Co-B合金粉体的制备和电化学行为

doi:10.3724/SP.J.1037.2009.00386

金属学报

2010, Vol. 46

Issue (3): 346-351 DOI: 10.3724/SP.J.1037.2009.00386

论文

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Co-B合金粉体的制备和电化学行为

吕东生^1;2); 李伟善^1;2); 谭春林^1;2); 曾荣华¹⁾

1) 华南师范大学化学与环境学院; 广州 510631
2) 广东省高等学校电化学储能和发电技术重点实验室; 广州 510006

PREPARATION AND ELECTROCHEMICAL BEHAVIORS OF Co-B ALLOY POWDERS

LV Dongsheng^1;2); LI Weishan^1;2); TAN Chunlin^1;2); ZE Ronghua¹⁾

1) Department of Chemistry and Environment; South China Normal University; Guangzhou 510631
2) Key Lab of Technology on Electrochemical Energy Storage and Power Generation in Guangdong Universities; Guangzhou 510006

引用本文:

吕东生李伟善谭春林曾荣华. Co-B合金粉体的制备和电化学行为[J]. 金属学报, 2010, 46(3): 346-351.
, , , . PREPARATION AND ELECTROCHEMICAL BEHAVIORS OF Co-B ALLOY POWDERS[J]. Acta Metall Sin, 2010, 46(3): 346-351.

全文: PDF(1221 KB)

摘要:

通过NaBH₄还原CoSO₄溶液制备了Co_0.68B_0.32, Co_0.55B_0.45和Co_0.50B_0.50一系列超细非晶态Co-B合金粉体. 电化学测试表明, 在300 mA/g的高电流密度下, 3种合金电极的首次放电容量分别高达510.6, 666.4和667.2 mA?h/g, 经60次循环后, 放电容量仍分别有331.6, 379.5和390.5 mA?h/g. 3种合金电极还表现出良好的高率放电性能, 在1200 mA/g的放电电流密度下, 放电容量分别为336.2, 373.4和390.1 mA?h/g. 较高的B含量有助于提高合金的电化学性能, 这是因为B的氧化溶解能提高合金电极的实际电化学反应面积.

关键词 ： Co-B合金, 非晶粉体, 化学还原, 电化学性能

Abstract：

Alkaline rechargeable batteries, such as Ni/Cd batteries and Ni/MH batteries have been widely used as power sources, however, their further applications are limited due to contamination of Cd in Ni/Cd batteries and lower discharge capacities of Ni/MH batteries. Some metal borides, such as Co-B, Ni-B, Fe-B, V-B and Ti-B, have been known to own very high discharge capacity in alkaline aqueous solution, in which Co--B alloy exhibits the highest reversible discharge capacity and the best cyclic stability. However, the reversible capacity of Co-B alloy prepared by arc melting process is usually less than 250 mA?h/g, which is only one fourth of the theoretical capacity of the alloy electrode (908 mA?h/g). In the present study, chemical reduction method was used to prepare Co-B alloy to further enhance the electrochemical capacity of the alloy. A series of ultrafine powders of amorphous Co-B alloys, Co_0.68B_0.32, Co_0.55B_0.45 and Co_0.50B_0.50, were prepared by reducing CoSO₄ with solution of NaBH₄. Electrochemical measurements indicate that the prepared alloys exhibit excellent electrochemical properties. At a high current density of 300 mA/g, the initial discharge capacities of these alloys are 510.6, 666.4 and 667.2 mA$?h/g, respectively, their discharge capacities still keep 331.6, 379.5 and 390.5 mA?h/g after 60 cyc, respectively. Even at a discharge current density as high as 1200 mA/g, the three alloys still deliver reversible capacities of 336.2, 373.4 and 390.1 mA?h/g, respectively. In the Co-B alloy electrodes, the boron atoms have two functions. First, boron can be oxidized to BO₃^3-, thereby partly contributes to the discharge capacity. Second, most importantly, the gradual dissolution of boron into the electrolyte (in the form of BO₃^3-) during the charging/discharging creates a new surface in the electrodes, which can effectively increase the surface area of the active material in contact with the electrolyte. The alloy with higher boron content thereby can produce a larger reaction surface area by boron dissolution than the alloy prepared with lower B content. So the higher B content in the Co-B alloys can be helpful for improving their electrochemical properties.

Key words： Co-B alloy amorphous powder chemical reduction electrochemical property

收稿日期: 2009-06-09

基金资助:

广东省高校优秀青年教师培养计划(育苗工程)资助项目

作者简介: 吕东生, 男, 1976年生, 讲师, 博士生

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https://www.ams.org.cn/CN/10.3724/SP.J.1037.2009.00386 或 https://www.ams.org.cn/CN/Y2010/V46/I3/346

[1] Chen J, Tao Z L, Gou X L. Chemical Power Sources—Principle, Technology & Application. Beijing: Chemical Industry Press, 2006: 187
(陈军, 陶占量, 苟兴龙. 化学电源—原理、技术与应用. 北京: 化学工业出版社, 2006: 187)

[2] Vermeulen P, Niessen R A H, Notten P H L. Electrochem Commun, 2006; 8: 27
[3] Yu X W, Licht S. Electrochim Acta, 2007; 52: 8138
[4] Yu X W, Licht S. J Power Sources, 2008; 179: 407
[5] Yu J X, Wang L, Wang Y D, Dong H, Yang H X. J Electrochem Soc, 2004; 151: A1124
[6] Liu Y, Wang Y J, Xiao L L, Song D W, Wang Y P, Jiao L F, Yuan H T. Electrochim Acta, 2008; 53: 2265
[7] Shukla A K, Venugopalan S, Hariprakash B. J Power Sources, 2001; 100: 125
[8] Hang B T, Yoon S–H, Okada S, Yamaki J. J Power Sources, 2007; 168: 522
[9] Hang B T, Watanabe T, Egashira M, Watanabe I, Okada S, Yamaki J. J Power Sources, 2006; 155: 461
[10] Huang Y X, Sun W Z. Chemical Analysis of Common Elements. Beijing: Chemical Industry Press, 2008: 42
(黄运显, 孙维贞. 常见元素化学分析方法. 北京: 化学工业出版社, 2008: 42)

[11] Palmas S, Ferrara F, Vacca A, Mascia M, Polcaro A M. Electrochim Acta, 2007; 53: 400
[12] Silva L M, Faria L A, Boodts J F C. Electrochim Acta, 2001; 47: 395
[13] Shen J Y, Li Z Y, Yan Q J, Chen Y. J Phys Chem, 1993; 97: 8504
[14] Schlesinger M, Paunovic M, Translated by Fan H Y. Modern Plating. Beijing: Chemical Industry Press, 2006: 24
(Schlesinger M, Paunovic M著; 范宏义~译. 现代电镀. 北京: 化学工业出版, 2006: 24)

[15] Pei Y, Guo P J, Qiao M H, Li H X,Wei S Q, He H Y, Fan K N. J Catal, 2007; 248: 303
[16] Wang Y D, Ai X P, Cao Y L, Yang H X. Electrochem Commun, 2004; 6: 780
[17] Zhang X B, Sun D Z, Yin W Y, Chai Y J, Zhao M S. Eur J Inorg Chem, 2005: 2235
[18] Zhang X G, Translated by Zhong H F, Cheng D M. Corrosion and Electrochemistry of Zinc. Beijing: Metallurgical Industry Press, 2008: 78
(章小鸽著; 仲海峰, 程东妹译. 锌的腐蚀与电化学. 北京: 冶金工业出版, 2008: 78)

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