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Ti_(1.0)Mn_(0.9)V_(1.1)基合金的微观结构和电化学性能

Microstructure and electrochemical characteristics of Ti_(1.0)Mn_(0.9)V_(1.1) based alloy
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摘要 “与Laves相相关的BCC固溶体”是一个新概念,由此发展起来的新型钛基BCC合金贮氢能力已经达到了2.2%(质量分数)。Akiba等用TEM(透射电子显微镜)方法观测TiMnV合金的BCC相和C14相的交界面,发现存在一个厚度为10 nm的薄层。通过EDX(电子探针X射线显微分析)方法观测,这个薄层物质的组成为Ti1.0Mn0.9V1.1,但是Ti1.0Mn0.9V1.1却不具备电化学活性。在此基础上,从Ti1.0Mn0.9V1.1出发,通过组成元素的部分取代,使储氢性能优良的Ti1.0Mn0.9V1.1具有电催化活性,对Ti1.0Mn0.9V1.1系合金的结构和电化学性能进行研究,Ti1.0Mn0.9V1.1系合金有可能成为MH-Ni蓄电池潜在的高温负极材料。 "Laves phase related BCC solid solution" is a new concept, and the hydrogen storage capacity of the new Ti-based BCC alloy developed from it has reached 2.2 %. Through the TEM microstructure observation of the area adjacent to the BCC/C14 interface in TiMnV, a very fine lamellar structure (about 10 nm thickness) has been found. The composition of this adjacent interface phase is Ti1.0Mn0.9V1.1, but Ti1.0Mn0.9V1.1 has no electrocatalyst activity. We use the partly substitution of the element to make Ti1.0Mn0.9V1.1 to have electrocatalyst activity, and the microstructure and electrochemical characteristics of Ti1.0Mn0.9V1.1 based alloys are studied. Ti1.0Mn0.9V1.1 may be a potential negative electrode material in Ni/MH battery at high temperature.
作者 苏静 赵敏寿 柴玉俊 朱新坚 曹广益
机构地区 燕山大学环境与化学工程学院 中国科学院长春应用化学研究所稀土化学与物理重点实验室 上海交通大学燃料电池研究所
出处 《电源技术》 CAS CSCD 北大核心 2006年第9期720-723,共4页 Chinese Journal of Power Sources
基金 国家自然科学基金资助项目(20171042)
关键词 MH-NI蓄电池 负极材料 与Laves相相关的BCC固溶体 球磨 Ni-MH battery negative electrode materials laves phase related BCC solid solution ball-milling
分类号 TM912.12 [电气工程—电力电子与电力传动]
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  • 1鲁辉,高学平,宋德瑛,张允什.稀土—镍系AB_(5±x)非化学计量贮氢材料的研究现状[J].稀土,1995,16(5):28-35. 被引量:5
  • 2大角泰章.金属氢化物的性质与应用[M].北京:化学工业出版社,1999,9.355.
  • 3方守狮 梁国宪 等.94'中国材料研讨会[M].北京,1994..
  • 4[1]Willems J J G, Philips J. Metal hydride electrodes stability of LaNi5 related compounds[J]. Res Suppl, 1984, 39(1): 10.
  • 5[2]Notten P H L, Hokkeling P. Double-phase hydride forming com pounds: A new class of highly electrocatalytic materials [ J ]. J Elec trochem Soc, 1991, 138:1 877.
  • 6[3]Sakai T, Miyamura H, Kuriyama N, et al. Metal hydride anodes for nickel-hydrogen secondary battery[J ]. J Electrochem Soc, 1990, 137: 795.
  • 7[4]Wang C S, Lei Y Q, Wang Q D. Studies of electrochemical properties of TiNi alloy used as an MH electrode( Ⅰ ). discharbge capacity[J].Electrochim Acta, 1998, 43: 3 193.
  • 8[5]Hongge Pan, Yun Chen, Chunsheng Wang, et al. Effect of alloys modi fied by an alkaline solution containing potassium borohydride on the kinetic properties of MINi3.7 Co0. 6 Mn0.4 AAl0. 3 hydride electrode [ J ]. Electrochim Acta, 1999, 44: 2 263.
  • 9[6]Yu J S, Lee S M, Cho K, et al. The cycle life of Ti0.8Zr0.2V0.5Mn0.5 - x CrxNi0.8 (x = 0~ 0.5) alloys for metal hydride electrodes of Ni-Metal hydride rechargeable battery [ J ]. J Electrochem Soc, 2000, 147: 2 013.
  • 10[7]Kim D M, Lee S M, Jang K J, et al. The electrode characteristics of over-stoichiometric ZrMn0.5V0.5 Ni1.4+ y (y = 0.0, 0.2, 0.4, 0.6) al loys with C15 laves phase structure [ J ]. Alloys Comp. 1998,268: 241.

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电源技术
2006年 第9期

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