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Gudze, M.; Melchers, R., Operational based corrosion analysis in naval ships. Corrosion science2008,50 (12), 3296-3307.Search in Google Scholar
Jinglei, Z.; Keliang, S.; Xiuming, H.; Jiande, Y.; Shujie, P., Cathodic protection of A1 hull ship. Chinese Journal of Oceanology and Limnology1990,8, 257-262.Search in Google Scholar
Seymour, A. J., Cathodic protection for corrosion control of ships and other steel structures in seawater. Anti-Corrosion Methods and Materials1990.Search in Google Scholar
Xu, L.; Xin, Y.; Ma, L.; Zhang, H.; Lin, Z.; Li, X., Challenges and solutions of cathodic protection for marine ships. Corrosion Communications2021,2, 33-40.Search in Google Scholar
Bellezze, T.; Fratesi, R.; Roventi, G., Cathodic protection of a ship propeller shaftby impressed current anodes. La Metallurgia Italiana2014.Search in Google Scholar
Bulatović, S.; Aleksić, V.; Zečević, B., Corrosion protection of ship structures Zaštita od korozije brodskih konstrukcija. PROCEEDINGS KNJIGA RADOVA2021, 177.Search in Google Scholar
Hossen, A.; Mahmud, R.; Islam, A., Minimization of corrosion in aquatic environment – a review. Int J Hydro2023,7 (1), 9-16.Search in Google Scholar
Nazari, M. H.; Zhang, Y.; Mahmoodi, A.; Xu, G.; Yu, J.; Wu, J.; Shi, X., Nanocomposite organic coatings for corrosion protection of metals: A review of recent advances. Progress in Organic Coatings2022,162, 106573.Search in Google Scholar
Thomas, D.; Philip, E.; Sindhu, R.; Ulaeto, S. B.; Pugazhendhi, A.; Awasthi, M. K., Developments in smart organic coatings for anticorrosion applications: a review. Biomass Conversion and Biorefinery2022,12 (10), 4683-4699.Search in Google Scholar
Govindaraju, M.; Vignesh, R. V.; Padmanaban, R., Effect of heat treatment on the microstructure and mechanical properties of the friction stir processed AZ91D magnesium alloy. Metal Science and Heat Treatment2019,61 (5-6), 311-317.Search in Google Scholar
Gusieva, K.; Davies, C.; Scully, J.; Birbilis, N., Corrosion of magnesium alloys: the role of alloying. International Materials Reviews2015,60 (3), 169-194.Search in Google Scholar
Balan, P.; Thiagarajan, V.; Ganesan, S. P.; Raghunathan, V.; Shankar, K. V.; Kumar, B. Y.; Ramalingam, V. V., Characterization of powder metallurgy processed magnesium alloys for biomedical implants. Emergent Materials2023,6 (2), 573-581.Search in Google Scholar
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 Processes2023,94, 297-315.Search in Google Scholar
Paidar, M.; Bokov, D.; Mehrez, S.; Ojo, O. O.; Ramalingam, V. V.; Memon, S., Improvement of mechanical and wear behavior by the development of a new tool for the friction stir processing of Mg/B4C composite. Surface and Coatings Technology2021,426, 127797.Search in Google Scholar
Meifeng, H.; Lei, L.; Yating, W.; Zhixin, T.; Wenbin, H., Corrosion properties of surface-modified AZ91D magnesium alloy. Corrosion science2008,50 (12), 3267-3273.Search in Google Scholar
Candan, S.; Unal, M.; Turkmen, M.; Koc, E.; Turen, Y.; Candan, E., Improvement of mechanical and corrosion properties of magnesium alloy by lead addition. Materials Science and Engineering: A2009,501 (1-2), 115-118.Search in Google Scholar
Ezhilselvi, V.; Nithin, J.;Balaraju, J.; Subramanian, S., The influence of current density on the morphology and corrosion properties of MAO coatings on AZ31B magnesium alloy. Surface and Coatings Technology2016,288, 221-229.Search in Google Scholar
Liang, J.; Hu, L.; Hao, J., Improvement of corrosion properties of microarc oxidation coating on magnesium alloy by optimizing current density parameters. Applied Surface Science2007,253 (16), 6939-6945.Search in Google Scholar
Razzaghi, M.; Mirzadeh, H.; Emamy, M., Mechanical properties of Mg–Al–Mn magnesium alloys with low Al content in the as-cast and extruded conditions. Materials Research Express2019,6 (10), 106521.Search in Google Scholar
Reza Kashyzadeh, K.; Amiri, N.; Maleki, E.; Unal, O., A Critical Review on Improving the Fatigue Life and Corrosion Properties of Magnesium Alloys via the Technique of Adding Different Elements. Journal of Marine Science and Engineering2023,11 (3), 527.Search in Google Scholar
Yao, C.; Wang, Z.; Tay, S. L.; Zhu, T.; Gao, W., Effects of Mg on microstructure and corrosion properties of Zn–Mg alloy. Journal of Alloys and Compounds2014,602, 101-107.Search in Google Scholar
Ramalingam, V. V.; Ramasamy, P.; Kovukkal, M. D.; Myilsamy, G., Research and development in magnesium alloys for industrial and biomedical applications: a review. Metals and Materials International2020,26, 409-430.Search in Google Scholar
Vaira Vignesh, R.; Padmanaban, R.; Govindaraju, M.; Suganya Priyadharshini, G., Investigations on the corrosion behaviour and biocompatibility of magnesium alloy surface composites AZ91D-ZrO2 fabricated by friction stir processing. Transactions of the IMF2019,97 (5), 261-270.Search in Google Scholar
Vignesh, R. V.; Padmanaban, R.; Govindaraju, M., Investigations on the surface topography, corrosion behavior, and biocompatibility of friction stir processed magnesium alloy AZ91D. Surface Topography: Metrology and Properties2019,7 (2), 025020.Search in Google Scholar
Vignesh, R. V.; Padmanaban, R.; Govindaraju, M.; Priyadharshini, G. S., Mechanical properties and corrosion behaviour of AZ91D-HAP surface composites fabricated by friction stir processing. Materials Research Express2019,6 (8), 085401.Search in Google Scholar
Loto, C. A.; Loto, R. T.; Popoola, A. P., Cathodic protection performance evaluation of magnesium anodes on mild steel corrosion in 0.5MH2SO4 and seawater environments. Journal of Bio-and Tribo-Corrosion2019,5, 1-7.Search in Google Scholar
Azzeddine, H.; Hanna, A.; Dakhouche, A.; Rabahi, L.; Scharnagl, N.; Dopita, M.; Brisset, F.; Helbert, A.-L.; Baudin, T., Impact of rare-earth elements on the corrosion performance of binary magnesium alloys. Journal of Alloys and Compounds2020,829, 154569.Search in Google Scholar
Sanmiguel-May, J. A.; López-Alcantara, R.; Juárez-Arellano, E. A.; Pérez-Quiroz, J. T.; Contreras, A.; Pérez-López, T., Performance Assessment of Magnesium Anodes Manufactured by Sintering Process. Metals2021,11 (3), 406.Search in Google Scholar
Zidane, N.; Albrimi, Y. A.; Addi, A. A.; Douch, J.; Souto, R.; Hamdani, M., Evaluation of the corrosion of AZ31 magnesium alloy used as sacrificial anode for cathodic protection of hot-water tank storage containing chloride. Int. J. Electrochem. Sci2018,13, 29-44.Search in Google Scholar
Rzychoń, T.; Michalska, J.; Kiełbus, A., Corrosion resistance of Mg-RE-Zr alloys. Journal of Achievements in Materials and Manufacturing Engineering2007,21 (1), 51-54.Search in Google Scholar
Yasakau, K.; Bastos, A.; Haffner, D.; Quandt, E.; Feyerabend, F.; Ferreira, M.; Zheludkevich, M., Sacrificial protection of Mg-based resorbable implant alloy by magnetron sputtered Mg5Gd alloy coating: A short-term study. Corrosion Science2021,189, 109590.Search in Google Scholar
Umoru, L.; Ige, O., Effects of tin on aluminum–zinc–magnesium alloy as sacrificial anode in seawater. Journal of Minerals & Materials Characterization & Engineering2007,7 (2), 105-113.Search in Google Scholar
Quevedo, M.; Genesca, J., Influence of turbulent flow on the corrosion of Al–Zn–Mg galvanic anode in artificial seawater media. Materials and corrosion2009,60 (6), 424-430.Search in Google Scholar
Robinson, H.; George, P., Effect of alloying and impurity elements in magnesium alloy cast anodes. Corrosion1954,10 (6), 182-188.Search in Google Scholar
Sun, H.; Liu, L.; Li, Y.; Ma, L.; Yan, Y., The performance of Al–Zn–In–Mg–Ti sacrificial anode in simulated deep water environment. Corrosion science2013,77, 77-87.Search in Google Scholar
Abubakar, M.; Onimisi, M. A., Effect of Precipitation Hardening Treatment on Corrosion Behavior and Anodic Efficiency of Sacrificial Anode Produced from Recycled Al–Zn–Mg Alloy. Journal of Failure Analysis and Prevention2021,21 (4), 1212-1219.Search in Google Scholar
Pathak, S. S.; Mendon, S. K.; Blanton, M. D.; Rawlins, J. W., Magnesium-based sacrificial anode cathodic protection coatings (Mg-rich primers) for aluminum alloys. Metals2012,2 (3), 353-376.Search in Google Scholar
Sekar, P.; Sanna, N.; Desai, V., Enhancement of resistance to galvanic corrosion of ZE41 Mg alloy by equal channel angular pressing. Materials and Corrosion2020,71 (4), 571-584.Search in Google Scholar
Kajánek, D.; Hadzima, B.; Buhagiar, J.; Wasserbauer, J.; Jacková, M., Corrosion degradation of AZ31 magnesium alloy coated by plasma electrolytic oxidation. Transportation Research Procedia2019,40, 51-58.Search in Google Scholar
Muazu, A.; Aliyu, Y. S.; Abdulwahab, M.; Idowu Popoola, A. P., Sacrificial anode stability and polarization potential variation in a ternary Al–xZn–xMg alloy in a seawater-marine environment. Journal of Marine Science and Application2016,15, 208-213.Search in Google Scholar
Radhika, K.; Lakshminarayanan, A., An insight into the stress corrosion cracking resistance of friction stir processed and micro arc oxidation coated ZE41 grade magnesium alloy. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science2022,236 (2), 1255-1273.Search in Google Scholar
Ling, M.; Mehrez, S.; Vignesh, R. V.; Zain, A. M.; Paidar, M.; Kharche, N. A.; Mohanavel, V., Investigation on underwater friction stir processing of AZ-61 magnesium alloy. Materials Today Communications2023,36, 106885.Search in Google Scholar
Raj, V.; Sabarinath, S.; Ramalingam, V. V., Biodegradable Magnesium Alloy-Based Composites: Properties, Processing, and Surface Coatings – A Review. Transactions of the Indian Institute of Metals2023, 1-9.Search in Google Scholar
Song, G. L.; Atrens, A., Corrosion mechanisms of magnesium alloys. Advanced engineering materials1999,1 (1), 11-33.Search in Google Scholar