The Influence of Laser Impact on Wettability of Brass Surface

The Influence of Laser Impact on Wettability of Brass Surface

  IJETT-book-cover  International Journal of Engineering Trends and Technology (IJETT)          
  
© 2020 by IJETT Journal
Volume-68 Issue-11
Year of Publication : 2020
Authors : A.V. Ryzhenkov, M.R. Dasaev, S.V. Grigoriev, E.M. Tyabut, E.S. Trushin
DOI :  10.14445/22315381/IJETT-V68I11P204

Citation 

MLA Style: A.V. Ryzhenkov, M.R. Dasaev, S.V. Grigoriev, E.M. Tyabut, E.S. Trushin  "The Influence of Laser Impact on Wettability of Brass Surface" International Journal of Engineering Trends and Technology 68.11(2020):25-32. 

APA Style:A.V. Ryzhenkov, M.R. Dasaev, S.V. Grigoriev, E.M. Tyabut, E.S. Trushin. The Influence of Laser Impact on Wettability of Brass Surface  International Journal of Engineering Trends and Technology, 68(11),25-32.

Abstract
This work discusses the influence of modification of brass surfaces using laser equipment on wettability properties; wetting and roll-off angles on modified surfaces were determined and analyzed as a function of laser radiation parameters and atomic composition. The most energy efficient hydrophobic surfaces characterized by the wetting angle of 149° and the roll-off angle of 3°, as well as the wetting angle of 147° and the roll-off angle of 2°, were obtained upon modification of brass surface at laser power of 15 W and 20 W, respectively, and beam speed of 100 mm/s, forming relief in the form of equidistant by 100 ?m lines.

Reference

[1] A.H. Alamri. Localized corrosion and mitigation approach of steel materials used in oil and gas pipelines – An overview, Engineering Failure Analysis. 116 (2020) 104735.
[2] A.V. Pridatko, A.V. Mironyuk, and V.A. Sviderskii, Analiz podkhodov k matematicheskomu opisaniyu kharakteristik materialov s povyshennoi gidrofobnost`yu [Analysis of approaches to mathematical description of materials with higher hydrophobicity], Vostochno-Evropeiskii zhurnal peredovykh tekhnologii, 2 5(77) (2015) 30-41.
[3] M. Liravi, H. Pakzad, A. Moosavi, and A. Nouri-Borujerdi, “A comprehensive review on recent advances in superhydrophobic surfaces and their applications for drag reduction”, Progress in Organic Coatings, Vol. 140, 105537, 2020.
[4] A.V. Ryzhenkov, M.R. Dasaev, and S.V. Grigor`ev, Ispol`zovanie lazernogo oborudovaniya s tsel`yu povysheniya effektivnosti i nadezhnosti truboprovodov [Using laser equipment for improvement of efficiency and reliability of pipelines], in Advanced innovative developments. Challenges and experience, issues of commercial implementation. Proceedings: 9th International Conference, October 31, 2019, Part 1, pp. 176-180.
[5] M. Langer, and D. Otto, Metody issledovaniya poverkhnostnykh kharakteristik polimerov posle plazmennoi obrabotki [Studying surface properties of polymers after plasm treatment], Analitika, Vol. 8, No. 2(39) (2018) 68-74.
[6] X. Zhang, and Y. Qin, Contact angle hysteresis of a water droplet on a hydrophobic fuel cell surface, Journal of Colloid and Interface Science. 545 (2019) 231-241.
[7] L.B. Boinovich, and A.M. Emel`yanenko, Gidrofobnye materialy i pokrytiya: printsipy sozdaniya, svoistva i primenenie [Hydrophobic materials and coatings: principles of development, properties and application], Uspekhi khimii, 77(7) (2008) 619-638.
[8] M.-J. Chuang, and A.-K. Chu, Formation of a high hydrophilic/hydrophobic contrast surface on PET substrates by ECR generated sulfur hexafluoride plasma, Applied Surface Science. 257(9) (2011) 3943-3947.
[9] Ch. Ma, L. Wang, A. Nikiforov, Yu. Onyshchenko, P. Cools, K. Ostrikov, N.D. Geyter, and R. Morent, Atmospheric-pressure plasma assisted engineering of polymer surfaces: From high hydrophobicity to superhydrophilicity, Applied Surface Science, 535 (2020) 147032.
[10] K. Ravi, W. Lock Sulen, Ch. Bernard, Y. Ichikawa, and K. Ogawa, Fabrication of micro-/nano-structured super-hydrophobic fluorinated polymer coatings by cold-spray”, Surface and Coatings Technology. 373 (2019) 17-24.
[11] Sh. Wang, Y. Xue, Ch. Ban, Y. Xue, A. Taleb, and Y. Jin, Fabrication of robust tungsten carbide particles reinforced Co-Ni super-hydrophobic composite coating by electrochemical deposition, Surface and Coatings Technology, 385 (2020) 125390.
[12] Zh. Yang, X. Liu, and Y. Tian, Novel metal-organic super-hydrophobic surface fabricated by nanosecond laser irradiation in solution, Colloids and Surfaces A: Physicochemical and Engineering Aspects. (2019) 587, 124343.
[13] G.B. Shirsath, K. Muralidhar, R.G.S. Pala, and J. Ramkumar, Condensation of water vapor underneath an inclined hydrophobic textured surface machined by laser and electric discharge, Applied Surface Science, 484 (2019) 999-1009.
[14] D. Huerta-Murillo, A.I. Aguilar-Morales, S. Alamri, J.T. Cardoso, R. Jagdheesh, A.F. Lasagni, and J.L. Ocaña, Fabrication of multi-scale periodic surface structures on Ti-6Al-4V by direct laser writing and direct laser interference patterning for modified wettability applications, Optics and Lasers in Engineering, 98 (2017) 134-142.
[15] H. Yan, M.R.B. Abdul Rashid, S.Y. Khew, F. Li, and M. Hong. “Wettability transition of laser textured brass surfaces inside different mediums”, Applied Surface Science. 427, Part B (2018) 369-375.

Keywords
hydrophobicity, laser texturing, L63 brass, wetting angle, roll-off angle, relief