ACCU DYNE TEST ™ Bibliography
Provided as an information service by Diversified Enterprises.
showing result page 27 of 76, ordered by
309. Sanchez-Rubio, M., J.R. Castellanos-Ortega, and J.E. Puig, “An analytical balance as tensiometer and densimeter,” J. Chemical Education, 68, 158-160, (1991).
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).
2774. Lamour, G., A. Hamraoui, A. Buvailo, Y. Xing, S. Keuleyan, V. Prokash, et al, “Contact angle measurements using a simplified experimental setup,” J. Chemical Education, 67, 1403-1407, (Dec 2010).
A basic and affordable experimental apparatus is described that measures the static contact angle of a liquid drop in contact with a solid. The image of the drop is made with a simple digital camera by taking a picture that is magnified by an optical lens. The profile of the drop is then processed with ImageJ free software. The ImageJ contact angle plugin detects the edge of the drop and fits its profile to a circle or an ellipse. The tangent to the triple line contact is calculated and drawn by the ImageJ software, thus, returning the value of the contact angle with acute precision on the measurement.
47. Cahn, J.W., “Critical point wetting,” J. Chemical Physics, 66, 3667-3672, (1977).
104. Fowkes, F.M., and W.M. Sawyer, “Contact angles and boundary energies of a low energy solid (letter),” J. Chemical Physics, 20, 1652, (1952).
213. Lee, C.Y., J.A. McCammonn and P.J. Rossky, “The structure of liquid water at an extended hydrophobic surface,” J. Chemical Physics, 80, 4448-4455, (1984).
316. Schonhorn, H., “Theoretical relationship between surface tension and cohesive energy density,” J. Chemical Physics, 43, 2041-2043, (1965).
1485. Joanny, J.F., and P.G. de Gennes, “A model for contact-angle hysteresis,” J. Chemical Physics, 81, 552-562, (1984).
1949. Murphy, W.J., M.W. Roberts, and J.R.H. Ross, “Contact angle studies of some low energy polymer surfaces,” J. Chemical Society, Faraday Transactions 1, 68, 1190-1199, (1972).
1580. Herbert, P.A.F., and E. Bourdin, “New generation atmospheric pressure plasma technology for industrial on-line processing,” J. Coated Fabrics, 28, (1999).
57. Cheever, G.D., “Evaluation of heterogeneous surfaces by contact angle distributions,” J. Coatings Technology, 58, 37-42, (Jan 1986).
250. Munro, H.S., and D.I. McBriar, “Influence of post treatment storage on the surface chemistry of plasma oxidized polymers,” J. Coatings Technology, 60, 41-46, (Nov 1988).
368. Tsutsui, K., A. Iwata, and S. Ikeda, “Plasma surface treatment of polypropylene-containing plastics,” J. Coatings Technology, 61, 65-72, (Sep 1989).
564. Schwartz, J., “The importance of low dynamic surface tension in waterborne coatings,” J. Coatings Technology, 64, 65-73, (Sep 1992).
607. Zisman, W.A., “Surface energetics of wetting, spreading, and adhesion,” J. Coatings Technology, 44, (1972).
1691. Al-Turaif, H., “Relationship between surface chemistry and surface energy of different shape pigment blend coatings,” J. Coatings Technology and Research, 5, 85-91, (Mar 2008).
The influence of pigment shapes and pigment blends on the surface energy was investigated and compared with the surface chemistry of pigmented latex coatings. The coatings were made of different volume ratios of two pigments: plate-like kaolin clay pigment and prismatic precipitated calcium carbonate (PCC) pigment. These were mixed together with carboxylated styrene–butadiene–acrylonitrile latex (SBA), and applied over nonabsorbent substrates as well as absorbent substrates. The composition of the surface of the coatings was investigated by X-ray photoelectron spectroscopy (XPS). Two approaches were used to estimate the total surface energy and the components of the coatings: a conventional approach—“the Kaelble approach”—and a more modern approach—“the van Oss approach.” Pigment blends with different shapes and increments caused a change in the surface chemistry and the surface energy of the latex coatings. As the prismatic PCC pigment particles increased in the kaolin/SBA coating system, the SBA latex content at the coating surface increased and the total surface energy of the coating decreased. This is valid for both nonabsorbent as well as absorbent substrates. It was found that there was a strong correlation between the surface energy and the surface composition. The surface energy of the coatings estimated by the Van Oss approach was always lower than that estimated by the Kaelble approach. Colloidal interactions between pigment–pigment and/or pigment–binder were thought to play an essential role in determining the final coating surface energy and its components. Changes in the surface latex content and the surface energy due to the different pigment blends investigated were found to fit straight-line equations.
109. Fox, H.W., and W.A. Zisman, “The spreading of liquids on low energy surfaces, I. Polytetrafluoroethylene,” J. Colloid Science, 5, 514-531, (1950).
110. Fox, H.W., and W.A. Zisman, “The spreading of liquids on low energy surfaces, II. Modified tetrafluoroethylene polymers,” J. Colloid Science, 7, 109-121, (1952).
111. Fox, H.W., and W.A. Zisman, “The spreading of liquids on low energy surfaces, III. Hydrocarbon surfaces,” J. Colloid Science, 7, 428-442, (1952).
112. Fox, H.W., and W.A. Zisman, “The spreading of liquids on low energy surfaces, VI. Branched-chain monolayers, aromatic surfaces, and thin liquid films,” J. Colloid Science, 8, 194-203, (1953).
1918. Fort, T., Jr., and H.T. Patterson, “A simple method for measuring solid-liquid contact angles,” J. Colloid Science, 18, 217-222, (Mar 1963).
1919. Kawasaki, K., “Study of wettability of polymers by sliding of water drop,” J. Colloid Science, 15, 402-407, (Oct 1960).
1920. Allan, A.J.G., “Surface properties of polyethylene: Effect of an amphiphatic additive,” J. Colloid Science, 14, 206-221, (Apr 1959).
2090. Shafrin, E.G., and W.A. Zisman, “The spreading of liquids on low-energy surfaces IV: Monolayer coatings on platinum,” J. Colloid Science, 7, 166-177, (Apr 1952).
3. Baszkin, A., M. Nishino, and L. Ter-Minassian-Saraga, “Solid-liquid adhesion of oxidized polyethylene films.Effect of temperature on polar forces,” J. Colloid and Interface Science, 59, 516-524, (1977).
8. Andrade, J.D., S.M. Ma, R.N. King, and D.E. Gregonis, “Contact angles at the solid-liquid interface,” J. Colloid and Interface Science, 72, 488-494, (1979).
24. Blais, P., D.J. Carlsson, G.W. Csullog, and D.M. Wiles, “The chromic acid etching of polyolefin surfaces, and adhesive bonding,” J. Colloid and Interface Science, 47, 636-649, (1974).
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).
53. Chan, R.K.S., “Surface tension of fluoropolymers, I. London dispersion term,” J. Colloid and Interface Science, 32, 492-498, (1970).
54. Chan, R.K.S., “Surface tension of fluoropolymers, II. The polar attraction term,” J. Colloid and Interface Science, 32, 499-504, (1970).
69. Dann, J.R., “Forces involved in the adhesive process, I. Critical surface tensions of polymeric solids as determined with polar liquids,” J. Colloid and Interface Science, 32, 302-320, (1970).
70. Dann, J.R., “Forces involved in the adhesive process, II. Nondisperions forces at solid-liquid interfaces,” J. Colloid and Interface Science, 32, 321-331, (1970).
87. Dwight, D.W., and W.M. Riggs, “Fluoropolymer surface studies,” J. Colloid and Interface Science, 47, 650-660, (1974).
88. Dwight, D.W., “Surface analysis and adhesive bonding, I. Fluoropolymers,” J. Colloid and Interface Science, 59, 447-455, (1977).
91. Eick, J.D., R.J. Good, and A.W. Neumann, “Thermodynamics of contact angles, II. Rough solid surfaces,” J. Colloid and Interface Science, 53, 235-248, (1975).
121. Gardon, J.L., “Critical review of concepts common to cohesive energy density, surface tension, tensile strength, heat of mixing, interfacial tension, and butt joint strength,” J. Colloid and Interface Science, 59, 582-596, (1977).
140. Good, R.J., J.A. Kvikstad, and W.O. Bailey, “Anisotropic forces in the surface of a stretch-oriented polymer,” J. Colloid and Interface Science, 35, 314-327, (1971).
141. Good, R.J., “Surface free energy of solids and liquids: thermodynamics, molecular forces, and structure,” J. Colloid and Interface Science, 59, 398-419, (1977).
165. Huh, C., and S.G. Mason, “Effects of surface roughness on wetting (theoretical),” J. Colloid and Interface Science, 60, 11-38, (1977).
172. Israelachvili, J.N., and B.W. Ninham, “Intermolecular forces - the long and short of it,” J. Colloid and Interface Science, 58, 14-25, (1977).
<-- Previous | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 | 16 | 17 | 18 | 19 | 20 | 21 | 22 | 23 | 24 | 25 | 26 | 27 | 28 | 29 | 30 | 31 | 32 | 33 | 34 | 35 | 36 | 37 | 38 | 39 | 40 | 41 | 42 | 43 | 44 | 45 | 46 | 47 | 48 | 49 | 50 | 51 | 52 | 53 | 54 | 55 | 56 | 57 | 58 | 59 | 60 | 61 | 62 | 63 | 64 | 65 | 66 | 67 | 68 | 69 | 70 | 71 | 72 | 73 | 74 | 75 | 76 | Next-->