[{“box”:0,”content”:”[if 992 equals=”Open Access”]
Open Access
n
[/if 992]n
n
n
n
n
- n t
n
Gaurav Verma, Kamal Sharma, Aayush Gupta
[/foreach]
n
n
n[if 2099 not_equal=”Yes”]n
- [foreach 286] [if 1175 not_equal=””]n t
- Research Scholar, Professor, Assistant Professor, Department of Mechanical Engineering, GLA University, Mathura, Department of Mechanical Engineering, GLA University, Mathura, Department of Mechanical Engineering, GLA University, Mathura, Uttar Pradesh, Uttar Pradesh, Uttar Pradesh, India, India, India
n[/if 1175][/foreach]
[/if 2099][if 2099 equals=”Yes”][/if 2099]nn
Abstract
nThe hydrophobic effects of Al₂O₃ coatings on glass slides are investigated in this work by comparing dip and spray procedures using three distinct solvents: acetone, polyvinyl alcohol (PVA), and ethanol. Using both dip and spray techniques, the experimental design systematically applies Al₂O₃ coatings on glass slides. Then, the effect of the chosen solvents on hydrophobicity is investigated. Delineating the complex interaction between coating processes and solvent options requires careful analysis of each solvent and regulated application. Measuring the hydrophobicity of coated glass surfaces, which includes the contact angle, allows for quantitative insights into their water-repellent characteristics. Coating efficiency, homogeneity, and the consequent hydrophobic properties are all part of the comparison examination. The study’s findings assist in choosing the best methods for customizing hydrophobic characteristics on glass surfaces for various uses and add to our knowledge of surface modification procedures in general.
n
Keywords: Hydrophobic Glass Slides; Dip Technique; Spray Technique; Hydrophobicity Assessment; solvent
n[if 424 equals=”Regular Issue”][This article belongs to Journal of Polymer and Composites(jopc)]
n
n
n
n
n
n
n[if 992 equals=”Open Access”] Full Text PDF Download[/if 992] nn
n[if 379 not_equal=””]nBrowse Figures
n
n[/if 379]n
References
n[if 1104 equals=””]n
- Wang, Q., Xu, S., Xing, X., & Wang, N. (2021). Progress in fabrication and applications of micro/nanostructured superhydrophobic surfaces. Surface Innovations, 10(2), 89-110.
- Nomeir, B., Lakhouil, S., Boukheir, S., Ali, M. A., & Naamane, S. (2023). Recent progress on transparent and self-cleaning surfaces by superhydrophobic coatings deposition to optimize the cleaning process of solar panels. Solar Energy Materials and Solar Cells, 257, 112347.
- Heale, F. L. (2020). Special Wettability Coatings, Films and Slippery Liquid Infused Porous Surfaces with Self-cleaning, Anti-icing and Anti-fogging Applications(Doctoral dissertation, UCL (University College London)).
- Ly, M. (2020). Hydrophobic Modifications of Cellulose Nanocrystals for Anticorrosion and Polymer Coating Applications(Master’s thesis, University of Waterloo).
- Jiang, K., Li, F., Zhao, X., & Pan, Y. (2022). Eco-friendly dopamine-modified silica nanoparticles for oil-repellent coatings: implications for underwater self-cleaning and antifogging applications. ACS Applied Nano Materials, 5(6), 8038-8047.
- Chakraborty, A., Mulroney, A. T., & Gupta, M. C. (2021). Superhydrophobic surfaces by microtexturing: a critical review. Progress in Adhesion and Adhesives, 6, 621-649.
- Sheikh, M., Pazirofteh, M., Dehghani, M., Asghari, M., Rezakazemi, M., Valderrama, C., & Cortina, J. L. (2020). Application of ZnO nanostructures in ceramic and polymeric membranes for water and wastewater technologies: a review. Chemical Engineering Journal, 391, 123475.
- Niculescu, A. G., Chircov, C., Bîrcă, A. C., & Grumezescu, A. M. (2021). Nanomaterials synthesis through microfluidic methods: an updated overview. Nanomaterials, 11(4), 864.
- Pakzad, H., Nouri-Borujerdi, A., & Moosavi, A. (2022). Drag reduction ability of slippery liquid-infused surfaces: A review. Progress in Organic Coatings, 170, 106970.
- Onggar, T., Kruppke, I., & Cherif, C. (2020). Techniques and processes for the realization of electrically conducting textile materials from intrinsically conducting polymers and their application potential. Polymers, 12(12), 2867.
- Žukauskas, S. K., Švažas, E., Linkevičius, T., & Misevičius, M. (2020). Comparison of two different healing abutment cleaning protocols. In NBCM 2020: international conference on nanostructured bioceramic materials, 1-3 December 2020, Vilnius, Vilnius University: conference book. Vilniaus universiteto leidykla.
- Seok, S. H. (2023). Processing of Two-Dimensional Titanium Carbide MXenes for Multifunctional and Scalable Coatings.
- Xing, J., Li, J., Fan, W., Zhao, T., Chen, X., Li, H., … & Zhao, Y. (2022). A review on nanofibrous separators towards enhanced mechanical properties for lithium-ion batteries. Composites Part B: Engineering, 110105.
- Rashid, S. H. (2020). Synthesis, Characterisation and Corrosion Protection Performance of Hybrid Nanocomposite Coatings. The University of Manchester (United Kingdom).
- Mussa, M. (2020). Development of Hybrid Sol-Gel Coatings on AA2024-T3 with Environmentally Benign Corrosion Inhibitors. Sheffield Hallam University (United Kingdom).
- Wang, Q., Sun, G., Tong, Q., Yang, W., & Hao, W. (2021). Fluorine-free superhydrophobic coatings from polydimethylsiloxane for sustainable chemical engineering: Preparation methods and applications. Chemical Engineering Journal, 426, 130829.
- Xing, D., Wu, F., Wang, R., Zhu, J., & Gao, X. (2019). Microdrop-assisted microdomain hydrophilicization of superhydrophobic surfaces for high-efficiency nucleation and self-removal of condensate microdrops. ACS applied materials & interfaces, 11(7), 7553-7558.
- Jannatun, N., Taraqqi-A-Kamal, A., Rehman, R., Kuker, J., & Lahiri, S. K. (2020). A facile cross-linking approach to fabricate durable and self-healing superhydrophobic coatings of SiO2-PVA@ PDMS on cotton textile. European Polymer Journal, 134, 109836.
- Kumar, A., Ryparová, P., Hosseinpourpia, R., Adamopoulos, S., Prošek, Z., Žigon, J., & Petrič, M. (2019). Hydrophobicity and resistance against microorganisms of heat and chemically crosslinked poly (vinyl alcohol) nanofibrous membranes. Chemical Engineering Journal, 360, 788-796.
- Celik, N., Kiremitler, N. B., Ruzi, M., & Onses, M. S. (2021). Waxing the soot: Practical fabrication of all-organic superhydrophobic coatings from candle soot and carnauba wax. Progress in Organic Coatings, 153, 106169.
- Meena, M. K., Sinhamahapatra, A., & Kumar, A. (2019). Superhydrophobic polymer composite coating on glass via spin coating technique. Colloid and Polymer Science, 297, 1499-1505.
- Chen, J., Yuan, L., Shi, C., Wu, C., Long, Z., Qiao, H., … & Fan, Q. H. (2021). Nature-inspired hierarchical protrusion structure construction for washable and wear-resistant superhydrophobic textiles with self-cleaning ability. ACS Applied Materials & Interfaces, 13(15), 18142-18151.
- Mani, K. A., Belausov, E., Zelinger, E., & Mechrez, G. (2022). Durable superhydrophobic coating with a self-replacing mechanism of surface roughness based on multiple Pickering emulsion templating. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 652, 129899.
- Abu-Thabit, N. Y., Uwaezuoke, O. J., & Elella, M. H. A. (2022). Superhydrophobic nanohybrid sponges for separation of oil/water mixtures. Chemosphere, 294, 133644.
- Hamdi, A., Chalon, J., Laurent, P., Dodin, B., Dogheche, E., & Champagne, P. (2021). Facile synthesis of fluorine-free, hydrophobic, and highly transparent coatings for self-cleaning applications. Journal of Coatings Technology and Research, 18(3), 807-818.
- Rasouli, S., Rezaei, N., Hamedi, H., Zendehboudi, S., & Duan, X. (2021). Superhydrophobic and superoleophilic membranes for oil-water separation application: A comprehensive review. Materials & Design, 204, 109599.
- Kim, H., Lee, S., Shin, Y. R., Choi, Y. N., Yoon, J., Ryu, M., … & Lee, H. (2021). Durable superhydrophobic poly (vinylidene fluoride) (PVDF)-based nanofibrous membranes for reusable air filters. ACS Applied Polymer Materials, 4(1), 338-347.
Aparna, A., Sethulekshmi, A. S., Saritha, A., & Joseph, K. (2022). Recent advances in superhydrophobic epoxy-based nanocomposite coatings and their applications. Progress in Organic Coatings, 166, 106819.
nn[/if 1104][if 1104 not_equal=””]n
- [foreach 1102]n t
- [if 1106 equals=””], [/if 1106][if 1106 not_equal=””],[/if 1106]
n[/foreach]
n[/if 1104]
nn
nn[if 1114 equals=”Yes”]n
n[/if 1114]
n
n
n
| Volume | ||
| [if 424 equals=”Regular Issue”]Issue[/if 424][if 424 equals=”Special Issue”]Special Issue[/if 424] [if 424 equals=”Conference”][/if 424] | ||
| Received | January 16, 2024 | |
| Accepted | February 11, 2024 | |
| Published | April 15, 2024 |
n
n
n
n
n
nn function myFunction2() {n var x = document.getElementById(“browsefigure”);n if (x.style.display === “block”) {n x.style.display = “none”;n }n else { x.style.display = “Block”; }n }n document.querySelector(“.prevBtn”).addEventListener(“click”, () => {n changeSlides(-1);n });n document.querySelector(“.nextBtn”).addEventListener(“click”, () => {n changeSlides(1);n });n var slideIndex = 1;n showSlides(slideIndex);n function changeSlides(n) {n showSlides((slideIndex += n));n }n function currentSlide(n) {n showSlides((slideIndex = n));n }n function showSlides(n) {n var i;n var slides = document.getElementsByClassName(“Slide”);n var dots = document.getElementsByClassName(“Navdot”);n if (n > slides.length) { slideIndex = 1; }n if (n (item.style.display = “none”));n Array.from(dots).forEach(n item => (item.className = item.className.replace(” selected”, “”))n );n slides[slideIndex – 1].style.display = “block”;n dots[slideIndex – 1].className += ” selected”;n }n”}]