Year 2022,
Volume: 7 Issue: 4, 316 - 321, 30.12.2022
Tuğçe Ervan
,
Mehmet Ali Küçüker
,
Uğur Cengiz
Project Number
FYL-2020-3256
References
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urban wastewater by Chlorella pyrenoidosa in
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coatings XV: An investigation of polysiloxane anti-fouling/fouling-release coatings containing tethered quaternary ammonium salt groups. ACS Combinatorial Science, 13, 298–309. [CrossRef]
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Nanoporosity-driven superhydrophilicity: A means
to create multifunctional antifogging coatings.
Langmuir, 22, 2856–2862. [CrossRef]
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Organic Coatings Fabrication and application of
superhydrophilic antifog surface by sol-gel method.
Progress in Organic Coatings, 126, 75–82. [CrossRef]
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carboxybetaine-containing copolymers for marine
fouling-release applications. ACS Applied Materials
and Interfaces, 12, 34148–34160. [CrossRef]
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the van Oss-Chaudhury- Good method. International Journal of Adhesion and Adhesives, 82, 139–
145. [CrossRef]
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(lactic acid). European Polymer Journal, 48(12),
2107–2116. [CrossRef]
Fabrication of Superhydrophilic TEOS-Lactic acid Composite Films and Investigation of Biofouling Behaviour
Year 2022,
Volume: 7 Issue: 4, 316 - 321, 30.12.2022
Tuğçe Ervan
,
Mehmet Ali Küçüker
,
Uğur Cengiz
Abstract
Phytoplankton and diatom microalgae species cause biofouling by adhering to the surfaces, especially in closed cultivation systems such as tubular photobioreactors. This biofilm formation blocks the sunlight; after harvesting, it is necessary to clean the reactor. This cleaning process causes loss not only for time and finance but also in terms of environmental pollution due to using toxic chemicals and excess water usage. This study aimed to investigate the reduction of the microorganism cell adhesion on the hybrid surface. To succeed in this, the composite surface of tetraethoxysilane (TEOS) and lactic acid (LA) was prepared by the sol-gel process. Then the hybrid surfaces were coated on glass slides by the dip coating method. The wettability performance of the TEOS-LA hybrid surface was investigated using contact angle measurement and light transmittance. The wettability result showed that the superhydrophilic surface having 54 mJ/m2 of surface free energy values was obtained. An increase in the lactic acid content of the composite films increased the surface free energy (SFE) values decreasing the water contact angle. A pencil hardness test characterized the mechanical strength of the surfaces, and it was determined that the hardness of the composite films was decreased by increasing the LA content of the composite films. Resultantly, it is found that the TEOS-LA superhydrophilic composite film reduces the adhesion of microalgae.
Supporting Institution
Canakkale Onsekiz Mart University, The Scientific Research Coordination Unit
Project Number
FYL-2020-3256
Thanks
This research was financially supported by Çanakkale Onsekiz Mart University The Scientific Research Coordination Unit, Project number: FYL-2020-3256
References
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Biomass, biopolymer-based materials, and bioenergy:
Construction, biomedical, and other industrial applications. Elseiver.
- [2] Heimann, K., & Huerlimann, R. (2015). Microalgal
Classification: Major Classes and Genera of Commercial Microalgal Species. In S-K. Kim, (Ed.),
Handbook of marine microalgae: Biotechnology advances (pp. 25–41). Elseiver. [CrossRef]
- [3] García J. L., de Vicente M., & Galán B. (2017). Microalgae, old sustainable food and fashion nutraceuticals. Microb Biotechnol, 10(5), 979–1274. [CrossRef]
- [4] Onen Cinar, S., Chong, Z. K., Kucuker, M. A., Wieczorek, N., Cengiz, U., & Kuchta, K. (2020). Bioplastic production from microalgae: A review. International Journal of Environmental Research and Public
Health, 17(11), Article 3842. [CrossRef]
- [5] Gottenbos, B., Grijpma, D. W., Van Der Mei, H.
C., Feijen, J., & Busscher, H. J. (2001). Antimicrobial effects of positively charged surfaces on adhering Gram-positive and Gram-negative bacteria. Journal of Antimicrobial Chemotherapy, 48(1),
7–13. [CrossRef]
- [6] Singh, V., & Mishra, V. (2020). Enhanced biomass
production and nutrient removal efficiency from
urban wastewater by Chlorella pyrenoidosa in
batch bioreactor system: optimization and model simulation. Desalination and Water Treatment,
197, 52–66. [CrossRef]
- [7] Talluri, S. N. L., Winter, R. M., & Salem, D. R.
(2020). Conditioning film formation and its influence on the initial adhesion and biofilm formation
by a cyanobacterium on photobioreactor materials.
Biofouling, 36(2), 183–199. [CrossRef]
- [8] Ozkan, A., & Berberoglu, H. (2013). Physico-chemical surface properties of microalgae. Colloids and
Surfaces B: Biointerfaces, 112, 287–293. [CrossRef]
- [9] Yu, L., Schlaich, C., Hou, Y., Zhang, J., Michael
Noeske, P-L., & Haag, R. (2018). Photoregulating
antifouling and bioadhesion functional coating
surface based on spiropyran. Chemistry, 24(30)
7531–7780. [CrossRef]
- [10] Stafslien S. J., Bahr, J. B., Daniels, J., Christianson, D.
A., Chisholm, B. J. (2011). High-throughput screening of fouling-release properties: An overview.
Journal of Adhesion Science and Technology, 25(17),
2239–2253. [CrossRef]
- [11] Majumdar, P. (2011). Combinatorial materials research applied to the development of new surface
coatings XV: An investigation of polysiloxane anti-fouling/fouling-release coatings containing tethered quaternary ammonium salt groups. ACS Combinatorial Science, 13, 298–309. [CrossRef]
- [12] Wu, Z., Zhai, L., Cohen, R.E., Rubner, M. F. (2006).
Nanoporosity-driven superhydrophilicity: A means
to create multifunctional antifogging coatings.
Langmuir, 22, 2856–2862. [CrossRef]
- [13] Topcu Kaya, A. S., Cengiz, U. (2019). Progress in
Organic Coatings Fabrication and application of
superhydrophilic antifog surface by sol-gel method.
Progress in Organic Coatings, 126, 75–82. [CrossRef]
- [14] Koschitzki, F., Wanka, R., Sobota, L., Koc, J., Gardner, H., Hunsucker, K. Z., Swain, G. W., & Rosenhahn, A. (2020). Amphiphilic dicyclopentenyl/
carboxybetaine-containing copolymers for marine
fouling-release applications. ACS Applied Materials
and Interfaces, 12, 34148–34160. [CrossRef]
- [15] Erbil, H. Y. (2006). Surface chemistry of solid and liquid interfaces. Blackwell Publishing. [CrossRef]
- [16] Rudawska, A., & Jacniacka, E. (2018). Evaluating
uncertainty of surface free energy measurement by
the van Oss-Chaudhury- Good method. International Journal of Adhesion and Adhesives, 82, 139–
145. [CrossRef]
- [17] Panja, B., Das, S. K., Sahoo, P. (2016). Tribological
behavior of electroless Ni-P coatings in various corrosive Environments. Surface Review and Letters,
23(5), 1–18. [CrossRef]
- [18] Miller, K. R., & Soucek, M. D. (2012). Photopolymerization of biocompatible films containing poly
(lactic acid). European Polymer Journal, 48(12),
2107–2116. [CrossRef]