Lelevkin, A. Tokarev, and V. Yudanov, “Synthesis of ozone in a surface barrier discharge with a plasma electrode,” High Energy Chemistry, 39, 263-267, (Jul 2005).

The synthesis of ozone from oxygen in a cylindrical ozonizer operating under surface discharge conditions with a plasma electrode was studied. The conditions of ozone synthesis were optimized. The dependence of ozone concentration and specific energy consumption on gas pressure in the plasma electrode and on distance between the coils of a corona electrode was determined. The results were compared with data obtained with the use of classical surface barrier discharge.

1735. Abdrashitov, E.F., and A.N. Ponomarev, “Plasma modification of elastomers,” High Energy Chemistry, 37, 279-285, (2003).

2322. Goldshtein, D., “Modification of the surface of polytetrafluoroethylene in a flow discharge plasma in vapors of various organic compounds,” High Energy Chemistry, 25, 303-306, (1991).

2323. Gilman, A., “Effect of treatment conditions in a glow discharge on the wettability of PTFE,” High Energy Chemistry, 24, 64-66, (1990).

1072. Pritykin, L.M., T.V. Lukienko, and A.N. Lyubchenko, “Influence of surface and cohesion parameters of adhesives on the metal adhesive joint strength (alphacyanoacrylates),” in Adhesion '99 Conference Proceedings, 363-368, ICM Communications, Sep 1999.

2554. Penache, C., C. Gessner, T. Betker, V. Bartels, A. Hollaender, and C.-P. Klages, “Plasma printing: Patterned surface functionalisation and coating at atmospheric pressure,” IEE Proceedings: Nanobiotechnology, 151, 139-144, (Aug 2004).

A new plasma-based micropatterning technique, here referred to as plasma printing, combines the well known advantages given by the nonequilibrium character of a dielectric barrier discharge (DBD) and its operation inside small gas volumes with dimension between tens and hundreds of micrometres. The discharge is run at atmospheric pressure and can be easily implemented for patterned surface treatment with applications in biotechnology and microtechnology. In this work the local modification of dielectric substrates, e.g. polymeric films, is addressed with respect to coating and chemical functionalisation, immobilisation of biomolecules and area-selective electroless plating.

2217. Masuda, S., “Surface treatment of plastic material by pulse corona induced plasma chemical process - PPCP,” in Proceedings of the IEEE Industry Applications Society Annual Meeting, Vol. 1, 703, IEEE, 1991.

2918. Sherman, P.B., “Corona discharge treatment,” in Conference Record of the 1993 IEEE Industry Applications Conference, 1669-1685, IEEE, Aug 1993.

2958. Kumara, S., B. Ma, Y.V. Seryuk, S.M. Gubanski, et al, “Surface charge decay on HTV silicone rubber: effect of material treatment by corona discharge,” IEEE Transactions on Dielectrics and Electrical Insulation, 19, 2189-2195, (Dec 2012).

Surface charge decay on thick flat samples of high temperature vulcanized silicone rubber is studied prior and after ac and dc corona pre-treatments. It is found that the charge decay rate on the material exposed to ac corona becomes much higher and sensitive to moisture content in the surrounding air. These features are associated with an increased surface conductivity and formation of a silica-like layer on the polymeric surface, both resulting from ac corona treatment. In contrast, characteristics of the charge decay on the material exposed to dc corona are found to be similar to that measured on untreated samples.

304. Rosenthal, L.A., and D.A. Davis, “Electrical characterization of a corona discharge for surface treatment,” IEEE Transactions on Industry Applications, 1A-11, 328-334, (May 1975).

1846. Chang, J.-S., P.A. Lawless, and T. Yamamoto, “Corona discharge processes,” IEEE Transactions on Plasma Science, 19, 1152-1166, (Dec 1991).

2732. Gonzalez, E. II, M.D. Barankin, P.C. Guschl, and R.F. Hicks, “Ring opening of aromatic polymers by remote atmospheric-pressure plasma,” IEEE Transactions on Plasma Science, 37, 823-831, (Jun 2009).

A low-temperature, atmospheric pressure oxygen and helium plasma was used to treat the surfaces of polyetheretherketone, polyphenylsulfone, polyethersulfone, and polysulfone. These aromatic polymers were exposed to the afterglow of the plasma, which contained oxygen atoms, and to a lesser extent metastable oxygen (^1δg O2) and ozone. After less than 2.5 seconds treatment, the polymers were converted from a hydrophobic state with a water contact angle of 85±5 to a hydrophilic state with a water contact angle of 13±5 . It was found that plasma activation increased the bond strength to adhesives by as much as 4 times. X-ray photoelectron spectroscopy revealed that between 7% and 27% of the aromatic carbon atoms on the polymer surfaces was oxidized and converted into aldehyde and carboxylic acid groups. Analysis of polyethersulfone by internal reflection infrared spectroscopy showed that a fraction of the aromatic carbon atoms were transformed into C=C double bonds, ketones, and carboxylic acids after plasma exposure. It was concluded that the oxygen atoms generated by the atmospheric pressure plasma insert into the double bonds on the aromatic rings, forming a 3-member epoxy ring, which subsequently undergoes ring opening and oxidation to yield an aldehyde and a carboxylic acid group.

2623. no author cited, “ISO 15989: Plastics - film and sheeting - measurement of water-contact angle of corona-treated films,” ISO, 2009.

1688. Kanda, N., M. Kogoma, H. Jinno, H. Ychiyama, and S. Okazaki, “Atmospheric pressure glow plasma discharge and its application to surface treatment and film deposition,” in Proceedings of the 10th International Symposium on Plasma Chemistry, Vol. 3, 3.2.201-204, ISPC, 1991.

2977. Novak, I., A. Popelka, J. Chodak, and J. Sedliacek, “Study of adhesion and surface properties of modified polypropylene,” in Polypropylene, 125-160, InTech, 2012.

1071. De Touni, E., “When rubber has a heart of metal,” Industria Della Gomma, 44, 37-42, (Feb 2004).

 

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