ACCU DYNE TEST ™ Bibliography
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957. Jingxin, L., and L. Xia, “Surface graft polymerization of 2-hydroxyethyl methacrylate onto low-density polyethylene film through corona discharge in air,” J. Applied Polymer Science, 81, 2881-2887, (Sep 2001).
1485. Joanny, J.F., and P.G. de Gennes, “A model for contact-angle hysteresis,” J. Chemical Physics, 81, 552-562, (1984).
1165. Johans, C., I. Palonen, P. Suomalainen, and P.K.J. Kinnunen, “Making surface tension measurement a practical utility for modern industrial R & D,” American Laboratory (News Edition), 37, 14-16, (Dec 2005).
1573. Johansson, K., “Plasma modification of natural cellulosic fibres,” in Plasma Technologies for Textiles, Shishoo, R., ed., 247-281, Woodhead Publishing, Mar 2007.
1426. Johansson, K.S., “Ammonia plasma-simulating treatments and their impact on wettability of PET fabrics,” in Contact Angle, Wettability and Adhesion, Vol. 4, Mittal, K.L., ed., 335-350, VSP, Jul 2006.
492. Johnson, B.A., “Studies of advancing and receding contact angles (MS thesis),” Univ. of Wisconsin, Madison, 1982.
177. Johnson, R.E. Jr., and R.H. Dettre, “An evaluation of Neumann's 'Surface equation of state' (comments),” Langmuir, 5, 293-295, (1989).
178. Johnson, R.E. Jr., and R.H. Dettre, “Wetting of low energy surfaces,” in Wettability, Berg, J.C., 1-74, Marcel Dekker, Apr 1993.
1605. Johnson, R.E. Jr., and R.H. Dettre, “Contact angle hysteresis, 1: Study of an idealized rough surface,” in Contact Angle, Wettability and Adhesion: The Kendall Award Symposium Honoring William A. Zisman (Advances in Chemistry Series 43), Fowkes, F.M., and R.F. Gould, eds., 112-135, American Chemical Society, 1964.
2297. Johnson, R.E. Jr., and R.H. Dettre, “Wettability and contact angles,” in Surface and Colloid Science, Vol. 2, Matijevic, E., ed., 85-153, Wiley - Interscience, 1969.
2301. Johnson, R.E. Jr., and R.H. Dettre, “Contact angle hysteresis III: Study of an idealized heterogeneous surface,” J. Physical Chemistry, 68, 1744-1750, (Jul 1964).
1998. Johnson, R.E., Jr., R.H. Dettre, andD.A. Brandreth, “Dynamic contact angles and contact angle hysteresis,” J. Colloid and Interface Science, 62, 205-212, (Nov 1977).
728. Jones, R.A.L., and R.W. Richards, Polymers at Surfaces and Interfaces, Cambridge University Press, Jun 1999.
2279. Jones, V., “Development of poly(propylene) surface topography during corona treatment,” Plasma Processes and Polymers, 2, 547-553, (Aug 2005).
Atomic force microscopy (AFM), contact-angle measurements, and X-ray photoelectron spectroscopy (XPS or ESCA) were used to characterize biaxially oriented poly(propylene) (PP) films modified by exposure to a corona discharge. Surface analysis was performed on PP films modified at various corona energies to explore the changes in surface topography, wettability, and oxidation state resulting from the corona treatment. Even at low corona energies, water-soluble low-molecular-weight oxidized materials (LMWOM) are formed. These LMWOM products agglomerate into small topographical mounds that are visible in the AFM images. For the detection of LMWOM on corona-treated surfaces, AFM appears to be at least as sensitive as contact-angle measurements or ESCA. A major advantage of AFM relative to the other surface analytical techniques used to confirm the presence of the LMWOM is that no washing of the surface with water is required in conjunction with the AFM analysis.
179. Jones, W.C., “Testing surfaces for cleanliness,” Metal Finishing, 83, 13-15, (Oct 1985).
2780. Jones, W.C., and M.C. Porter, “A method for measuring contact angles on fibres,” J. Colloid and Interface Science, 24, 1+, (1967).
493. Jones, W.R., “Contact angle and surface tension measurements of a five-ring polyphenyl ether,” ASLE Translations, 29, 276-282, (Apr 1986).
670. Joos, P., Dynamic Surface Phenomena, VSP, Sep 1999.
494. Joos, P., and E. Rillaerts, “Theory on the determination of the dynamic surface tension with the drop volume and maximum bubble pressure methods,” J. Colloid and Interface Science, 79, 96-100, (1981).
1733. Jorda-Vilaplana, A., V. Fombuena, D. Garcia-Garcia, M.D. Samper, and L. Sanchez-Nacher, “Surface modification of polylactic acid (PLA) by air atmospheric plasma treatment,” European Polymer J., 58, 23-33, (Jun 2014).
2420. Jordan, J.F., A. Yahiaoui, and P.R.R. Wallajapet, “Durable hydrophilic treatment for a biodegradable polymeric substrate,” U.S. Patent 7700500, Apr 2010.
2406. Jorgensen, M., “Electric discharge surface treating electrode and system,” U.S. Patent 6007784, Dec 1999.
2273. Joshi, R., R.-D. Schulze, A. Meyer-Plath, and J.F. Friedrich, “Selective surface modification of poly(propylene) with OH and COOH groups using liquid-plasma systems,” Plasma Processes and Polymers, 5, 695-707, (Sep 2008).
Underwater plasma and glow discharge electrolysis are interesting new methods for polymer surface functionalization. The achievable content of O-containing functional groups exceeds that of oxygen glow discharge gas plasmas by a factor of two (up to ca. 56 O/100 C). The percentage of OH groups among all O-containing groups can reach 25 to 40%, whereas it is about 10% in the gas plasmas. Addition of hydrogen peroxide increases the fraction of OH groups to at most 70% (27 OH/100 C). The liquid plasma systems are also able to polymerize acrylic acid and deposit the polymer as very thin film on substrate surfaces or membranes, thereby retaining about 80% of all COOH functional groups (27 COOH/100 C).
2421. Jung, J., and T. Gottfreund, “Biaxially oriented polyolefin film having improved surface properties,” U.S. Patent 7824600, Nov 2010.
495. Junnila, J., A. Savolainen, and D. Forsberg, “Adhesion improvements between paper and polyethylene by pretreatment of substrates,” in 1989 Polymers, Laminations and Coatings Conference Proceedings, TAPPI Press, Aug 1989.
2074. K. Kato, V.N. Vasilets, M.N. Fursa, M. Meguro, Y. Ikada, and K. Nakamae, “Surface oxidation of cellulose fibers by vacuum ultraviolet irradiation,” J. Polymer Science Part A: Polymer Chemistry, 37, 357-361, (1999).
180. Kaainoa, S., “What you should know about bare-roll corona treaters,” Plastics Technology, 32, 85-88, (Feb 1986).
1514. Kabza, K., J.E. Gestwicki, and J.L. McGrath, “Contact angle goniometry as a tool for surface tension measurements of solids, using Zisman plot method: A physical chemistry experiment,” J. Chemical Education, 77, 63-65, (Jan 2000).
1450. Kaczinski, M.B., and D.W. Dwight, “Enhancement of polymer film adhesion using acid-base interactions determined by contact angle measurements,” J. Adhesion Science and Technology, 7, 165-177, (1993) (also in Contact Angle, Wettability and Adhesion: Festschrift in Honor of Professor Robert J. Good, K.L. Mittal, ed., p. 739-751, VSP, Nov 1993).
181. Kaczmarek, H., “Changes to polymer morphology caused by UV irradiation, I. Surface damage,” Polymer, 37, 189-194, (1996).
496. Kadash, M.M., and C.G. Seefried Jr., “Closer characterization of corona treated PE surfaces,” Plastics Engineering, 41, 45-48, (Dec 1985).
184. Kaelble, D.H., “Interface degradation processes and durability,” Polymer Engineering and Science, 17, 474-477, (1977).
497. Kaelble, D.H., “Dispersion-polar surface tension properties of organic solids,” J. Adhesion, 2, 66-81, (1970).
947. Kaelble, D.H., P.J. Dynes, and D. Pav, “Surface energetics analysis of lithography,” in Adhesion Science and Technology, Lee, L.-H., ed., 735-761, Plenum Press, 1975.
498. Kaelble, D.H., P.J. Dynes, and L. Maus, “Surface energy analysis of treated graphite fibers,” J. Adhesion, 6, 239+, (1974).
182. Kaelble, D.H., and E.H. Cirlin, “Dispersion and polar contributions to surface tension of poly(methylene oxide) and Na-treated polytetrafluoroethylene,” J. Polymer Science Part B: Polymer Physics, 9, 363-368, (1971).
183. Kaelble, D.H., and J. Moacanin, “A surface energy analysis of bioadhesion,” Polymer, 18, 475-482, (1977).
2356. Kaghan, W.S., P.M. Kay, and W.J. Schmitt, “Method for improving electric glow discharge treatment of plastic materials,” U.S. Patent 3391044, Jul 1968.
2310. Kaghan, W.S., and D.F. Stoneback, “Electrical discharge treatment of polyethylene,” U.S. Patent 2859481, Nov 1958.
2897. Kalantarian, A., R. David, and A.W. Neumann, “Methodology for high accuracy contact angle measurement,” Langmuir, 25, 14146-14154, (Aug 2009).
A new version of axisymmetric drop shape analysis (ADSA) called ADSA-NA (ADSA-no apex) was developed for measuring interfacial properties for drop configurations without an apex. ADSA-NA facilitates contact angle measurements on drops with a capillary protruding into the drop. Thus a much simpler experimental setup, not involving formation of a complete drop from below through a hole in the test surface, may be used. The contact angles of long-chained alkanes on a commercial fluoropolymer, Teflon AF 1600, were measured using the new method. A new numerical scheme was incorporated into the image processing to improve the location of the contact points of the liquid meniscus with the solid substrate to subpixel resolution. The images acquired in the experiments were also analyzed by a different drop shape technique called theoretical image fitting analysis-axisymmetric interfaces (TIFA-AI). The results were compared with literature values obtained by means of the standard ADSA for sessile drops with the apex. Comparison of the results from ADSA-NA with those from TIFA-AI and ADSA reveals that, with different numerical strategies and experimental setups, contact angles can be measured with an accuracy of less than 0.2°. Contact angles and surface tensions measured from drops with no apex, i.e., by means of ADSA-NA and TIFA-AI, were considerably less scattered than those from complete drops with apex. ADSA-NA was also used to explore sources of improvement in contact angle resolution. It was found that using an accurate value of surface tension as an input enhances the accuracy of contact angle measurements.
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