ACCU DYNE TEST ™ Bibliography
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1139. Briggs, D., “Corona discharge treatment,” in Handbook of Adhesion, 2nd Ed., Packham, D.E., ed., 89-90, John Wiley & Sons, Jul 2005.
1143. Briggs, D., “Hydrogen bonding,” in Handbook of Adhesion, 2nd Ed., Packham, D.E., ed., 230-231, John Wiley & Sons, Jul 2005.
1145. Briggs, D., “Plasma treatment,” in Handbook of Adhesion, 2nd Ed., Packham, D.E., ed., 325-326, John Wiley & Sons, Jul 2005.
1345. Briggs, D., “Surface treatments for polyolefins,” in Surface Analysis and Pretreatment of Plastics and Metals, Brewis, D.M., ed., 199-226, Applied Science, 1982.
1509. Briggs, D., “Chemical analysis of polymer surfaces,” in Surface Analysis and Pretreatment of Plastics and Metals, Brewis, D.M., ed., 73-94, Applied Science, Feb 1982.
40. Briggs, D., D.G. Rance, C.R. Kendall, and A.R. Blythe, “Surface modification of poly(ethylene terephthalate) by electrical discharge treatment,” Polymer, 21, 895-900, (1980).
1274. Briggs, D., D.M. Brewis, R.H. Dahm, and I.W. Fletcher, “Analysis of the surface chemistry of oxidized polyethylene: Comparison of XPS and ToF-SIMS,” Surface and Interface Analysis, 35, 156-167, (Feb 2003).
427. Briggs, D., D.M. Brewis, and M.B. Konieczko, “X-ray photoelectron spectroscopy studies of polymer surfaces, Part III. Flame treatment of polyethylene,” J. Materials Science, 14, 1344-1348, (1979).
41. Briggs, D., D.R. Kendall, A.R. Blythe, and A.B. Wootton, “Electrical discharge treatment of polypropylene film,” Polymer, 24, 47-52, (1983).
2037. Briggs, D., H. Chan, M.J. Hearn, D.I. McBriar, and H.S. Munro, “The contact angle of poly(methyl methacrylate) cast against glass,” Langmuir, 6, 420-424, (Feb 1990).
39. Briggs, D., and C.R. Kendall, “Chemical basis of adhesion to electrical discharge treated polyethylene,” Polymer, 20, 1053-1055, (1979).
994. Briggs, D., and C.R. Kendall, “Derivatisation of discharge-treated LDPE: An extension of XPS analysis and a probe of specific interactions in adhesion,” Intl. J. Adhesion and Adhesives, 2, 13-17, (Jan 1982).
429. Briggs, D., and M.P. Seah, Practical Surface Analysis: By Auger and X-Ray Photoelectron Spectroscopy, John Wiley & Sons, 1983.
2867. Bright, K., and B.A.W. Simmons, “Testing the level of pretreatment of polyethylene film using critical surface tension measurements,” European Polymer J., 3, 219-222, (May 1967).
2467. Brodine, D., “Surface treatment is a challenge for decorators,” Plastics Decorating, 29-30, (Jul 2013).
2593. Brodine, D., “Surface treatment is a challenge for decorators,” http://www.plasticsdecorating.com/stories/081613/surface-treatment..., Aug 2013.
1925. Brown, H.R., “The adhesion of polymers: Relations between properties of polymer chains and interface toughness,” J. Adhesion, 82, 1013-1032, (Oct 2006).
A review is presented of the adhesion between polymers with particular emphasis on the processes that occur during failure at the level of polymer chains and how these processes relate to the macroscopic interface toughness. The same processes at the chain level, pull-out and scission, occur in both glassy polymers and elastomers, but the two classes of material are considered separately because their deformation processes around a crack tip are so different. Emphasis is placed on the work in which the author has participated and so the review makes no attempt to be an unbiased survey of the field.
44. Brown, J.R., P.J.C. Chappell, and Z. Mathys, “Plasma surface modification of advanced organic fibres III: Effects on the mechanical properties of aramid/vinylester and extended-chain polyethylene/vinyl ester composites,” J. Materials Science, 27, 6475-6480, (1992).
1154. Brown, P.F., “The role of surface chemistry in the bonding of a cellulose substrate treated in a corona discharge (PhD dissertation),” The Institute of Paper Chemistry, 1971.
2355. Bruno, M.F., “Method of flame treating and heat sealing a biaxially oriented heat shrinkable plastic film,” U.S. Patent 3361607, Jan 1968.
2349. Bryan, W.L., and D.E. Swarts, “Flame treatment of polyvinyl fluoride,” U.S. Patent 3153683, Oct 1964.
1170. Brynolf, R., “Method and apparatus for treating substrate plastic parts to accept paint without using adhesion promoters,” U.S. Patent 6582773, Apr 2001.
1171. Brynolf, R., “Method and apparatus, with redundancies, for treating substrate plastic parts to accept paint without using adhesion promoters,” U.S. Patent #6716484, Nov 2002.
774. Buchman, A., H. Dodiuk, M. Rotel, and J. Zahavi, “Durability of laser treated reinforced PEEK/epoxy bonded joints,” in Polymer Surfaces and Interfaces: Characterization, Modification and Application, Mittal, K.L., and K.-W. Lee, eds., 37-70, VSP, Jun 1997.
738. Buchman, A., and H. Dodiuk-Kenig, “Laser surface treatment to improve adhesion,” in Adhesion Promotion Techniques: Technological Applications, Mittal, K.L., and A. Pizzi, eds., 205-244, Marcel Dekker, Feb 1999.
1297. Budziak, C.J., E.I. Vargha Butler, and A.W. Neumann, “Temperature dependence of contact angles on elastomers,” J. Applied Polymer Science, 42, 1959-1964, (1991).
2999. Burdzik, A., M. Stahler, M. Carmo, and D. Stolten, “Impact of reference values used for surface free energy determinatipn: An uncertainty analysis,” Intl. J. Adhesion and Adhesives, 82, 1-7, (Apr 2018).
Polar and dispersion surface free energy (SFE) can be determined with the Owens-Wendt method. Thereby, contact angles (CAs) of at least two liquids with known surface tension (ST) components are measured. The ST components can either be determined through experiment or drawn from literature. However, it is important to know how big the difference is between SFE component values that have been calculated with experimentally-determined ST values or values derived from literature. In this study, STs of different test liquids were analyzed by Pendant Drop method and the components by CA measurement on a non-polar surface. CAs on different polymer surfaces were measured to calculate SFE components with the Owens-Wendt method. The calculations conducted were either based on experimentally-determined ST parts or different sets of values found in the literature. The findings of the survey show that, depending on the set of literature values used, the SFE results deviate significantly from the values obtained from experiment. Expressing this deviation in figures, in extreme cases the polar part differs for some polymers by -100% to +100%, with the dispersion component spanning -50% to +43%. In comparison, the expected relative uncertainties exhibited by the experimentally-determined ST values are about 15% for the polar and approximately 5% for the dispersion SFE part. Hence, the results show that the SFE uncertainty can be reduced significantly by means of analyzing the ST parts experimentally.
430. Burkstrand, J.M., “Metal-polymer interfaces: Adhesion and x-ray photoemission studies,” J. Applied Physics, 52, 4795-4800, (1981).
431. Burrell, H., “The challenge of the solubility parameter concept,” J. Paint Technology, 40, 197, (1968).
45. Burrell, M.C., and J.J. Chera, “Surface analysis of BPA-polycarbonate/poly(butylene terephthalate) blends by x-ray photoelectron spectroscopy,” Applied Surface Science, 35, 110-120, (1988).
1785. Busscher, H.J., A.W.J. Van Pelt, H.P. De Jong, and J. Arends, “Effect of spreading pressure on surface free energy determinations by means of contact angle measurements,” J. Colloid and Interface Science, 95, 23-27, (Sep 1983).
2115. Busscher, H.J., A.W.J. van Pelt, P. de Boer, H.P. de Long, and J. Arends, “The effect of surface roughening of polymers on measured contact angles of liquids,” Colloids and Surfaces, 9, 319-331, (May 1984).
46. Busscher, H.J., and J. Arends, “Determination of the surface forces from contact angle measurements on polymers and dental enamel,” J. Colloid and Interface Science, 81, 75-79, (1981).
2314. Butcher, L.M. Jr., “Method for improving the wettability of a sheet material,” U.S. Patent 3871980, Mar 1975.
1039. Butt, H.-J., K. Graf, and M. Kappl, eds., Physics and Chemistry of Interfaces, 2nd Ed., Wiley-VCH, Mar 2006.
47. Cahn, J.W., “Critical point wetting,” J. Chemical Physics, 66, 3667-3672, (1977).
432. Cai, G., M.H. Litt, and I.M. Krieger, “Surface properties and abhesion of undecyl oxazoline block and homopolymers,” J. Polymer Science Part B: Polymer Physics, 29, 773-784, (1991).
49. Caimi, R.J., L.K. Derr, T.J. Dunn, and D. Ruff, “Precision of the surface energy test,” Converting, 10, 62-64, (Jun 1992).
2103. Caines, R.S., “Process for manufacture of surface-modified oriented polymeric film,” U.S. Patent 4810434, May 1989.
48. Callari, J., “Treat film only where needed, or you're throwing away $$,” Plastics Technology, 44, 53, (Apr 1998).
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