Abstract
In this paper, the electrochemical performances of Al 0.5-Mg 0.1-Sn (wt%), Al 0.5-Mg 0.1-Sn 0.05 In (wt%), Al 0.5-Mg 0.1-Sn 0.05 Ga (wt%) and Al 0.5-Mg 0.1-Sn 0.05 Bi (wt%) alloys were investigated through electrochemical techniques and microstructure observation in 4 M NaOH solution. The results indicate that Al 0.5-Mg 0.1-Sn 0.05 In (wt%) alloy has the best discharge performance among all alloys, followed by Al 0.5-Mg 0.1-Sn 0.05-Bi (wt%) alloy, both of which is better than Al 0.5 Mg 0.1-Sn 0.05-Ga (wt%) alloy. This is due to the fact that the addition of indium to the Al 0.5-Mg 0.1-Sn-based alloy improves the discharge activity of the alloy while increasing its anodic efficiency. Although the addition of gallium or bismuth to this alloy increases the discharge activity, it reduces the efficiency of the anode, especially the addition of gallium resulting in severe intergranular corrosion of the alloy anode.
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References
Mutlu R, Yazici B (2019) Copper-deposited aluminum anode for aluminum-air battery. J Solid State Electrochem 23(2):529–541
Ma Z, Li X (2011) The study on microstructure and electrochemical properties of Al-Mg-Sn-Ga-Pb alloy anode material for Al/AgO battery. J Solid State Electrochem 15(11-12):2601–2610
Li Q, Bjerrum N (2002) Aluminum as anode for energy storage and conversion: a review. J Power Sources 110(1):1–10
Liu Y, Sun Q, Li W, Adair KR, Li J, Sun X (2017) A comprehensive review on recent progress in aluminum-air batteries. Green Energy & Environment 2(3):246–277
Ma J, Wen J, Gao J, Li Q (2014) Performance of Al-1Mg-1Zn-0.1Ga-0.1Sn as anode for Al-air battery. Electrochim Acta 129:69–75
Egan DR, Ponce de León C, Wood RJK, Jones RL, Stokes KR, Walsh FC (2013) Developments in electrode materials and electrolytes for aluminium-air batteries. J Power Sources 236:293–310
Abedin SZE, Endres F (2004) Electrochemical behaviour of Al, Al-In and Al-Ga-In alloys in chloride solutions containing zinc ions. J Appl Electrochem 34(10):1071–1080
Gudić S, Radošević J, Smoljko I, Kliškić M (2005) Cathodic breakdown of anodic oxide film on Al and Al-Sn alloys in NaCl solution. Electrochim Acta 50(28):5624–5632
Sun Z, Lu H, Fan L, Hong Q, Leng J, Chen C (2015) Performance of Al-air batteries based on Al-Ga, Al-In and Al-Sn alloy electrodes. J Electrochem Soc 162(10):A2116–A2122
Mutlu R, Ateş S, Yazici B (2017) Al-6013-T6 and Al-7075-T7351 alloy anodes for aluminium-air battery. Int J Hydrog Energy 42(36):23315–23325
Ma J, Wen J, Ren F, Wang G, Xiong Y (2016) Electrochemical performance of Al-Mg-Sn based alloys as anode for Al-air battery. J Electrochem Soc 163(8):A1759–A1764
Kurt K, Diplas S, Walmsley JC, Nisancioglu K (2013) Effect of trace elements lead and tin on anodic activation of AA8006 aluminum sheet. J Electrochem Soc 160(11):C542–C552
Shayeb HAE, Wahab FMAE, Abedin SZE (2001) Effect of gallium ions on the electrochemical behaviour of Al, Al-Sn, Al-Zn and Al-Zn-Sn alloys in chloride solutions. Corros Sci 43(4):643–654
Flamini DO, Saidman SB, Bessone JB (2006) Aluminium activation produced by gallium. Corros Sci 48(6):1413–1425
Senel E, Nisancioglu K (2014) Role of dealloying on the electrochemical behaviour of aluminium alloyed with trace amounts of gallium. Corros Sci 85:436–444
Moghannibavilolyaei H, Arjomandi J (2015) Performance of Al-1Mg-1Zn-0.1Bi-0.02In as anode for the Al-AgO battery. RSC Adv 5(111):91273–91279
Bessone JB, Flamini DO, Saidman SB (2005) Comprehensive model for the activation mechanism of Al-Zn alloys produced by indium. Corros Sci 47(1):95–105
Jeffrey PW, Halliop W, Smith FN (1988) Aluminium anode alloy United States Patent 4751086
Rao BML, Scamans GM (1993) Proc 10th international seminar on primary and secondary battery technology applications, Deerfied Beach, Florida
Nestoridi M, Pletcher D, Wood RJK, Wang S, Jones RL, Stokes KR, Wilcockc I (2008) The study of aluminium anodes for high power density Al/air batteries with brine electrolytes. J Power Sources 178(1):445–455
Ma J, Wen J, Zhu H, Li Q (2015) Electrochemical performances of Al-0.5Mg-00.1Sn-0.02In alloy in different solutions for Al-air battery. J Power Sources 293:592–598
Ma J, Ren F, Wang G, Xiong Y, Li Y, Wen J (2017) Electrochemical performance of melt-spinning Al-Mg-Sn based anode alloys. Int J Hydrog Energy 42:11654–11661
Srinivasa M, Adapakaa SK, Neelakantan L (2017) Solubility effects of Sn and Ga on the microstructure and corrosion behavior of Al-Mg-Sn-Ga alloy anodes. J Alloys Compd 683:647–653
Liang R, Su Y, Sui XL, Gu DM, Huang GS, Wang ZB (2019) Effect of Mg content on discharge behavior of Al-0.05Ga-0.05Sn-0.05Pb-xMg alloy anode for aluminum-air battery. J Solid State Electrochem 23(1):53–62
Fan L, Lu H, Leng J, Sun Z (2015) Performance of Al-0.6Mg-0.05Ga-0.1Sn-0.1In as anode for Al-air battery in KOH electrolytes. J Electrochem Soc 162(14):A2623–A2627
Ma J, Wen J, Gao J, Li Q (2014) Performance of Al-0.5Mg-0.02Ga-0.1Sn-0.5Mn as anode for Al-air battery in NaCl solutions. J Power Sources 253:419–423
Li J, Zhang B, Wei Q, Wang N, Hou B (2017) Electrochemical behavior of Mg-Al-Zn-in alloy as anode materials in 3.5 wt.% NaCl solution. Electrochim Acta 238:156–167
Wang Q, Miao H, Xue Y, Sun S, Li S, Liu Z (2017) Performances of an Al-0.15 Bi-0.15 Pb-0.035 Ga alloy as an anode for Al-air batteries in neutral and alkaline electrolytes. RSC Adv 7(42):25838–25847
Moghanni-Bavil-Olyaei H, Arjomandi J (2016) Enhanced electrochemical performance of Al-0.9Mg-1Zn-0.1Mn-0.05Bi-0.02In fabricated from commercially pure aluminum for use as the anode of alkaline batteries. RSC Adv 6(33):28055–28062
Gudić S, Smoljko I, Kliškić M (2010) The effect of small addition of tin and indium on the corrosion behavior of aluminium in chloride solution. J Alloys Compd 505(1):54–63
Khireche S, Boughrara D, Kadri A, Hamadou L, Benbrahim N (2014) Corrosion mechanism of Al, Al-Zn and Al-Zn-Sn alloys in 3wt.% NaCl solution. Corros Sci 87:504–516
Xiong W, Qi GT, Guo XP, Lu ZL (2011) Anodic dissolution of Al sacrificial anodes in NaCl solution containing Ce. Corros Sci 53(4):1298–1303
Tang Y, Lu L, Roesky HW, Wang L, Huang B (2004) The effect of zinc on the aluminum anode of the aluminum–air battery. J Power Sources 138(1-2):313–318
Wang N, Wang R, Peng C, Feng Y, Chen B (2012) Effect of hot rolling and subsequent annealing on electrochemical discharge behavior of AP65 magnesium alloy as anode for seawater activated battery. Corros Sci 64:17–27
Abdel-Gaber AM, Khamis E, Abo-Eldahab et al (2010) Novel package for inhibition of aluminium corrosion in alkaline solutions. Mater Chem Phys 124(1):773–779
Moghanni-Bavil-Olyaei H, Arjomandi J, Hosseini M (2017) Effects of gallium and lead on the electrochemical behavior of Al-Mg-Sn-Ga-Pb as anode of high rate discharge battery. J Alloys Compd 695:2637–2644
Umoren SA, Li Y, Wang FH (2011) Effect of aluminium microstructure on corrosion and inhibiting effect of polyacrylic acid in H2SO4 solution. J Appl Electrochem 41(3):307–315
Liu X, Zhang P, Xue J (2019) The role of micro-naoscale AlSb precipitates in improving the discharge performance of Al-Sb alloy anodes for Al-air batteries. J Power Sources 425:174–182
Liu X, Xue J, Zhang P, Wang Z (2019) Effects of the combinative Ca, Sm and La additions on the electrochemical behaviors and discharge performance of the as-extruded AZ91 anodes for Mg-air batteries. J Power Sources 414:186–194
Rohrer GS (2011) Grain boundary energy anisotropy: a review. J Mater Sci 46(18):5881–5895
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The authors received financial support from the National Natural Science Foundation of China (Grant No. U1864209) and National Natural Science Foundation of China-Liaoning Provincial People’s Government Joint Fund (Grant No. U1708253).
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Wu, Z., Zhang, H., Guo, C. et al. Effects of indium, gallium, or bismuth additions on the discharge behavior of Al-Mg-Sn-based alloy for Al-air battery anodes in NaOH electrolytes. J Solid State Electrochem 23, 2483–2491 (2019). https://doi.org/10.1007/s10008-019-04341-2
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DOI: https://doi.org/10.1007/s10008-019-04341-2