Surface Energy of Solids: Selection of Effective Substrates for Bioadhesion in Aqueous Media

Authors

  • Katarzyna Boniewicz-Szmyt Gdynia Maritime University, Morska 81-87, 81-225 Gdynia, Poland, Faculty of Marine Engineering, Department of Physics https://orcid.org/0000-0003-1693-6623
  • Stanisław Pogorzelski University of Gdańsk, Wita Stwosza 57, 80-308 Gdańsk, Poland, Faculty of Mathematics, Physics and Informatics, Institute of Experimental Physics https://orcid.org/0000-0001-5618-7941

DOI:

https://doi.org/10.26408/112.01

Keywords:

wettability process energetics, surface adsorption, contact angle hysteresis, bioadhesion, surface energy

Abstract

Surface wettability of model solids of different hydrophobicity (from hydrophilic to hydrophobic) in contact with an aqueous medium was determined by measuring the dynamic contact angles (CA) using common techniques: sessile drop, inclined plate and captive bubble. The surface wettability energetics parameters: contact angle hysteresis (CAH), 2D adhesive layer pressure, surface free energy (SFE) and work values of cohesion, adhesion and spreading were determined using the formalism proposed by Chibowski [2003]. CA values depended on the technique used and experimental conditions (flow numbers, spatial heterogeneity and roughness of the sample). The most effective substrates for testing bioadhesion on solids submerged in aqueous media were hydrophilic surfaces (SFE ~ 40–58 mJ m-2; CAH ~ 16–20 mN m-1).

References

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[20] Mazurek, A., Pogorzelski, S.J., Boniewicz-Szmyt, K., 2009, Adsorption of Natural Surfactants Present in Sea Waters at Surfaces of Minerals: Contact Angle Measurements, Oceanologia, vol. 51, pp. 377–403.

[21] Pogorzelski, S.J., Berezowski, Z., Rochowski, P., Szurkowski, J., 2012, A Novel Methodology Based on Contact Angle Hysteresis Approach for Surface Changes Monitoring in Model PMMA-Corega Tab System, Applied Surface Science, vol. 258, pp. 3652–3658.

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[23] Pogorzelski, S.J., Mazurek, A.Z., Szczepańska, A., 2013, In-situ Surface Wettability Parameters of Submerged in Brackish Water Surfaces Derived from Captive Bubble Contact Angle Studies as Indicators of Surface Condition Level, Journal of Marine Systems, vol. 119–120, pp. 50–60.

[24] Pogorzelski, S.J., Rochowski, P., Szurkowski, J., 2014, Pinus sylvestris L. Needles Surface Wettability Parameters as Indicators of Atmospheric Environment Pollution Impacts: Novel Contact Angle Hysteresis Methodology, Applied Surface Science, vol. 292, pp. 857–866.

[25] Radelczuk, H., Hołysz, L., Chibowski, E., 2002, Comparison of the Lifshits – Van der Waals/Acid Base and Contact Angle Hysteresis Approaches to Determination of the Solid Surface Free Energy, Journal of Adhesion Science and Technology, vol. 16, pp. 1547–1568.

[26] Rame, E., Garoff, S., 1996, Microscopic and Macroscopic Dynamic Interface Shapes and the Interpretation of Dynamic Contact Angles, Journal of Colloid and Interface Science, vol. 177, pp. 234–244.

[27] Robson, M.A., Williams, D., Wolff, K., Thomason, J.C., 2009, The Effect of Surface Colour on the Adhesion Strength of Elminus Modestus Darwin on a Commercial Non-biocidal Antifouling Coating at Two Locations in the UK, Biofouling, vol. 25, pp. 215–227.

[28] Rodrigues-Valverde, M.A., Cabrerizo-Vilches, M.A., Rosales-Lopez, P., Paez-Duneas, A., Hidalgo-Alvarez, R., 2002, Contact Angle Measurements on Two (Wood and Stone) Non-ideal Surfaces, Colloids and Surfaces. A: Physicochem. Eng. Aspects, vol. 206, pp. 485-495.

[29] Rymuszka, D., Terpiłowski, K., Hołysz, L., 2013, Influence of Volume Drop on Surface Free Energy of Glass, Annales Univ. Mariae Curie-Skłodowska Lublin, vol. LXVIII, Sec. AA, pp. 121–132.

[30] Schaffer, E., Wong, P., 2000, Contact Line Dynamics Near the Pinning Threshold: A Capillary Rise and Fall Experiment, Physical Review E, vol. 61, pp. 5257–5277.

[31] Schmidt, D.L., Brady, R.F., Lam, K., Schmidt, D.C., Chaudhury, M.K., 2004, Contact Angle Hysteresis, Adhesion, and Marine Biofouling, Langmuir, vol. 20, pp. 2830–2836.

[32] Strobel, M., Lyons, Ch.S., 2011, An Essay on Contact Angle Measurements, Plasma Process. Polym., vol. 8, pp. 8–13.

[33] Qurynen, M., Bollen, C.M., 1995, The Influence of Surface Roughness and Surface Free- Energy on Supra- and Subgingival Plaque Formation in Man, J. Clin. Periodontol., vol. 22, pp. 1–14.

[34] Tavana, H., Lam, C.N.C., Grundke, K., Friedel, P., Kwok, D.Y., Hair, M.L., 2004, Contact Angle Measurements with Liquids Consisting of Bulky Molecules, J. Colloid Interf. Sci., vol. 279, pp. 493–502.

[35] Thomas, E., Muirhead, D., 2009, Impact of Wastewater Fouling on Contact Angle, Biofouling, vol. 25, pp. 445–454.

[36] Van Oss, C.J., 1997, Hydrophobicity and Hydrophilicity of Biointerfaces, Current Opinion in Colloid and Interface Science, vol. 2, pp. 503–512.

[37] Zhao, Q., Liu, Y., Wang, C., Wang, S., Muller-Steinhagen, H., 2005, Effect of Surface Free Energy on the Adhesion of Biofouling and Crystalline Fouling, Chemical Engineering Science, vol. 60, pp. 4858-4865.

[38] Zhou, Z.A., Hussein, H., Xu Z., Czarnecki, J., Masliyah, J.H., 1998, Interaction of Ionic Species and Fine Solids with a Low Energy Hydrophobic Surface from Contact Angle Measurement, J. Colloid Interface Sci., vol. 204, pp. 342–349.

[39] Żenkiewicz, M., 2007, Methods for the Calculation of Surface Free Energy of Solids, Journal of Achievements in Materials and Manufacturing, vol. 24, pp. 137–145.

Remove [1] Adamson, A.W., Gast, A.P., 1997, Physical Chemistry of Surfaces, 6th edition, Wiley and Sons, New York, USA.

[2] Afsar-Siddiqui, A.B., Luckham, P.F., Matar, O.K., 2003, The Spreading of Surfactant Solutions on thin Liquid Films, Adv. Colloid Interf., vol. 106, pp. 183–236.

[3] Baier, R.E., 1980, Adsorption of Microorganisms to Surface, Wiley-Interscience Publishers, New York, USA, pp. 59–104.

[4] Baier, R.E., 2006, Surface Behaviour of Biomaterials: The Theta Surface for Biocompatibility, J. Mater. Sci.: Mater. Med., vol. 17, pp. 1057–1062.

[5] Batlin, T.J., Kaplan, L.A., Newbold, J.D., Cheng, X., Hansen, C., 2003, Effects of Current Velocity on the Nascent Architecture of Stream Microbial Biofilms, Applied and Environmental Microbiology, vol. 69, pp. 5443–5452.

[6] Bormashenko, E., Bormashenko, Y., Whyman, G., Pogreb, R., Musin, A., Jager, R., Barkay, Z., 2008, Contact Angle Hysteresis on Polymer Substrates Established with Various Experimental Techniques, its Interpretation, and Quantitative Characterization, Langmuir, vol. 24, pp. 4020–4025.

[7] Bracke, M., De Voeght, F., Joos, P., 1989, The Kinetics of Wetting: the Dynamic Contact Angle, Progress in Colloid & Polymer Science, vol. 79, pp. 142–149.

[8] Chibowski, E., 2003, Surface Free Energy of a Solid from Contact Angle Hysteresis, Adv. Colloid Interf. Sci., vol. 103, pp. 149–172.

[9] Chibowski, E., 2007, On Some Relations Between Advancing, Receding and Young’s Contact Angles, Adv. Colloid Interf. Sci., vol. 133, pp. 51–59.

[10] Chibowski, E., Terpiłowski, K., 2008, Surface Free Energy of Sulfur – Revisited I. Yellow and Orange Samples Solidified Against Glass Surface, J. Colloid. Interface Sci., vol. 319, pp. 505–513.

[11] De Gennes, P.G., 1985, Wetting: Statics and Dynamics, Review of Modern Phys., vol. 57, pp. 827–834.

[12] Drelich, J., Miller, J.D., Good, R.J., 1996, The Effect of Drop (Bubble) on Advancing and Receding Contact Angles for Heterogenous and Rough Solid Surfaces as Observed with Sessile-drop and Captive-bubble Techniques, Journal of Colloid and Interface Science, vol. 179, pp. 37–50.

[13] Erbil, H.Y., 2006, Surface Chemistry of Solid and Liquid Interfaces, Blackwell Publ. Ltd., Hong Kong.

[14] Erbil, H.Y., Mc Hale, G., Rowan, S.M., Newton, M.I., 1999, Determination of the Receding Contact Angle of Sessile Drops on Polymer Surfaces, Langmuir, vol. 15, pp. 7378–7385.

[15] Finlay, J.A., Callow, M.E., Ista, L.K., Lopez, G.P., Callow, J.A., 2002, The Influence of Surface Wettability on the Adhesion Strength of Settled spores of the Green Alga Enteromorpha and the Diatom Amphora, Integr. Comp. Biol., vol. 42, pp. 1116–1122.

[16] Jańczuk, B., Wójcik, W., Zdziennicka, A., 1999, Wettability and Surface Free Energy of Glass in the Presence of Cetyltrimethylammonium Bromide, Materials Chemistry and Physics, vol. 58, pp. 166–171.

[17] Karaguzel, C., Can, M.F., Sonmez, E., Celik, M.S., 2005, Effect of Electrolite on Surface Free Energy Components of Feldspar Minerals Using Thin-layer Wicking Method, J. Colloid Interface Sci., vol. 285, pp. 192–200.

[18] Lakshmi, K., Muthukumar, T., Doble, M., Vedaprakash, L., Kruparathnam, D., Dineshram, R., Jayaraj, K., Venkatesan, R., 2012, Influence of Surface Characteristics on Biofouling Formed on Polymers Exposed to Coastal Sea Waters of India, Colloids and Surfaces B: Biointerfaces, vol. 91, pp. 205–211.

[19] Lam, C.N.C., Wu, R., Li, D., Hair, M.L., Neumann, A.W., 2002, Study of the Advancing and Receding Contact Angles: Liquid Sorption as a Cause of Contact Angle Hysteresis, Advances in Colloid and Interface Science, vol. 96, pp. 169–191.

[20] Mazurek, A., Pogorzelski, S.J., Boniewicz-Szmyt, K., 2009, Adsorption of Natural Surfactants Present in Sea Waters at Surfaces of Minerals: Contact Angle Measurements, Oceanologia, vol. 51, pp. 377–403.

[21] Pogorzelski, S.J., Berezowski, Z., Rochowski, P., Szurkowski, J., 2012, A Novel Methodology Based on Contact Angle Hysteresis Approach for Surface Changes Monitoring in Model PMMA-Corega Tab System, Applied Surface Science, vol. 258, pp. 3652–3658.

[22] Pogorzelski, S.J., Grzegorczyk, M., 2016, Method and Automatic Device for Continuous Non-invasive Measurement of Surface Energy of Solids Permanently Immersed in Liquids, Polish Government Patent Office, submission no. P.419913, University of Gdańsk, Gdańsk, Poland.

[23] Pogorzelski, S.J., Mazurek, A.Z., Szczepańska, A., 2013, In-situ Surface Wettability Parameters of Submerged in Brackish Water Surfaces Derived from Captive Bubble Contact Angle Studies as Indicators of Surface Condition Level, Journal of Marine Systems, vol. 119–120, pp. 50–60.

[24] Pogorzelski, S.J., Rochowski, P., Szurkowski, J., 2014, Pinus sylvestris L. Needles Surface Wettability Parameters as Indicators of Atmospheric Environment Pollution Impacts: Novel Contact Angle Hysteresis Methodology, Applied Surface Science, vol. 292, pp. 857–866.

[25] Radelczuk, H., Hołysz, L., Chibowski, E., 2002, Comparison of the Lifshits – Van der Waals/Acid Base and Contact Angle Hysteresis Approaches to Determination of the Solid Surface Free Energy, Journal of Adhesion Science and Technology, vol. 16, pp. 1547–1568.

[26] Rame, E., Garoff, S., 1996, Microscopic and Macroscopic Dynamic Interface Shapes and the Interpretation of Dynamic Contact Angles, Journal of Colloid and Interface Science, vol. 177, pp. 234–244.

[27] Robson, M.A., Williams, D., Wolff, K., Thomason, J.C., 2009, The Effect of Surface Colour on the Adhesion Strength of Elminus Modestus Darwin on a Commercial Non-biocidal Antifouling Coating at Two Locations in the UK, Biofouling, vol. 25, pp. 215–227.

[28] Rodrigues-Valverde, M.A., Cabrerizo-Vilches, M.A., Rosales-Lopez, P., Paez-Duneas, A., Hidalgo-Alvarez, R., 2002, Contact Angle Measurements on Two (Wood and Stone) Non-ideal Surfaces, Colloids and Surfaces. A: Physicochem. Eng. Aspects, vol. 206, pp. 485-495.

[29] Rymuszka, D., Terpiłowski, K., Hołysz, L., 2013, Influence of Volume Drop on Surface Free Energy of Glass, Annales Univ. Mariae Curie-Skłodowska Lublin, vol. LXVIII, Sec. AA, pp. 121–132.

[30] Schaffer, E., Wong, P., 2000, Contact Line Dynamics Near the Pinning Threshold: A Capillary Rise and Fall Experiment, Physical Review E, vol. 61, pp. 5257–5277.

[31] Schmidt, D.L., Brady, R.F., Lam, K., Schmidt, D.C., Chaudhury, M.K., 2004, Contact Angle Hysteresis, Adhesion, and Marine Biofouling, Langmuir, vol. 20, pp. 2830–2836.

[32] Strobel, M., Lyons, Ch.S., 2011, An Essay on Contact Angle Measurements, Plasma Process. Polym., vol. 8, pp. 8–13.

[33] Qurynen, M., Bollen, C.M., 1995, The Influence of Surface Roughness and Surface Free- Energy on Supra- and Subgingival Plaque Formation in Man, J. Clin. Periodontol., vol. 22, pp. 1–14.

[34] Tavana, H., Lam, C.N.C., Grundke, K., Friedel, P., Kwok, D.Y., Hair, M.L., 2004, Contact Angle Measurements with Liquids Consisting of Bulky Molecules, J. Colloid Interf. Sci., vol. 279, pp. 493–502.

[35] Thomas, E., Muirhead, D., 2009, Impact of Wastewater Fouling on Contact Angle, Biofouling, vol. 25, pp. 445–454.

[36] Van Oss, C.J., 1997, Hydrophobicity and Hydrophilicity of Biointerfaces, Current Opinion in Colloid and Interface Science, vol. 2, pp. 503–512.

[37] Zhao, Q., Liu, Y., Wang, C., Wang, S., Muller-Steinhagen, H., 2005, Effect of Surface Free Energy on the Adhesion of Biofouling and Crystalline Fouling, Chemical Engineering Science, vol. 60, pp. 4858-4865.

[38] Zhou, Z.A., Hussein, H., Xu Z., Czarnecki, J., Masliyah, J.H., 1998, Interaction of Ionic Species and Fine Solids with a Low Energy Hydrophobic Surface from Contact Angle Measurement, J. Colloid Interface Sci., vol. 204, pp. 342–349.

[39] Żenkiewicz, M., 2007, Methods for the Calculation of Surface Free Energy of Solids, Journal of Achievements in Materials and Manufacturing, vol. 24, pp. 137–145.

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Published

2019-12-30

How to Cite

Boniewicz-Szmyt, K., & Pogorzelski, S. (2019). Surface Energy of Solids: Selection of Effective Substrates for Bioadhesion in Aqueous Media. Scientific Journal of Gdynia Maritime University, 1(112), 7–22. https://doi.org/10.26408/112.01

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