ACCU DYNE TEST ™ Bibliography
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2294. Wenzel, R.N., “Resistance of solid surfaces to wetting by water,” Industrial & Engineering Chemistry, 28, 988-994, (1936).
2338. Mantell, R.M., and W.L. Ormand, “Activation of plastic surfaces in a plasmajet,” Industrial & Engineering Chemistry, 3, 300-303, (Dec 1964).
1530. Fowkes, F.M., and M.A. Mostafa, “Acid-base interactions in polymer adsorption,” Industrial & Engineering Chemistry Product Research & Development, 17, 3-7, (1978).
2784. Kato, Y., F.M. Fowkes, and J.W. Vanderhoff, “Surface energetics of the lithographic printing process,” Industrial & Engineering Chemistry Product Research & Development, 21, 441-450, (1982).
1634. Hsieh, Y.-L., and E.Y. Chen, “Improvement of hydrophilicity of poly(ethylene terephthalate) by non-polymer forming gaseous glow discharge,” Industrial & Engineering Chemistry Product Research and Development, 24, 246, (1985).
107. Fowkes, F.M., “Attractive forces at interfaces,” Industrial and Engineering Chemistry, 56, 40-52, (Dec 1964).
400. Zisman, W.A., “Adhesion,” Industrial and Engineering Chemistry, 55, 18-38, (1963).
1789. Fox, H.W., P.W. Taylor, and W.A. Zisman, “Polyorganosiloxanes: Surface active properties,” Industrial and Engineering Chemistry, 39, 1401-1409, (1947).
1522. Snyder, J.M., I.K. Meier, and J. Whitehead, “New additive technologies for fountain solutions,” Ink Maker, 85, 28-33, (Jan 2007).
97. Fishman, D., “All about surface tension,” Ink World, 3, 22-28, (May 1997).
296. Podhajny, R.M., “Progress and problems of surface tension measurement of films,” Ink World, 3, 22-26, (Jul 1997).
2215. Madhusoodhanan, S., S. Sung, E. Delp, et al, “Dynamic surface tension of digital UV curable inks,” Ink World, 14, 0, (Mar 2008).
1083. Morgan, W., “Why do I need corona treating & how does it work?,” Inside The FTA, (Aug 2004).
78. Dewez, J.L., E. Humbeek, et al, “Plasma treated polymer films: Relationship between surface composition and surface hydrophilicity,” in Polymer-Solid Interfaces, 463-474, Inst. of Physics Publishing, 1991.
998. Sako, N., T. Matsuoka, and K. Sakaguchi, “Changes and control of plasma modified surface energy of polypropylene with aging time and temperature,” in Adhesion '99, 395-400, Institute of Materials, 1999.
999. Tod, D.A., and P.D. Wylie, “Surface pretreatments for hypalon,” in Adhesion '99, 375-379, Institute of Materials, 1999.
1000. Sharpe, L.H., “Wettability and adhesion revisited,” in Adhesion '99, 19-24, Institute of Materials, 1999.
1011. Ogawa, T., T. Sato, and S. Ogawa, “Charge density distribution of functional groups and their contribution to adhesion properties,” in Adhesion '99, 149-154, Institute of Materials, 1999.
544. Pireaux, J.J., P. Bertrand, and J.L. Bredas, eds., Polymer - Solid Interfaces, Institute of Physics, 1991.
1517. Holland, L., “Glow discharge excitation and surface treatment in low-pressure plasmas,” in Conference Series No. 54, 220-228, Institute of Physics, 1980.
1536. Becker, K.H., U. Kogelschatz, K.H. Schoenbach, and R.J. Barker, eds., Non-Equilibrium Air Plasmas at Atmospheric Pressure, Institute of Physics, Nov 2004.
1537. Kogelschatz, U., Y.S. Akishev, and A.P. Napartovich, “History of non-equilibrium air discharges,” in Non-Equilibrium Air Plasmas at Atmospheric Pressure, Becker, K.H., U. Kogelschatz, K.H. Schoenbach, and R.J. Barker, eds., 17-75, Institute of Physics, Nov 2004.
1538. Becker, K.H., M. Schmidt, A.A. Viggiano, R. Dressler, and S. Williams, “Air plasma chemistry,” in Non-Equilibrium Air Plasmas at Atmospheric Pressure, Becker, K.H., U. Kogelschatz, K.H. Schoenbach, and R.J. Barker, eds., 124-182, Institute of Physics, Nov 2004.
1539. Kogelschatz, U., Y.S. Akishev, K.H. Becker, E.E. Kunhart, M. Kogoma, et al, “DC and low frequency air plasma sources,” in Non-Equilibrium Air Plasmas at Atmospheric Pressure, Becker, K.H., U. Kogelschatz, K.H. Schoenbach, and R.J. Barker, eds., 276-361, Institute of Physics, Nov 2004.
1540. Laroussi, M., K.H. Schoenbach, U. Kogelschatz, R.J. Vidmar, S. Kuo, et al, “Current applications of atmospheric pressure air plasmas,” in Non-Equilibrium Air Plasmas at Atmospheric Pressure, Becker, K.H., U. Kogelschatz, K.H. Schoenbach, and R.J. Barker, eds., 537-678, Institute of Physics, Nov 2004.
626. Chakraborty, A.K., “Progress and future directions in the theory of strongly interacting polymer - solid interfaces,” in Polymer - Solid Interfaces, Pireaux, J.J., P. Bertrand, and J.L. Bredas, eds., 3-35, Institute of Physics Publishing, 1991.
629. David, D.J., “Fundamental concepts in the interfacial adhesion of laminated safety glass,” in Polymer - Solid Interfaces, Pireaux, J.J., P. Bertrand, and J.L. Bredas, eds., 133-144, Institute of Physics Publishing, 1991.
645. Liston, E.M., “Plasma modification of polymer surfaces,” in Polymer - Solid Interfaces, Pireaux, J.J., P. Bertrand, and J.L. Bredas, eds., 429-454, Institute of Physics Publishing, 1991.
648. Morra, M., E. Occhiello, and F. Garbassi, “Dynamics of plasma treated polymer surfaces: mechanisms and effects,” in Polymer - Solid Interfaces, Pireaux, J.J., P. Bertrand, and J.L. Bredas, eds., 407-428, Institute of Physics Publishing, 1991.
649. Nowak, S.M., M. Collaud, et al, “Polymer - metal interface formation after in-situ plasma and ion treatment,” in Polymer - Solid Interfaces, Pireaux, J.J., P. Bertrand, and J.L. Bredas, eds., 257-280, Institute of Physics Publishing, 1991.
652. Silvain, J.F., A. Veyrat, and J.J. Ehrhardt, “Morphology and adhesion of magnesium thin films evaporated on polyethylene terephthalate,” in Polymer - Solid Interfaces, Pireaux, J.J., P. Bertrand, and J.L. Bredas, eds., 281-287, Institute of Physics Publishing, 1991.
656. Vargo, T.G., and J.A. Gardella Jr., “Modification of surfaces designed for cell growth studies,” in Polymer - Solid Interfaces, Pireaux, J.J., P. Bertrand, and J.L. Bredas, eds., 485-494, Institute of Physics Publishing, 1991.
1198. Cazabat, A.M., S. Gerdes, M.P. Valignat, and S. Villette, “Dynamics of wetting: from theory to experiment,” Interface Science, 5, 129-139, (Sep 1997).
1438. Wade, G.A., W.J. Cantwell, and R.C. Pond, “Plasma surface modification of glass fibre-reinforced nylon-6,6 thermoplastic composites for improved adhesive bonding,” Interface Science, 8, 363-373, (Oct 2000).
2766. Custodio, J., J. Broughton, H. Cruz, and P. Winfield, “Activation of timber surfaces by flame and corona treatments to improve adhesion,” International J. of Adhesion and Adhesives, 29, 167-172, (Mar 2009).
Long-term durability of a structural adhesive joint is an important requirement, because it has to be able to support the required design loads, under service conditions, for the planed lifetime of the structure. One way of improving bond durability is through the use of surface treatments prior to bonding, which will activate the adherends’ surface, making it more receptive to the adhesive. In this study, the effects of two surface pre-treatments (corona discharge and flame ionization) on three timbers (maritime pine, iroko, and European oak) were evaluated quantitatively through contact angle measurements. These measurements allowed the determination of the changes in the timber surface thermodynamic characteristics, thus indicating which pre-treatment performed better. The results showed that both techniques increased each timber's surface free energy, which could translate into a durability enhancement of bonded joints. Overall, the corona-discharge treatment looks more promising, since this treatment leads to a bigger increase in the timber's surface energy, especially in its polar component, whilst also tended to be less species specific, less susceptible to variation, and the treatment effects lasted longer for this type of treatment.
2765. Roth, J.R., D.M. Sherman, F. Karakaya, P.P.Y. Tsai, K. Kelly-Wintenberg, and T.C. Montie, “Increasing the surface energy and sterilization of nonwoven fabrics by exposure to a one atmosphere uniform glow discharge plasma (OAUGDP),” International Nonwovens J., 10, 34-47, (2001).
653. Sugita, K., “Wettability and adhesion of polymer surfaces,” International Polymer Science and Technology, 14-T, 38-46, (Sep 1994).
2478. no author cited, “International Standard ISO 8296-2013: Plastics - film and sheeting - determination of wetting tension,” International Standards Organization, 2013.
2736. Dowling, D.P., J. Tynan, P. Ward, A.M. Hynes, J. Cullen, and G. Byrne, “Atmospheric pressure plasma treatment of amorphous polyethylene terephthalate for enhanced heatsealing properties,” Intl. J. Adhesion & Adhesives, 35, 1-8, (2012).
An atmospheric pressure plasma system has been used to treat amorphous polyethylene terephthalate (APET) to enhance its healseal properties to a polyethylene terephthalate (PET) film. The plasma treated APET sheet material was thermoformed into trays for use in the food packaging industry and heatsealed to a PET film. The heatsealing properties of the resulting package were assessed using the burst test technique. It was found that the plasma treatment significantly enhanced the adhesive properties and an increase in burst pressure from 18 to 35 kPa was observed for plasma treated food trays. The APET surface chemistry was assessed after plasma treatment where it was found that the plasma treatment had affected an increase in oxygen and an addition of nitrogen species to the polymer surface. The surface roughness (Ra) of the plasma treated samples was also observed to increase from 0.4 to 0.9 nm after plasma treatment.
598. Wightman, J.P., T.D. Lin, and H.F. Webster, “Surface chemical aspects of polymer/metal adhesion,” Intl. J. Adhesion and Adhesives, 12, 133-137, (Jul 1992).
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