Research status of zinc anode for zinc-air batteries

doi:10.16085/j.issn.1000-6613.2016.02.016

Abstract

Abstract: In renewable energy power generation and electric vehicle technology,the development of high energy density,safe,reliable and pollution-free zinc-air batteries is of important social and economic value. However,some problems of zinc anode has seriously hindered its application. Therefore,this paper systematically reviews the progress on corrosion,dendrite formation,shape change and passivation of zinc anode. The inhibition effects of inorganic corrosion inhibitors,organic corrosion inhibitors and mixed corrosion inhibitors on hydrogen evolution are introduced,and the effects of additives,separators and operating conditions on the formation and growth of dendrite are discussed. The mechanism of shape change and the common solutions are reviewed,and the causes of passivation and its effects are described briefly. The analysis shows that the electrically rechargeable zinc-air batteries have more market prospects than the primary ones. Also,the inhibition of hydrogen corrosion is still the focus toward zinc anode studies in the future,and improving the capacity and power stability during cycling is the key to the practical application.

Key words: zinc anode, corrosion, dendrite formation, shape change, passivation

摘要： 在可再生能源发电和电动汽车技术领域,发展能量密度高、安全可靠、绿色无污染的锌空气电池具有重要社会经济价值。但锌空气电池负极存在的问题严重影响了电池的使用性。本文从析氢腐蚀、枝晶生长、电极形变和钝化4个方面介绍锌空气电池负极的研究状况,深入分析无机缓蚀剂、有机缓蚀剂和混合缓蚀剂对析氢腐蚀的抑制作用;讨论添加剂、隔膜和操作条件对枝晶形成与生长的影响;阐述电极形变的机理与常见的解决方法;简述锌负极钝化发生的原因和对电池性能的影响。研究结果表明,电化学可充的锌空气电池比一次锌空气电池更具有市场前景,进一步抑制析氢腐蚀仍是今后锌负极研究的重点,提高循环过程的容量与功率稳定性是满足实际应用的关键。

关键词: 锌负极, 析氢腐蚀, 枝晶生长, 电极形变, 钝化

CLC Number:

TM911.41

HONG Weichen, LEI Qing, MA Hongyun, WANG Baoguo. Research status of zinc anode for zinc-air batteries[J]. Chemical Industry and Engineering Progree, 2016, 35(02): 445-452.

洪为臣, 雷青, 马洪运, 王保国. 锌空气电池锌负极研究进展[J]. 化工进展, 2016, 35(02): 445-452.

References

[1] LI Y,DAI H. Recent advances in zinc-air batteries[J]. Chemical Society Reviews,2014,43(15):5257-5275.
[2] LEE J S,TAI KIM S,CAO R,et al. Metal-air batteries with high energy density:Li-air versus Zn-air[J].Advanced Energy Materials,2011,1(1):34-50.
[3] RAHMAN M A,WANG X,WEN C. High energy density metal-air batteries:a review[J]. Journal of the Electrochemical Society,2013,160(10) A1759-A1771.
[4] 景义军,郭际,孟宪玲,等. 汽车用锌空气动力电池研究现状[J]. 电源技术,2011,35(10):1302-1303.
[5] MA H,WANG B,FAN Y,et al. Development and characterization of an electrically rechargeable zinc-air battery stack[J]. Energies,2014,7(10):6549-6557.
[6] 黄启明,李伟善,张世涌,等. 铟在无汞碱性锌锰电池中的应用[J]. 电池,2001,31(5):233-235.
[7] KANNAN A R S,MURALIDHARAN S,SARANGAPANI K B,et al. Corrosion and anodic behaviour of zinc and its ternary alloys in alkaline battery electrolytes[J]. Journal of Power Sources,1995,57(1):93-98.
[8] 费锡明,彭历,黄正喜,等. 无汞碱锰电池锌负极的研究(Ⅱ)[J]. 华中师范大学学报(自然科学版),2001,35(1):57-60.
[9] 洪淑娜,林海斌,苏卓健,等. 碱性溶液中锌电极缓蚀的研究[J]. 电化学,2011(2):144-148.
[10] LEE S M,KIM Y J,EOM S W,et al. Improvement in self-discharge of Zn anode by applying surface modification for Zn-air batteries with high energy density[J]. Journal of Power Sources,2013,227:177-184.
[11] 周合兵,杨美珠,吕东生,等. 几种缓蚀剂对锌粉缓蚀效果的比较[J]. 电池,2003,33(6):378-380.
[12] 周合兵,杨美珠,李伟善,等. 化学镀铟对锌在碱性溶液中电化学行为的影响[J]. 稀有金属材料与工程,2008,37(3):404-408.
[13] LEE C W,SATHIYANARAYANAN K,EOM S W,et al. Novel alloys to improve the electrochemical behavior of zinc anodes for zinc/air battery[J]. Journal of Power Sources,2006,160(2):1436-1441.
[14] EL-SAYED A R,MOHRAN H S,EL-LATEEF H M A. Inhibitive action of ferricyanide complex anion on both corrosion and passivation of zinc and zinc-nickel alloy in the alkaline solution[J]. Journal of Power Sources,2011,196(15):6573-6582.
[15] 张奇尧,王善民,陈云娣,等. 碱锰电池负极添加稀土氧化物的研究[J]. 电池,2005,35(3):212-213.
[16] ZHU L,ZHANG H,LI W,et al. Great improvement over electrochemical performance of zinc electrodes from sonochemical growth of cerium conversion films on zinc powder[J]. Journal of Alloys and Compounds,2009,471(1):481-487.
[17] KIM H S,JO Y N,LEE W J,et al. Coating on zinc surface to improve the electrochemical behavior of zinc anodes for zinc-air fuel cells[J]. Electroanalysis,2015,27(2):517-523.
[18] DOBRYSZYCKI J,BIALLOZOR S. On some organic inhibitors of zinc corrosion in alkaline media[J]. Corrosion Science,2001,43(7):1309-1319.
[19] NAJA M,PENAZZI N,FARNIA G,et al. Zinc corrosion in NH₄Cl and effect of some organic inhibitors[J]. Electrochimicaacta,1993,38(10):1453-1459.
[20] ZHOU H,HUANG Q,LIANG M,et al. Investigation on synergism of composite additives for zinc corrosion inhibition in alkaline solution[J]. Materials Chemistry and Physics,2011,128(1):214-219.
[21] 孟凡桂,唐有根,蒋金芝,等. 碱锰电池有机代汞缓蚀剂的研究[J]. 电源技术,2004,28(3):137-140.
[22] EIN-ELI Y,AUINAT M,STAROSVETSKY D. Electrochemical and surface studies of zinc in alkaline solutions containing organic corrosion inhibitors[J]. Journal of Power Sources,2003,114(2):330-337.
[23] HANSAL W E G,HANSAL S,PÖLZLER M,et al. Investigation of polysiloxane coatings as corrosion inhibitors of zinc surfaces[J]. Surface and Coatings Technology,2006,200(9):3056-3063.
[24] LEE C W,SATHIYANARAYANAN K,EOM S W,et al. Novel electrochemical behavior of zinc anodes in zinc/air batteries in the presence of additives[J]. Journal of Power Sources,2006,159(2):1474-1477.
[25] JIA Zheng,ZHOU Deyui,ZHANG Cuifen. Composite corrosion inhibitors for secondary alkaline zinc anodes[J]. Transactions of Nonferrous Metals Socicy of China,2005,15(1):200-206.
[26] 贾铮,张翠芬,周德瑞. 二次碱性锌电极的复合缓蚀剂[J]. 电池,2004,34(2):111-113.
[27] 周合兵,杨美珠,吕东生,等. KOH中几种缓蚀剂抑制锌腐蚀的协同作用[J]. 电源技术,2002,26(s1):195-197.
[28] DIGGLE J W,DESPICA R,BOCKRIS J O M. The mechanism of the dendritic electrocrystallization of zinc[J]. Journal of the Electrochemical Society,1969,116(11):1503-1514.
[29] DESPIC A R,DIGGLE J,BOCKRIS J O M. Mechanism of the formation of zinc dendrites[J]. Journal of the Electrochemical Society,1968,115(5):507-508.
[30] 王建明,张莉,张春,等. Bi~(3+)和四丁基溴化铵对碱性可充锌电极枝晶生长行为的影响[J]. 功能材料,2001,32(1):45-47.
[31] 胡卫华,喻敬贤,杨汉西,等. 二维锌枝晶生长行为研究[J]. 武汉大学学报(理学版),2004,50(4):431-435.
[32] 高鹏,董媛媛,张哲,等. 二乙醇胺、三乙醇胺对锌电极性能的影响[J]. 电池工业,2011,16(1):13-16.
[33] 胡莲跃,张胜涛,黄小红,等. 添加剂在KOH溶液中对锌电极枝晶的影响[J]. 应用化学,2012,29(3):359-363.
[34] BANIK S J,AKOLKAR R. Suppressing dendrite growth during zinc electrodeposition by PEG-200 additive[J]. Journal of The Electrochemical Society,2013,160(11):D519-D523.
[35] 尤金跨,詹亚丁,林祖庚. 碱性二次锌电池隔膜材料耐枝晶性[J].电池,1992,22(2):51-53.
[36] YANG C C,YANG J M,WU C Y. Poly(vinyl alcohol)/poly(vinyl chloride) composite polymer membranes for secondary zinc electrodes[J]. Journal of Power Sources,2009,191(2):669-677.
[37] WOUMFO E D,VITTORI O. Electrochemical behaviour of a zinc electrode in 8 M KOH under pulsed potential loading[J]. Journal of Applied Electrochemistry,1991,21(1):77-83.
[38] PARKER J F,CHERVIN C N,NELSON E S,et al. Wiring zinc in three dimensions re-writes battery performance—dendrite-free cycling[J]. Energy & Environmental Science,2014,7(3):1117-1124.
[39] MCBREEN J. Zinc electrode shape change in secondary cells[J]. Journal of the Electrochemical Society,1972,119(12):1620-1628.
[40] EINERHAND R E F,VISSCHER W,DE GOEIJ J J M,et al. Zinc electrode shape change Ⅱ. process and mechanism[J]. Journal of The Electrochemical Society,1991,138(1):7-17.
[41] EINERHAND R E F,VISSCHER W,DE GOEIJ J J M,et al. Zinc electrode shape change I. in situ monitoring[J]. Journal of the Electrochemical Society,1991,138(1):1-7.
[42] 孙烨,张宝宏,张娜. 碱性二次锌电极的新进展[J]. 应用科技,2002,29(2):47-49.
[43] CHOI K W,BENNION D N,NEWMAN J. Engineering analysis of shape change in zinc secondary electrodes I. theoretical[J]. Journal of the Electrochemical Society,1976,123(11):1616-1627.
[44] CHOI K W,HAMBY D,BENNION D N,et al. Engineering analysis of shape change in zinc secondary electrodes II. experimental[J]. Journal of the Electrochemical Society,1976,123(11):1628-1637.
[45] POA S P,WU C H. A quantitative study of shape change in zinc secondary electrodes[J]. Journal of Applied Electrochemistry,1978,8(5):427-436.
[46] 张春,王建明,张昭,等. 钙添加剂对可充锌电极性能的影响[J]. 中国有色金属学报,2001,11(5):780-784.
[47] ADLER T C,MCLARNON F R,CAIRNS E J. Rechargeable zinc cell with alkaline electrolyte which inhibits shape change in zinc electrode:US5453336[P]. 1995-09-26.
[48] VATSALARANI J,TRIVEDI D C,RAGAVENDRAN K,et al. Effect of polyaniline coating on “shape change” phenomenon of porous zinc electrode[J]. Journal of the Electrochemical Society,2005,152(10):A1974-A1978.
[49] 蔡年生,李少丰. 一次电池中的锌电极——Ⅰ.锌的电化学行为及钝化[J]. 电池,1982,12(4):9-13.
[50] FARMER E D,WEBB A H. Zinc passivation and the effect of mass transfer in flowing electrolyte[J]. Journal of Applied Electrochemistry,1972,2(2):123-136.
[51] HAMPSON N A,TARBOX M J. The anodic behavior of zinc in potassium hydroxide solution Ⅰ. horizontal anodes[J]. Journal of the Electrochemical Society,1963,110(2):95-98.
[52] DIRKSE T P,HAMPSON N A. The anodic behaviour of zinc in aqueous KOH solution——Ⅰ. passivation experiments at very high current densities[J]. Electrochimica Acta,1971,16(12):2049-2056.
[53] DIRKSE T P,HAMPSON N A. The anodic behaviour of zinc in aqueous KOH solution——Ⅱ. passivation experiments using linear sweep voltammetry[J]. Electrochimica Acta,1972,17(3):387-394.
[54] LIU M B,COOK G M,YAO N P. Passivation of zinc anodes in KOH electrolytes[J]. Journal of the Electrochemical Society,1981,128(8):1663-1668.
[55] THOMAS S,COLE I S,SRIDHAR M,et al. Revisiting zinc passivation in alkaline solutions[J]. Electrochimica Acta,2013,97:192-201.
[56] POWERS R W,BREITER M W. The anodic dissolution and passivation of zinc in concentrated potassium hydroxide solutions[J]. Journal of the Electrochemical Society,1969,116(6):719-729.
[57] YANG H,CAO Y,AI X,et al. Improved discharge capacity and suppressed surface passivation of zinc anode in dilute alkaline solution using surfactant additives[J]. Journal of Power Sources,2004,128(1):97-101.