Investigations on the texture and corrosion characteristics of AA5083 alloy reinforced with CeO₂ by friction stir processing

1 Rasouli, S.; Behnagh, R. A.; Dadvand, A.; Saleki-Haselghoubi, N., Improvement in corrosion resistance of 5083 aluminum alloy via friction stir processing. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications 2016, 230 (1), 142-150. Search in Google Scholar

2 Moldovan, P.; Stanica, C. N.; Ciobanu, G.; Ungureanu, I.; Iorga, G. M.; Buţu, M., Intergranular corrosion of AA 5083-H321 aluminum alloy. UPB Sci Bull Ser B 2014, 76 (3), 169-80. Search in Google Scholar

3 Amra, M.; Ranjbar, K.; Dehmolaei, R., Mechanical properties and corrosion behavior of CeO2 and SiC incorporated Al5083 alloy surface composites. Journal of Materials Engineering and Performance 2015, 24, 3169-3179. Search in Google Scholar

4 Huang, C.; Wu, Z.; Huang, R.; Wang, W.; Li, L., Mechanical Properties of AA5083 in Different Tempers at Low Temperatures, IOP Conf. Series: Materials Science and Engineering 2017, 279. Search in Google Scholar

5 Vignesh, R. V.; Padmanaban, R., Intergranular corrosion susceptibility of friction stir processed aluminium alloy 5083. Materials today: proceedings 2018, 5 (8), 16443-16452. Search in Google Scholar

6 Prabhakar, G.; Kumar, N. R.; Sunil, B. R., Surface metal matrix composites of Al5083-fly ash produced by friction stir processing. Materials Today: Proceedings 2018, 5 (2), 8391-8397. Search in Google Scholar

7 Jain, V. K. S.; Yazar, K.; Muthukumaran, S., Development and characterization of Al5083-CNTs/SiC composites via friction stir processing. Journal of Alloys and Compounds 2019, 798, 82-92. Search in Google Scholar

8 Behnagh, R. A.; Shen, N.; Abdollahi, M.; Ding, H., Ultrafine-grained surface layer formation of aluminum alloy 5083 by friction stir processing. Procedia CIRP 2016, 45, 243-246. Search in Google Scholar

9 Ashraf, P. M.; Shibli, S., Reinforcing aluminium with cerium oxide: A new and effective technique to prevent corrosion in marine environments. Electrochemistry Communications 2007, 9 (3), 443-448. Search in Google Scholar

10 Jain, V. K.; Yadav, M. K.; Saxena, A.; Siddiquee, A. N.; Khan, Z. A., Effect of tool rotational speed on microstructure and mechanical properties of friction stir processed AA5083/Fe-Al in-situ composite. Materials Today: Proceedings 2021, 46, 6496-6500. Search in Google Scholar

11 El-Danaf, E. A.; El-Rayes, M. M.; Soliman, M. S., Friction stir processing: an effective technique to refine grain structure and enhance ductility. Materials & Design 2010, 31 (3), 1231-1236. Search in Google Scholar

12 Huang, K.-T.; Lui, T.-S.; Chen, L.-H., Effect of microstructural feature on the tensile properties and vibration fracture resistance of friction stirred 5083 Alloy. Journal of alloys and compounds 2011, 509 (27), 7466-7472. Search in Google Scholar

13 García-Bernal, M.; Mishra, R.; Hernández-Silva, D.; Sauce-Rangel, V., Microstructural homogeneity and hot deformation of various friction-stir-processed 5083 Al Alloys. Journal of Materials Engineering and Performance 2017, 26, 460-464. Search in Google Scholar

14 Hayashi, J.; Sarath Menon, E.; Su, J.; McNelley, T. R., Friction stir processing (FSP) of as-Cast AA5083 for grain refinement and superplasticity. Key Engineering Materials 2010, 433, 135-140. Search in Google Scholar

15 Rahman, Z.; Siddiquee, A. N.; Khan, Z. A. In Effect of Ti/SiC Reinforcement on AA5083 Surface Composites Prepared by Friction Stir Processing, IOP Conference Series: Materials Science and Engineering, IOP Publishing: 2021; p 012001. Search in Google Scholar

16 Zohoor, M.; Givi, M. B.; Salami, P., Effect of processing parameters on fabrication of Al–Mg/Cu composites via friction stir processing. Materials & Design 2012, 39, 358-365. Search in Google Scholar

17 Amra, M.; Ranjbar, K.; Hosseini, S., Microstructure and wear performance of Al5083/CeO2/SiC mono and hybrid surface composites fabricated by friction stir processing. Transactions of Nonferrous Metals Society of China 2018, 28 (5), 866-878. Search in Google Scholar

18 Jannet, S.; Raja, R.; Jaio, M. G.; Manohar, B., Synthesis and characterization of sic/Al2O3 reinforced aa5083 metal matrix composite by friction stir processing. Int. J. Recent Technol. Eng 2019, 7, 629-634. Search in Google Scholar

19 Ikumapayi, O. M.; Akinlabi, E. T.; Pal, S. K.; Majumdar, J. D., A survey on reinforcements used in friction stir processing of aluminium metal matrix and hybrid composites. Procedia Manufacturing 2019, 35, 935-940. Search in Google Scholar

20 Vaira Vignesh, R.; Padmanaban, R.; Datta, M., Influence of FSP on the microstructure, microhardness, intergranular corrosion susceptibility and wear resistance of AA5083 alloy. Tribology-Materials, Surfaces & Interfaces 2018, 12 (3), 157-169. Search in Google Scholar

21 Mishra, R. S.; Ma, Z., Friction stir welding and processing. Materials science and engineering: R: reports 2005, 50 (1-2), 1-78. Search in Google Scholar

22 Suganya Priyadharshini, G.; Satish Kumar, T.; Anbuchezhian, N.; Vaira Vignesh, R.; Subramanian, R.; Velmurugan, T.; Kamal Basha, K., Influence of tool traverse speed on microstructure and mechanical properties of CuNi/B4C surface composites. Transactions of the IMF 2021, 99 (1), 38-45. Search in Google Scholar

23 Węglowski, M. S., Friction stir processing – state of the art. Archives of civil and Mechanical Engineering 2018, 18, 114-129. Search in Google Scholar

24 Han, J.; Paidar, M.; Vignesh, R. V.; Mehta, K. P.; Heidarzadeh, A.; Ojo, O., Effect of shoulder features during friction spot extrusion welding of 2024-T3 to 6061-T6 aluminium alloys. Archives of Civil and Mechanical Engineering 2020, 20, 1-17. Search in Google Scholar

25 Samuel Ratna Kumar, P.; Vaira Vignesh, R.; Mashinini, P.; Ramanathan, S., Tribological behavior of friction stir process surface hybrid composite AA5083/MWCNT/Al2SiO5 using multi-quadratic RBF algorithm. Carbon Letters 2023, 1-15. Search in Google Scholar

26 Kurt, A.; Uygur, I.; Cete, E., Surface modification of aluminium by friction stir processing. Journal of materials processing technology 2011, 211 (3), 313-317. Search in Google Scholar

27 Luo, J.; Liu, S.; Paidar, M.; Vignesh, R. V.; Mehrez, S., Enhanced mechanical and tribological properties of AA6061/CeO2 composite fabricated by friction stir processing. Materials Letters 2022, 318, 132210. Search in Google Scholar

28 Shahraki, S.; Khorasani, S.; Abdi Behnagh, R.; Fotouhi, Y.; Bisadi, H., Producing of AA5083/ZrO2 nanocomposite by friction stir processing (FSP). Metallurgical and Materials Transactions B 2013, 44, 1546-1553. Search in Google Scholar

29 Li, H.; Paidar, M.; Ojo, O. O.; Vignesh, R. V.; Iswandi, I.; Mehrez, S.; Zain, A. M.; Mohanavel, V., Effect of tool profile on wear and mechanical behaviors of CeO2 and ZrO2-reinforced hybrid magnesium matrix composite developed via FSP technique. Journal of Manufacturing Processes 2023, 94, 297-315. Search in Google Scholar

30 Choi, D.-H.; Ahn, B.-W.; Quesnel, D. J.; Jung, S.-B., Behavior of β phase (Al3Mg2) in AA 5083 during friction stir welding. Intermetallics 2013, 35, 120-127. Search in Google Scholar