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李洲鹏,浙江大学化学工程与生物工程学系教授,化学工程研究所支部书记、副所长,从事能源化工,燃料电池,二次电池的研究。作为项目负责人已先后承担了国家“863”科技计划、国家自然科学基金面上项目、重大横向项目、浙江省自然科学基金重点项目、博士点基金项目、钱江人才项目等10余项。
姓名:李洲鹏
单位:化学工程与生物工程学院
职称:教授
学习与工作经历:
1979年~1983年,浙江大学材料科学与工程学系,学士
1983年~1986年,浙江大学材料科学与工程学系,硕士
1986年~1989年,浙江大学材料科学与工程学系,博士
1989年~1992年,浙江大学讲师、儲氢合金与镍氢电池氢化物电极材料的研究
1992年~1997年,工学院大学客座研究员、儲氢合金的表面处理与电化学特性的研究。从95年起参加日本通商产业省工业技术院的“石油代替能源关系技术实用化开发”的项目:利用氟化儲氢合金进行普氢的利用技術的开发项目(95-99年)。
1997年~1999年,氢能源技术研究所电池开发室長、工学院大学客座研究员、儲氢合金的表面处理与电化学特性以及镍氢电池研究。1999年参加日本科学技术振兴会的“独创性研究成果育成事业”的“利用氟化储氢合金的高容量镍氢电池”开发项目中担任首席研究员。
1999年~2002年,氢能源技术研究所董事, 研究开发室長, 工学院大学客座研究员、硼氢化合物及其燃料电池的研究、使用完燃料的再生处理的开发。2000年参加新能源·产业技术综合开发机构(NEDO)的燃料电池实用化的核心技术的开发与实证、液态产氢燃料的研究开发项目中担任首席研究员。2001年参加日本科学技术振兴会的「独创性研究成果育成事业」“携帯机器用小型液体燃料电池的开发”的项目中担任首席研究员。
2003年~2005年,メリット·フュエルセル株式会社(Merit Fuel Cell Ltd.) 董事长,总经理, 氢能源技术研究所董事, 研究开发室長, 工学院大学客座研究员、2002年参加新能源·产业技术综合开发机构(NEDO)的“高容量常温工作硼氢化合物液体燃料电池的实用化研究开发”项目中担任首席研究员。
2005年~现在,浙江大学化学工程与生物工程学系教授,化学工程研究所支部书记、副所长,从事能源化工,燃料电池,二次电池的研究。作为项目负责人已先后承担了国家“863”科技计划、国家自然科学基金面上项目、重大横向项目、浙江省自然科学基金重点项目、博士点基金项目、钱江人才项目等10余项。
学位论文:
学士学位论文:稀土类储氢合金的储氢性能研究
硕士学位论文:储氢合金的粉化与储氢容器的变形及改良方法
博士学位论文:镍氢电池负极材料的研究
申请专利50余件,授权30余项,出版书籍5册中的部分章节,在学术杂志上发表SCI论文80余篇,他引数超1700 次,其中“Nickel- and cobalt-based catalysts for hydrogen generation by hydrolysis of borohydride”《J. Alloy Compd., 415 (2006) 288-293》获该杂志2008年最多引用作者奖,“A review: Hydrogen generation from borohydride hydrolysis reaction”《J. Power Sources, 187 (2009) 527-534》,“Evaluation of alkaline borohydride solutions as the fuel for fuel cell”《J. Power Sources, 126 (2004) 28-33》, “Current status and progress of direct borohydride fuel cell technology development”《J. Power Sources, 187 (2004) 291-297》,以上4篇论文入选ESI工程类高被引论文,H指数24。
(1)镍氢电池的研究开发:实用化AB5型氢化物电极的开发成功
(2)表面处理技术的研究开发:提高儲氢合金的初期活性,抗中毒性、耐久性、提高氢化物电极的高速放电性能的表面处理方法
(3)镍氢电池用的儲氢合金的表面处理方法转让给日本重化学工业公司
(4)镍氢电池技术:AB2型儲氢合金为负极的大容量电池
(5)硼氢化合物为燃料的燃料电池模型的开发成功
(6)燃料的再生处理的开发成功
(7)氢发生器的模型开发成功
(8)建立年产200吨的磷酸铁锂生产线,容量达到150 mAh/g
其他:2000年被选入世界名人录(Who’s Who)。
工作研究领域
物理化学,电化学,材料科学,能源化工,燃料电池,二次电池
联系方式
电话:87953149
电子信箱:zhoupengli@zju.edu.cn
发表论文
(1) Z. P. Li, Z. X. Liu, H.Y. Qin, K.N. Zhu, B. H. Liu, “Performance degradation of a direct borohydride fuel cell”, J. Power Sources, 236 (2013) 17-24.
(2) Pei Pei Yuan, Bin Hong Liu, He Peng Zhu, Wei Yuan Pan, Zhou Peng Li, “Destabilized dehydrogenation reaction of LiBH4 by AlF3”, J. Alloys Compd., 557 (2013) 124-129.
(3) J. Wang, H.Y. Qin, J.B. Liu, Z.P. Li, H. Wang, K. Yang, A.G. Li, Y. He, X.H. Yu, “Atomic structure of polypyrrole-modified carbon-supported cobalt catalyst”, J. Phy. Chem. C, 116 (2012) 20225-20229.
(4) Z.P. Li , Z.X. Liu, K.N. Zhu, Z. Li, B.H. Liu, “Synergy among transition element, nitrogen, and carbon for oxygen reduction reaction in alkaline medium”, J. Power Sources, 219 (2012) 163-171.
(5) H.Y. Qin, K.N. Zhu, L.Q. Ye, Z.P. Li, “Oxygen reduction reaction on a polypyrrole-modified, carbon-supported cobalt hydroxide catalyst”, J. Power Sources, 208 (2012) 203– 209.
(6) P. Li, Z.P. Li, B.H.Liu, “Methanol electrooxidation promoted by UV–vis light irradiation”, J. Power Sources, 199 (2012) 146–149.
(7) Z.X. Liu, Z.P. Li, H.Y. Qin, B.H. Liu, “Oxygen reduction reaction via the 4-electron transfer pathway on transition metal hydroxides”, J. Power Sources, 196 (2011) 4972–4979.
(8) Z.P. Li, B.H. Liu, F.F. Liu, D. Xu, “A composite of borohydride and super absorbent polymer for hydrogen generation”, J. Power Sources, 196 (2011) 3863–3867.
(9) L Q. Ye, Z. P. Li, H. Y. Qin, J.K. Zhu, B. H. Liu, “Hydrazine electrooxidation on a composite catalyst consisting of nickel and palladium”, J. Power Sources, 196 (2011) 956–961.
(10) K.N. Zhu, H.Y. Qin, B.H. Liu, Z.P. Li, “Carbon nanotubes supported Fe-based compounds as the electrode catalyst for oxygen reduction reaction”, J. Power Sources, 196 (2011) 182-185.
(11) K. Xu, S.J. Lao, H.Y Qin, B. H. Liu, Z.P. Li, “A study of the direct dimethyl ether fuel cell using alkaline anolyte”, J. Power Sources, 195 (2010) 5606–5609.
(12) H.Y. Qin, Z.X. Liu, Y.F. Guo, Z.P. Li , “The affects of membrane on the cell performance when using alkaline borohydride–hydrazine solutions as the fuel”, Int. J. of Hydrogen Energy, 35 (2010) 2868-2871.
(13) S.J. Lao, H.Y. Qin, L.Q. Ye, B. H. Liu, Z.P. Li, “A development of direct hydrazine/hydrogen peroxide fuel cell”, J. Power Sources, 195 (2010) 4135–4138.
(14) Z.P. Li, B. H. Liu, “The use of macrocyclic compounds as electrocatalysts in fuel cells”, J. Appl. Electrochem., 40 (2010) 475–483.
(15) H.Y. Qin, S.J. Lao, Z.X. Liu, J.K. Zhu, Z.P. Li, “Effects of heat treatment on the Structure, morphology And electrocatalytic activity of cobalt hydroxide electrocatalyst”, Int. J. of Hydrogen Energy, 35 (2010) 1872-1878.
(16) H.Y Qin, Z.X Liu, S.J. Lao, J.K. Zhu, Z.P. Li, “Influences of carbon support on the electrocatalysis of polypyrrole-modified cobalt hydroxide in the direct borohydride fuel cell”, J. Power Sources, 195 (2010) 3124–3129.
(17) B.H. Liu, J.Q. Yang, Z.P. Li, “Concentration ratio of [OH-]/[BH4-]: A controlling factor for the fuel efficiency of borohydride electro-oxidation”, Int. J. of Hydrogen Energy, 34(23) (2009) 9436-9443.
(18) H.Y. Qin, Z.X. Liu, L.Q. Ye, J.K. Zhu, Z.P. Li , “The use of polypyrrole modified carbon-supported cobalt hydroxide as cathode and anode catalysts for the direct borohydride fuel cell”, J. Power Sources, 192 (2009) 385–390.
(19) B. H. Liu and Z. P. Li, “A Review: Hydrogen generation from Borohydride Hydrolysis Reaction”, J. Power Sources, 187 (2009) 527–534.
(20) B. H. Liu and Z. P. Li, “Current status and progress of direct borohydride fuel cell technology development”, J. Power Sources, 187 (2009) 291–297.
(21) B. H. Liu, Z. P. Li, J. K. Zhu, “ Sodium borohydride formation when Mg reacts with hydrous sodium borates under hydrogen”, J. Alloys Compd., 476 (2009) L16-L20.
(22) B. H. Liu, Z. P. Li, S. Suda, “Improving MgH2 formation kinetics and its effect on NaBH4synthesis”, J. Alloys Compd., 474 (2009) 321-325.
(23) B. H. Liu, Z. P. Li, S. Suda, “Influences of alkali in borates on recovery of sodium borohydride”, J. Alloys Compd., 474 (2009) L6-L9.
(24) B. H. Liu, Z. P. Li and S. Suda, “Solid sodium borohydride as a hydrogen source for fuel cells”, J. Alloys Compd., 468(1-2) (2009) 493-498.
(25) B. H. Liu, Z. P. Li, S. Suda, “A study on performance stability of the passive direct borohydride fuel cell”, J. Power Sources, 185 (2008) 1257–1261.
(26) H.Y. Qin, Z.X. Liu, W.X. Yin, J.K. Zhu, Z.P. Li , “Effects of hydrazine addition on gas evolution and performance of the direct borohydride fuel cell” J. Power Sources, 185 (2008) 895–898.
(27) H.Y. Qin, Z.X. Liu, W.X. Yin, J.K. Zhu, Z.P. Li , “A cobalt polypyrrole composite catalyzed cathode for the direct borohydride fuel cell”, J. Power Sources, 185 (2008) 909–912.
(28) B. H. Liu,Z. P. Li, J. K. Zhu, S. Suda, “Influences of hydrogen evolution on the cell and stack performances of the direct borohydride fuel cell”, J. Power Sources, 183 (2008) 151-156.ISSN:0378-7753
(29) W. X. Yin, Z. P. Li, J. K. Zhu, H. Y. Qin, “Effects of NaOH addition on performance of the direct hydrazine fuel cell”, J. Power Sources, 182 (2008) 520-523.
(30) B. H. Liu, Z. P. Li, N. Morigasaki and S. Suda, “Alkali oxide addition effects on borohydride formation during reaction of Al, Si and Ti with borate and hydrogen”, Energy & Fuels, Vol:22(3) (2008) 1894-1896.
(31) B. H. Liu, Z. P. Li and S. Suda, “Thermal properties of alkaline sodium borohydride solutions”, Thermochimica Acta, 471 (2008) 103-105.
(32) B.H. Liu, Z.P. Li and L.L. Chen, “Alkaline sodium borohydride gel as a hydrogen source for PEMFC or an energy carrier for NaBH4-air battery”, J. Power Sources, 180 (2008) 530-534.
(33) B. H. Liu, Z. P. Li and S. Suda, “Development of high-performance planar borohydride fuel cell modules for portable applications”, J. Power Sources, 175(1)(2008)226-231.
(34) B. H. Liu, Z. P. Li, N. Morigasaki and S. Suda, “Kinetic characteristics of sodium borohydride formation when sodium meta-borate reacts with magnesium and hydrogen”, Int. J. of Hydrogen Energy, 33 (2008) 1323-1328.
(35) Liu Bin-hong, Li Zhou-peng, Zhu Jing-ke, “NaBH4 formation through NaBO2 reacts with Mg and H2”, Acta Scientiarum Naturalium Universitatis Sunyatseni, Vol.46 Sup.(2007) 17-18.
(36) Qin Hai-ying, Zhao Xin-bing, Li Zhou-peng, “Solvothermal synthesis and electrochemical performance of nano-Ni3Sn2 used as an anodes for lithium-ion batteries”, Acta Scientiarum Naturalium Universitatis Sunyatseni, Vol.46 Sup. (2007) 274-275.
(37) H.Y Qin, X.B. Zhao, N.P. Jiang, Z.P. Li, “Solvothermal synthesis and ex situ XRD study of nano-Ni3Sn2 used as an anode material for lithium-ion batteries”, J. Power Sources, 171 (2007) 948-952.
(38) B. H. Liu, Z. P. Li, J. K.Zhu, N. Morigasaki and S. Suda, “Sodium borohydride synthesis by reaction of Na2O contained sodium borate with Al and hydrogen”, Energy & Fuels, Vol:21(3) (2007) 1707-1711.
(39) Z. P. Li, B. H. Liu, J. K. Zhu, N. Morigasaki and S. Suda, “NaBH4 formation mechanism by reaction of sodium borate with Mg and H2”, J. Alloys Compd.,437(1-2) (2007) 311-316.
(40) Z. P. Li, B. H. Liu, J. K. Zhu and S. Suda, “Depression of hydrogen evolution during operation of the direct borohydride fuel cell”, J. Power Sources, 163(1)(2006)555-559.
(41) Suda, S., Li, Z.-P., Sun, Y.-M., Liu, B.-H., Morigasaki, N., Hara, S.“Sodium borohydride as the hydrogen and protide source”,TMS Annual Meeting 2006, pp. 297, 12-16, Mar. 2006.SAN ANTONIO, TEXAS, USA.
(42) Suda, S., Morigasaki, N., Hara, S., Liu, B.-H., Sun, Y.-M., Li,Z.-P., “Sodium borohydride as a hydrogen storage material”, TMS Annual Meeting 2006, (2006) 147-148. 12-16, Mar. 2006.SAN ANTONIO, TEXAS, USA.
(43) B. H. Liu, Z. P. Li and S. Suda, “Nickel- and cobalt-based catalysts for hydrogen generation by hydrolysis of borohydride”, J. Alloys Compd.,415, (2006) 288-293.
(44) Z. P. Li, B. H. Liu, K. Arai and S. Suda, “Development of the direct borohydride fuel cell”, J. Alloys Compd.,404-406, (2005) 648-652.
(45) S. Suda, N. Morigasaki Y. Iwase, and Z. P. Li “Production of sodium borohydride by using dynamic behaviors of protide at the extreme surface of magnesium particles”, J. Alloys Compd.,404-406, (2005) 643-647.
(46) 須田精二郎、李洲鵬、劉賓虹、“ボロハイドライドを水素燃料源とする小型燃料電池の開発”, ECO INDUSTRY, Vol.10 No.6, pp.25-33 (2005). シーエムシー出版 (in Japanese).
(47) B. H. Liu, Z. P. Li, K. Arai and S. Suda, “Performance improvement of a micro borohydride fuel cell operating at ambient conditions”, Electrochim. Acta. 50/18, (2005)3719-3725.
(48) 須田精二郎、李洲鵬、森ヶ崎信人、劉賓虹、孫元明、内田雅樹 “水素貯蔵材料としての水素ホウ素ナトリウム”, 表面技術Vol.56 No.4, (2005) 194-200. (in Japanese).
(49) 須田精二郎、李洲鵬、劉賓虹、“ボロハイドライド燃料電池”, 燃料電池Vol.4 No.3, (2005) 37-43. (in Japanese).
(50) 須田精二郎、森ヶ崎信人、岩瀬安慶、李洲鵬、“水素貯蔵材料としての水素ホウ素ナトリウム”, 化学装置Vol.46 No.10, (2004) 64-71. (in Japanese).
(51) B. H. Liu, Z. P. Li and S. Suda, “Electrocatalysts for the anodic oxidation of borohydrides”, Electrochim. Acta, 49, pp.3097-3105 (2004).
(52) S. Suda, Y. Iwase, N. Morigasaki and Z. -P. Li, "Metal-hydrogen complex compounds as hydrogen storage materials", Advanced Materials for Energy Conversion II TMS: pp. 123-133.
(53) Z. P. Li, B. H. Liu, K. Arai, K. Asaba and S. Suda, “Evaluation of alkaline borohydride solutions as the fuel for fuel cell”, J. Power Sources,126(1-2), pp.28-33 (2004).
(54) Z. P. Li, B. H. Liu, K. Arai and S. Suda, “A fuel cell development for using borohydrides as the fuel”, J. Electrochem. Soc. , 150 (2003) A868-872.
(55) B. H. Liu, Z.P. Li, S. Suda, “Anodic Oxidation of Alkali Borohydrides Catalyzed by Nickel”, J. Electrochem. Soc. 150 (2003) A398-402.
(56) Z. P. Li, B. H. Liu, N. Morigasaki and S. Suda, “Preparation of potassium borohydride by a mechano-chemical reaction of saline hydrides with dehydrated borate through ball milling”, J. Alloys Compd., 354(1/2) (2003) 243-247.
(57) Z. P. Li, B. H. Liu, K. Arai, N. Morigasaki and S. Suda, “Protide compounds in hydrogen storage systems”, J. Alloys Compd., 356-357(2003) 469-474.
(58) Z. P. Li, B. H. Liu, N. Morigasaki and S. Suda, “Preparation of sodium borohydride by the reaction of MgH2 with dehydrated borax through ball milling at room temperature”, J. Alloys Compd., 349(1)(2003) 232-236.
(59) B. H. Liu, Z. P. Li and S. Suda, “Electrochemical cycle life of Zr-based Laves phase alloys influenced by alloy stoichiometry and composition”, J. Electrochem. Soc., 149, (2002) A537-542.
(60) Z. -P. Li, B. -H. Liu, K. Hitaka, S. Suda, "Effects of Surface Structure of Fluorinated AB2 Alloys on their Electrodes and Battery Performances", J. Alloys Compd., 330-332, (2002)776-781.
(61) B.-H. Liu, Z.-P. Li, R. Kitani and S. Suda, “Improvement of electrochemical cyclic durability of Zr-based AB2 alloy electrodes”, J. Alloys Compd., 330-332, (2002) 825-830.
(62) E. Higuchi, K. Hidaka, Z. P. Li, S. Suda, H. Inoue, S. Nohara, C, Iwakura, “Effects of modified fluorination treatment on structural and electrochemical characteristics of AB2-type Laves phase alloy”, J. Alloys Compd., 335, (2002)277-280.
(63) E. Higuchi, Z. P. Li, S. Suda, H. Inoue, S. Nohara, C, Iwakura, “Structural and electrochemical characterization of fluorinated AB2-type Laves phase alloys obtained by different pulverization methods”, J. Alloys Compd., 335 (2002) 241-245.
(64) E. Higuchi, H. Miyoshi, Z. P. Li, S. Suda, Hiroshi Inoue, S. Nohara and C. Iwakura, “Effect of substitution with Cr on electrochemical characteristics of a fluorinated AB2-type Laves-phase alloy”, ITE Letters on Batteries, New Technologies & Medicine, 2(1), (2001)69-74.
(65) E. Higuchi, E. Toyota, Z. P. Li, S. Suda, H. Inoue, S. Nohara, C, Iwakura, “Effects of fluorination of AB2-type alloys and of mixing with AB5-type alloys on the charge-discharge characteristics”, Electrochim. Acta, 46, (2001)1191-1194.
(66) S. Suda, Y. -M. Sun, B. -H. Liu, Y. Zhou, S. Morimitsu, K. Arai, N. Tsukamoto, M. Uchida, Y. Candra, Z. -P. Li, "Catalytic Generation of Hydrogen by Applying Fluorinated-Metal Hydrides as Catalysts", J. Applied Physics A 72: (2001) 209-212.
(67) S. Suda, Y. -M. Sun, M. Uchida, B. -H. Liu, S. Morimitsu, K. Arai, Y. Zhou, N. Tsukamoto, Y. Candra, Z. -P. Li, "Fluorinated Metal Hydrides for the Catalytic Hydrolysis of Metal-Hydrogen Complexes", Metals and Materials International 7(1), (2001)73-75.
(68) Z. -P. Li, E. Higuchi, B. -H. Liu, S. Suda, “Effects of Fluorination Temperature on Surface Structure and Electrochemical Properties of AB 2 Electrode Alloys”, Electrochim. Acta 45, (2000) 1773-1779.
(69) B.-H. Liu, Z.-P. Li, E. Higuchi and S. Suda, “Corrosion and degradation behavior of Zr-based AB2alloy electrodes during electrochemical cycling”, J. Alloys Compd., 296, (2000)201-208.
(70) B.-H. Liu, Z.-P. Li, A. Okutsu and S. Suda, “A wet ball milling treatment of Zr-based AB2 alloys as negative electrode materials”, J. Alloys Compd., 296, (2000)148-151.
(71) Z. -P. Li, E. Higuchi, B. -H. Liu, S. Suda, “Electrochemical Properties and Characteristics of a Fluorinated AB 2-alloy”, J. Alloys Compd., 293-295, (1999)593-600.
(72) B.-H. Liu, Z.-P. Li, E. Higuchi and S. Suda, “Improvement of the electrochemical properties of Zr-based AB2 alloys by advanced fluorination technique”, J. Alloys Compd., 293-295, (1999)702-706.
(73) S. Suda, Z.-P. Li, Y.-M. Sun, B.-H. Liu and X.-P. Gao, “Surface passivation of metal hydrides for applications”, Mat. Res. Soc. Sympo., Vol.513,(1998)25-36.
(74) M. Sakashita, Z. P. Li and S. Suda, “fluorination mechanism and its effects on the electrochemical properties of metal hydrides”, J. Alloys Compd., 253-4, (1997)500-505.
(75) Z. -P. Li, T. Matsuoka, S. Suda, “An Investigation of Ca-based Hydride Electrode Materials”, Vacuum 47(6-8), (1996)893-897.
(76) Z. P. Li, and S. Suda, “Electrochemical durability of Ca-based alloys”, Electrochim. Acta, 40, No:4, (1995)467-471.
(77) Z. P. Li and S. Suda, “Effects of hydriding-dehydriding cycling on P-C-T and electrochemical properties of La-Ca-Ni-Al alloys”, J. Alloys Compd., 231, (1995)594-597.
(78) Z. P. Li and S. Suda, “A new family of hydride electrode materials based on CaNi5-type alloys”, J. Alloys Compd., 231, (1995)751-754.
(79) B.H. Liu, Z.P. Li, C.P. Chen, W.H. Liu and Q.D. Wang, “The effects of mechanical grinding on the hydrogen storage properties of MlNi4.7Al0.3 alloy”, J. Alloys Compd., 231, (1995)820-823.
(80) Z. P. Li and S. Suda, “The annealing effect on the durabilities of La-substituted CaNi5-type alloys”, J. Alloys Compd., 231, (1995)835-840.
(81) Z.-P. Li and S. Suda, “The inorganic compound coating effect on the durability of CaNi5electrode”, Proc. of the Symp. on HYDROGEN and METAL HYDRIDE BATTERIES, Vol.94-27, (1994)78-84.
(82) Z.-P. Li and S. Suda, “The metallurgical and electrochemical investigations of Ca-La-(NiAl)5alloys”, Proc. of the Symp. on HYDROGEN and METAL HYDRIDE BATTERIES, Vol.94-27, (1994)16-23.
(83) Z. P. Li, D. Y. Yan and S. Suda, “The effects of F-treatment level on the electrochemical behavior of LaNi4.7Al0.3”, Trans. Mat. Res. Soc. Jpn., Vol. 18B, (1994)1209-1212.
(84) Deyi Yan, Gary Sandrock, Zhoupeng Li, Xianglong Wang and Seijirau Suda, “Activation of Zr0.5Ti0.5V0.75Ni1.25 electrodes by hot alkaline solutions”, Trans. Mat. Res. Soc. Jpn., Vol. 18B, (1994)1213-1216.
(85) D.-Y Yan, Z. P. Li, and S. Suda, “Electrochemical properties of the Chemically-treated LaNi4.7Al0.3 and MmNi3.5Co0.7Al0.8”, Trans. Mat. Res. Soc. Jpn., Vol. 18B, (1994)1217-1219.
(86) Z.-P. Li, Y.-Q. Lei, B.-H. Liu, J. Wu and Q.-D. Wang, “The cycling mechanism and behavior of hydride electrodes in charging-discharging”, Z. Phy. Chem. Bd. 183, pp.1325-1330 (1994).
(87) C.-P. Chen, B.-H. Liu, Z.-P. Li, J. Wu and Q.-D. Wang, “The Activation mechanism of Mg-based hydrogen storage alloys”, Z. Phy. Chem. Bd. 181, (1993)817-825.
(88) B.-H. Liu, C.-P. Chen, Z.-P. Li, J. Wu and Q.-D. Wang, “The hydriding and dehydriding properties of some multi-component rare-earth magnesium alloys”, Z. Phy. Chem. Bd. 181, (1993)809-816.
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发表于 2018-5-21 17:15:39
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