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[130] M. Zhang, X. Xiao*, B. Luo, M. Liu, M. Chen, L. Chen. Superior de/hydrogenation performances of MgH2 catalyzed by 3D flower-like TiO2@C nanostructures. Journal of Energy Chemistry 2020; 46: 191-198.
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[109] Y. W. Zhang, X. Z. Xiao*, B. S. Luo, X. Huang, M. J. Liu, L. X. Chen. Synergistic Effect of LiBH4 and LiAIH4 Additives on Improved Hydrogen Storage Properties of Unexpected High Capacity Magnesium Hydride. Journal of Physical Chemistry C 2018; 122: 2528-2538.
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[107] Z. D. Yao, L. X. Liu, X. Z. Xiao*, C. T. Wang, L. J. Jiang, L. X. Chen. Effect of rare earth doping on the hydrogen storage performance of Ti1.02Cr1.1Mn0.3Fe0.6 alloy for hybrid hydrogen storage application. Journal of Alloys and Compounds 2018; 731: 524-530.
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[104] Y. Q. Jiang, X. L. Fan, M. Chen, X. Z. Xiao* et al. AuPd Nanoparticles Anchored on Nitrogen-Decorated Carbon Nanosheets with Highly Efficient and Selective Catalysis for the Dehydrogenation of Formic Acid. Journal of Physical Chemistry C 2018; 122: 4792-4801.
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[101] X. Huang, X. Z. Xiao*, X. C. Wang et al. Synergistic Catalytic Activity of Porous Rod-like TMTiO3 (TM = Ni and Co) for Reversible Hydrogen Storage of Magnesium Hydride. Journal of Physical Chemistry C 2018; 122: 27973-27982.
[100] C. J. Cheng, M. Chen, X. Z. Xiao*, X. Huang, J. G. Zheng, L. X. Chen. Superior Reversible Hydrogen Storage Properties and Mechanism of LiBH4-MgH2-Al Doped with NbF5 Additive. Journal of Physical Chemistry C 2018; 122: 7613-7620.
[99] J. G. Zheng, X. Z. Xiao, L. T. Zhang, S. Q. Li, H. W. Ge, L. X. Chen. Facile synthesis of bowl-like 3D Mg(BH4)2-NaBH4-fluorographene composite with unexpected superior dehydrogenation performances. Journal of Materials Chemistry A 2017; 5: 9723-9732.
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[94] L. T. Zhang, L. X. Chen, X. L. Fan, X. Z. Xiao, J. G. Zheng, X. Huang. Enhanced hydrogen storage properties of MgH2 with numerous hydrogen diffusion channels provided by Na2Ti3O7 nanotubes. Journal of Materials Chemistry A 2017; 5: 6178-6185.
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[88] Y. Q. Jiang, X. L. Fan, X. Z. Xiao et al. La2O3-modified highly dispersed AuPd alloy nanoparticles and their superior catalysis on the dehydrogenation of formic acid. International Journal of Hydrogen Energy 2017; 42: 9353-9360.
[87] X. Huang, X. Xiao, W. Zhang et al. Transition metal (Co, Ni) nanoparticles wrapped with carbon and their superior catalytic activities for the reversible hydrogen storage of magnesium hydride. Physical Chemistry Chemical Physics 2017; 19: 4019-4029.
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[85] C. C. Xu, X. Z. Xiao, J. Shao, L. X. Liu, T. Qin, and L. X. Chen. Effects of Ti-based additives on Mg2FeH6 dehydrogenation properties, Transactions of Nonferrous Metals Society of China, 2016, 26(3), 791-798.
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[83] G. Tu, J. He, X. Xiao, L. Chen, Q. Ren, X. Du, and M. Luo: 'Synergetic Effect of NbH@h-BN on Dehydrogenation of LiBH4', Chemical Journal of Chinese Universities-Chinese, 2016, 37(10), 1757-1762.
[82] M. Li, X. L. Fan, X. Z. Xiao, X. Huang, Y. Q. Jiang, and L. X. Chen. Ternary perovskite nickel titanate/reduced graphene oxide nano-composite with improved lithium storage properties', Rsc Advances, 2016, 6(66), 61312-61318.
[81] Y. Q. Jiang, X. L. Fan, X. Z. Xiao, T. Qin, L. T. Zhang, F. L. Jiang, M. Li, S. Q. Li, H. W. Ge, and L. X. Chen. Novel AgPd hollow spheres anchored on graphene as an efficient catalyst for dehydrogenation of formic acid at room temperature, Journal of Materials Chemistry A, 2016, 4(2), 657-666.
[80] X. Huang, X. Z. Xiao, J. Shao, B. Zhai, X. L. Fan, C. J. Cheng, S. Q. Li, H. W. Ge, Q. D. Wang, and L. X. Chen. Building robust architectures of carbon-wrapped transition metal nanoparticles for high catalytic enhancement of the 2LiBH4-MgH2 system for hydrogen storage cycling performance, Nanoscale, 2016, 8(31), 14898-14908.
[79] Guoping Tu, Xuezhang Xiao, Yiqun Jiang, Teng Qin, Shouquan Li, Hongwei Ge, Qidong Wang and Lixin Chen. Composite Cooperative enhancement on the hydrogen desorption kinetics of LiBH4 by co-doping with NbCl5 and hexagonal BN, International Journal of Hydrogen Energy, 2015; 40, 10527–10535.
[78] Guoping Tu, Xuezhang Xiao, Teng Qin, Yiqun Jiang, Shouquan Li, Hongwei Ge, Qidong Wang and Lixin Chen. Significantly improved de/rehydrogenation properties of lithium borohydride modified with hexagonal boron nitride, RSC Advances, 2015; 5, 51110–51115.
[77] Jie Shao, Xuezhang Xiao, Xiulin Fan, Xu Huang, Bing Zhai, Shouquan Li, Hongwei Ge, Qidong Wang, Lixin Chen. Enhanced hydrogen storage capacity and reversibility of LiBH4 nanoconfined in the densified zeolite-templated carbon with high mechanical stability, Nano Energy, 2015; 15, 244−255.
[76] C. C. Xu, X. Z. Xiao, J. Shao, L. T. Zhang, T. Qin, L. X. Chen. Effects of Ti-based additives on the Mg2FeH6 dehydrogenation properties, Transactions of Nonferrous Metals Society of China, 2015; in press.
[75] Liuting Zhang, Xuezhang Xiao, Chenchen Xu, Jiaguang Zheng, Xiulin Fan, Jie Shao, Shouquan Li, Hongwei Ge, Qidong Wang, Lixin Chen. Remarkably Improved Hydrogen Storage Performance of MgH2 Catalyzed by Multi-valence NbHx Nanoparticles, Journal of Physical Chemistry C, 2015; 119, 8554−8562.
[74] Langxia Liu, Lixin Chen, Xuezhang Xiao, Chenchen Xu, Jian Sun, Shouquan Li, Hongwei Ge, Lijun Jiang. Influence of annealing treatment on the microstructure and hydrogen storage performance of Ti1.02Cr1.1Mn0.3Fe0.6 alloy for hybrid hydrogen storage application. Journal of Alloys and Compounds, 2015; 636: 117-123.
[73] X. Z. Xiao, C. C. Xu, J. Shao, L. T. Zhang, T. Qin, S. Q. Li, H. W. Ge, Q. D. Wang, L. X. Chen. Remarkable Hydrogen Desorption Properties and Mechanisms for Mg2FeH6@MgH2 Core-Shell Nanostructure, Journal of Materials Chemistry A, 2015; 3: 5517-5524.
[72] L. T. Zhang, X. Z. Xiao, X. L. Fan, S. Q. Li, H. W. Ge, Q. D. Wang, L. X. Chen. Fast hydrogen release under moderate conditions from NaBH4 destabilized by fluorographite, RSC Advances, 2014; 4: 2550-2556.
[71] L. T. Zhang, L. X. Chen, X. Z. Xiao, X. L. Fan, J. Shao, S. Q. Li, H. W. Ge, Q. D. Wang. Fluorographene nanosheets enhanced hydrogen absorption and desorption performances of magnesium hydride, International Journal of Hydrogen Energy, 2014; 39: 12715-12726.
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[69] Xiulin Fan, JieShao, XuezhangXiao, XinhuaWang, Shouquan Li, HongweiGe, LixinChen. SnLi4.4 nanoparticles encapsulated in carbon matrix as high performance anode material for lithium-ion batteries, Nano Energy, 2014; 9, 196−203.
[68] X. Z. Xiao, S. K. Wang, G. P. Tu, L. T. Zhang, X. L. Fan, S. Q. Li, H. W. Ge, Q. D. Wang, L. X. Chen. Enhanced reversible hydrogen storage performance of NbCl5 doped 2LiH-MgB2 composite, International Journal of Hydrogen Energy, 2014; 39: 2132-2141.
[67] X. Z. Xiao, S. K. Wang, X. L. Fan, C. C. Xu, J. Sun, Q. D. Wang, L. X. Chen. Improved de/hydrogenation properties and favorable reaction mechanism of CeH2 + KH co-doped sodium aluminum hydride, International Journal of Hydrogen Energy, 2014; 39: 6577-6587.
[66] J. Shao, X. Z. Xiao, X. L. Fan, L. T. Zhang, S. Q. Li, H. W. Ge, Q. D. Wang, L. X. Chen. Low-Temperature Reversible Hydrogen Storage Properties of LiBH4: A Synergetic Effect of Nanoconfinement and Nanocatalysis, Journal of Physical Chemistry C, 2014; 118: 11252-11260.
[65] L. Y. Han, X. Z. Xiao, S. K. Wang, X. L. Fan, S. Q. Li, H. W. Ge, L. X. Chen. Dehydrogenation Behavior and Mechanism of LiBH4 Doped with Ce2Mg17 and Its Hydride, Rare Metal Materials and Engineering, 2014; 43: 1935-1938.
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[63] X. L. Fan, X. Z. Xiao, L. X. Chen, J. Shao, L. T. Zhang, S. Q. Li, H. W. Ge, Q. D. Wang. Superior Catalytic Effects of Transition Metal Boride Nanoparticles on the Reversible Hydrogen Storage Properties of Li-Mg-B-H System, Particle & Particle Systems Characterization, 2014; 31: 195-200.
[62] X. L. Fan, J. Shao, X. Z. Xiao, X. H. Wang, S. Q. Li, H. W. Ge, L. X. Chen, C. S. Wang. In situ synthesis of SnO2 nanoparticles encapsulated in micro/mesoporous carbon foam as a high-performance anode material for lithium ion batteries, Journal of Materials Chemistry A, 2014; 2: 18367-18374.
[61] X. L. Fan, J. Shao, X. Z. Xiao, L. X. Chen, X. H. Wang, S. Q. Li, H. W. Ge. Carbon encapsulated 3D hierarchical Fe3O4 spheres as advanced anode materials with long cycle lifetimes for lithium-ion batteries, Journal of Materials Chemistry A, 2014; 2: 14641-14648.
[60] Z. W. Chen, X. Z. Xiao, L. X. Chen, X. L. Fan, L. X. Liu, S. Q. Li, H. W. Ge, Q. D. Wang. Influence of Ti super-stoichiometry on the hydrogen storage properties of Ti1+xCr1.2Mn0.2Fe0.6 (x=0-0.1) alloys for hybrid hydrogen storage application, Journal of Alloys and Compounds, 2014; 585: 307-311.
[59] X. Z. Xiao, L. T. Zhang, X. L. Fan, L. Y. Han, J. Shao, S. Q. Li, H. W. Ge, Q. D. Wang, L. X. Chen. Synergetic Effect of in Situ Formed Nano NbH and LiH1-xFx for Improving Reversible Hydrogen Storage Properties of the Li-Mg-B-H System, Journal of Physical Chemistry C, 2013; 117: 12019-12025.
[58] Z. Wu, L. X. Chen, X. Z. Xiao, X. L. Fan, S. Q. Li, Q. D. Wang. Influence of lanthanon hydride catalysts on hydrogen storage properties of sodium alanates, Journal of Rare Earths, 2013; 31: 502-506.
[57] S. K. Wang, Z. J. Li, X. Z. Xiao, X. L. Fan, Z. W. Chen, S. Q. Li, H. W. Ge, L. X. Chen. Influence of KH on Reversible Dehydriding Performance of Na-Al-H Complex Hydride, Acta Physico-Chimica Sinica, 2013; 29: 1804-1808.
[56] J. Shao, X. Z. Xiao, L. X. Chen, X. L. Fan, L. Y. Han, S. Q. Li, H. W. Ge, Q. D. Wang. Enhanced hydriding-dehydriding performance of a 2LiH-MgB2 composite by the catalytic effects of Ni-B nanoparticles, Journal of Materials Chemistry A, 2013; 1: 10184-10192.
[55] J. Shao, X. Z. Xiao, X. L. Fan, L. X. Chen, H. Y. Zhu, S. Q. Yu, Z. D. Gong, S. Q. Li, H. W. Ge, Q. D. Wang. A low temperature mechanochemical synthesis and characterization of amorphous Ni-B ultrafine nanoparticles, Mater. Lett., 2013; 109: 203-206.
[54] X. L. Fan, X. Z. Xiao, J. Shao, L. T. Zhang, S. Q. Li, H. W. Ge, Q. D. Wang, L. X. Chen. Size effect on hydrogen storage properties of NaAlH4 confined in uniform porous carbons, Nano Energy, 2013; 2: 995-1003.
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[52] X. L. Fan, X. Z. Xiao, L. X. Chen, X. H. Wang, S. Q. Li, H. W. Ge, Q. D. Wang. High catalytic efficiency of amorphous TiB2 and NbB2 nanoparticles for hydrogen storage using the 2LiBH4-MgH2 system, Journal of Materials Chemistry A, 2013; 1: 11368-11375.
[51] Z. W. Chen, X. Z. Xiao, L. X. Chen, X. L. Fan, L. X. Liu, S. Q. Li, H. W. Ge, Q. D. Wang. Development of Ti-Cr-Mn-Fe based alloys with high hydrogen desorption pressures for hybrid hydrogen storage vessel application, International Journal of Hydrogen Energy, 2013; 38: 12803-12810.
[50] X. Z. Xiao, J. Shao, L. X. Chen, H. Q. Kou, X. L. Fan, S. S. Deng, L. T. Zhang, S. Q. Li, H. W. Ge, Q. D. Wang. Effects of NbF5 addition on the de/rehydrogenation properties of 2LiBH4/MgH2 hydrogen storage system, International Journal of Hydrogen Energy, 2012; 37: 13147-13154.
[49] J. Shao, X. Z. Xiao, L. X. Chen, X. L. Fan, S. Q. Li, H. W. Ge, Q. D. Wang. Enhanced hydriding-dehydriding performance of 2LiBH4-MgH2 composite by the catalytic effects of transition metal chlorides, Journal of Materials Chemistry, 2012; 22: 20764-20772.
[48] Y. Li, X. Z. Xiao, L. X. Chen, L. Y. Han, J. Shao, X. L. Fan, S. Q. Li, Q. D. Wang. Effects of Fluoride Additives on the Hydrogen Storage Performance of 2LiBH4-Li3AlH6 Destabilized System, Journal of Physical Chemistry C, 2012; 116: 22226-22230.
[47] C. X. Li, X. Z. Xiao, P. Q. Ge, J. W. Xue, S. Q. Li, H. W. Ge, L. X. Chen. Investigation on synthesis, structure and catalytic modification of Ca(AlH4)2 complex hydride, International Journal of Hydrogen Energy, 2012; 37: 936-941.
[46] H. Q. Kou, X. Z. Xiao, J. X. Li, S. Q. Li, H. W. Ge, Q. D. Wang, L. X. Chen. Effects of fluoride additives on dehydrogenation behaviors of 2LiBH4+MgH2 system, International Journal of Hydrogen Energy, 2012; 37: 1021-1026.
[45] K. Jiang, X. Z. Xiao, L. X. Chen, L. Y. Han, S. Q. Li, H. W. Ge, Q. D. Wang. A comparative study of the hydrogen storage properties of LiBH4 doping with CaHCl and CaH2, Journal of Alloys and Compounds, 2012; 539: 103-107.
[44] Z. M. Hang, X. Z. Xiao, S. Q. Li, H. W. Ge, C. P. Chen, L. X. Chen. Influence of heat treatment on the microstructure and hydrogen storage properties of Ti10V77Cr6Fe6Zr alloy, Journal of Alloys and Compounds, 2012; 529: 128-133.
[43] S. S. Deng, X. Z. Xiao, L. Y. Han, Y. Li, S. Q. Li, H. W. Ge, Q. D. Wang, L. X. Chen. Hydrogen storage performance of 5LiBH4+Mg2FeH6 composite system, International Journal of Hydrogen Energy, 2012; 37: 6733-6740.
[42] S. S. Deng, X. Z. Xiao, L. X. Chen, L. Y. Han, S. Q. Li, H. W. Ge, Q. D. Wang. Effects of Stoichiometry and Dehydrogenation Back-pressure on the Dehydrogenation Behavior of LiBH4+xMg2NiH4 Composites, Chemical Journal of Chinese Universities-Chinese, 2012; 33: 2030-2034.
[41] X. Z. Xiao, K. R. Yu, X. L. Fan, Z. Wu, X. H. Wang, C. P. Chen, Q. D. Wang, L. X. Chen. Synthesis and hydriding/dehydriding properties of nanosized sodium alanates prepared by reactive ball-milling, International Journal of Hydrogen Energy, 2011; 36: 539-548.
[40] X. Z. Xiao, C. X. Li, L. X. Chen, X. L. Fan, H. Q. Kou, Q. D. Wang. Synthesis and dehydrogenation of CeAl4-doped calcium alanate, Journal of Alloys and Compounds, 2011; 509: S743-S746.
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[38] C. X. Li, X. Z. Xiao, L. X. Chen, K. Jiang, S. Q. Li, Q. D. Wang. Synthesis of calcium alanate and its dehydriding performance enhanced by FeF3 doping, Journal of Alloys and Compounds, 2011; 509: 590-595.
[37] H. Q. Kou, X. Z. Xiao, L. X. Chen, S. Q. Li, Q. D. Wang. Formation mechanism of MgB2 in 2LiBH4 + MgH2 system for reversible hydrogen storage, Transactions of Nonferrous Metals Society of China, 2011; 21: 1040-1046.
[36] K. Jiang, X. Z. Xiao, S. S. Deng, M. Zhang, S. Q. Li, H. W. Ge, L. X. Chen. A Novel Li-Ca-B-H Complex Borohydride: Its Synthesis and Hydrogen Storage Properties, Journal of Physical Chemistry C, 2011; 115: 19986-19993.
[35] X. L. Fan, X. Z. Xiao, L. X. Chen, S. Q. Li, Q. D. Wang. Investigation on the nature of active species in the CeCl3-doped sodium alanate system, Journal of Alloys and Compounds, 2011; 509: S750-S753.
[34] X. L. Fan, X. Z. Xiao, L. X. Chen, S. Q. Li, H. W. Ge, Q. D. Wang. Enhanced Hydriding-Dehydriding Performance of CeAl2-Doped NaAlH4 and the Evolvement of Ce-Containing Species in the Cycling, Journal of Physical Chemistry C, 2011; 115: 2537-2543.
[33] X. L. Fan, X. Z. Xiao, L. X. Chen, S. Q. Li, H. W. Ge, Q. D. Wang. Direct synthesis and hydrogen storage behaviors of nanocrystalline Na2LiAlH6, Journal of Materials Science, 2011; 46: 3314-3318.
[32] X. L. Fan, X. Z. Xiao, L. X. Chen, L. Y. Han, S. Q. Li, H. W. Ge, Q. D. Wang. Hydriding-dehydriding kinetics and the microstructure of La- and Sm-doped NaAlH4 prepared via direct synthesis method, International Journal of Hydrogen Energy, 2011; 36: 10861-10869.
[31] X. L. Fan, X. Z. Xiao, L. X. Chen, L. Y. Han, S. Q. Li, H. W. Ge, Q. D. Wang. Thermodynamics, Kinetics, and Modeling Investigation on the Dehydrogenation of CeAl4-Doped NaAlH4 Hydrogen Storage Material, Journal of Physical Chemistry C, 2011; 115: 22680-22687.
[30] L. X. Chen, X. L. Fan, X. Z. Xiao, J. W. Xue, S. Q. Li, H. W. Ge, C. P. Chen. Influence of TiC catalyst on absorption/desorption behaviors and microstructures of sodium aluminum hydride, Transactions of Nonferrous Metals Society of China, 2011; 21: 1297-1302.
[29] X. Z. Xiao, G. C. Liu, S. K. Peng, K. R. Yu, S. Q. Li, C. P. Chen, L. X. Chen. Microstructure and hydrogen storage characteristics of nanocrystalline Mg plus x wt% LaMg2Ni (x=0-30) composites, International Journal of Hydrogen Energy, 2010; 35: 2786-2790.
[28] S. K. Peng, X. Z. Xiao, R. J. Xu, L. Li, F. Wu, S. Q. Li, Q. D. Wang, L. X. Chen. Hydrogen storage behaviors and microstructure of MF3 (M=Ti, Fe)-doped magnesium hydride, Transactions of Nonferrous Metals Society of China, 2010; 20: 1879-1884.
[27] Z. M. Hang, X. Z. Xiao, K. R. Yu, S. Q. Li, C. P. Chen, L. X. Chen. Influence of Fe content on the microstructure and hydrogen storage properties of Ti16Zr5Cr22V57-xFex (x=2-8) alloys, International Journal of Hydrogen Energy, 2010; 35: 8143-8148.
[26] Z. M. Hang, X. Z. Xiao, D. Z. Tan, Z. H. He, W. P. Li, S. Q. Li, C. P. Chen, L. X. Chen. Microstructure and hydrogen storage properties of Ti10V84-xFe6Zrx (x=1-8) alloys, International Journal of Hydrogen Energy, 2010; 35: 3080-3086.
[25] Z. M. Hang, L. X. Chen, X. Z. Xiao, S. Q. Li, C. P. Chen, Y. Q. Lei, Q. D. Wang. The effect of Cr content on the structural and hydrogen storage characteristics of Ti10V80-xFe6Zr4Crx (x=0-14) alloys, Journal of Alloys and Compounds, 2010; 493: 396-400.
[24] X. Z. Xiao, X. L. Fan, K. R. Yu, S. Q. Li, C. P. Chen, Q. D. Wang, L. X. Chen. Catalytic Mechanism of New TiC-Doped Sodium Alanate for Hydrogen Storage, Journal of Physical Chemistry C, 2009; 113: 20745-20751.
[23] X. Z. Xiao, L. X. Chen, Z. M. Hang, X. H. Wang, S. Q. Li, C. P. Chen, Y. Q. Lei, Q. D. Wang. Microstructures and electrochemical hydrogen storage properties of novel Mg-Al-Ni amorphous composites, Electrochemistry Communications, 2009; 11: 515-518.
[22] X. Z. Xiao, L. X. Chen, X. L. Fan, X. H. Wang, C. P. Chen, Y. Q. Lei, Q. D. Wang. Direct synthesis of nanocrystalline NaAlH4 complex hydride for hydrogen storage, Applied Physics Letters, 2009; 94.
[21] Y. M. Jia, F. Y. Liu, X. Z. Xiao, Z. M. Hang, Y. Q. Lei, L. X. Chen. Microstructure and Electrochemical Properties of V2.1TiNi0.4Zr0.06Cu0.03M0.10 (M=Cr, Co, Fe, Nb, Ta) Hydrogen Storage Alloys, Acta Physico-Chimica Sinica, 2009; 25: 247-252.
[20] Y. M. Jia, L. X. Chen, X. Z. Xiao, K. R. Yu, T. Ying, Y. Q. Lei. Effect of quenching treatment on the phase structure and electrochemical properties of V2.1TiNi0.4Zr0.06Mn0.05 alloy, International Journal of Hydrogen Energy, 2009; 34: 7756-7760.
[19] X. L. Fan, X. Z. Xiao, J. C. Hou, Z. Zhang, Y. B. Liu, Z. Wu, C. P. Chen, Q. D. Wang, L. Chen. Reversible hydrogen storage behaviors and microstructure of TiC-doped sodium aluminum hydride, Journal of Materials Science, 2009; 44: 4700-4704.
[18] X. L. Fan, X. Z. Xiao, L. X. Chen, K. R. Yu, Z. Wu, S. Q. Li, Q. D. Wang. Active species of CeAl4 in the CeCl3-doped sodium aluminium hydride and its enhancement on reversible hydrogen storage performance, Chemical Communications, 2009: 6857-6859.
[17] X. Z. Xiao, L. X. Chen, X. H. Wang, S. Q. Li, C. P. Chen, Q. D. Wang. Reversible hydrogen storage properties and favorable co-doping mechanism of the metallic Ti and Zr co-doped sodium aluminum hydride, International Journal of Hydrogen Energy, 2008; 33: 64-73.
[16] X. Z. Xiao, L. X. Chen, X. L. Fan, H. W. Ge, S. Q. Li, T. Ying, X. H. Wang, C. P. Chen. Influence of Ti-Zr catalysts on reversible hydrogen storage characteristics of NaH/Al composite, Acta Physico-Chimica Sinica, 2008; 24: 423-427.
[15] X. Z. Xiao, X. H. Wang, L. X. Chen, S. Q. Li, Y. Tang, C. P. Chen. Microstructure and hydrogen storage properties of La1.8Ca0.2Mg14Ni3 + x% Ti composites, Rare Metal Materials and Engineering, 2007; 36: 790-793.
[14] X. Z. Xiao, L. X. Chen, X. H. Wang, Q. D. Wang, C. P. Chen. The hydrogen storage properties and microstructure of Ti-doped sodium aluminum hydride prepared by ball-milling, International Journal of Hydrogen Energy, 2007; 32: 2475-2479.
[13] X. Z. Xiao, L. X. Chen, X. H. Wang, S. Q. Li, Q. D. Wang, C. P. Chen. Influence of temperature and hydrogen pressure on the hydriding/dehydriding behavior of Ti-doped sodium aluminum hydride, International Journal of Hydrogen Energy, 2007; 32: 3954-3958.
[12] X. Z. Xiao, L. X. Chen, X. H. Wang, S. Q. Li, Z. M. Hang, C. P. Chen, Q. D. Wang. Dehydriding properties of Ti or/and Zr-doped sodium aluminum hydride prepared by ball-milling, Physica Scripta, 2007; T129: 95-98.
[11] X. Z. Xiao, X. H. Wang, L. H. Gao, L. Wang, C. P. Chen. Electrochemical properties of amorphous Mg-Fe alloys mixed with Ni prepared by ball-milling, Journal of Alloys and Compounds, 2006; 413: 312-318.
[10] X. Z. Xiao, L. X. Chen, X. H. Wang, S. Q. Li, C. P. Chen. Preparation and hydrogen storage characteristics of Ti-NaAlH4 complex hydride, Acta Physico-Chimica Sinica, 2006; 22: 1511-1515.
[9] X. Z. Xiao, C. P. Chen, X. H. Wang, L. X. Chen. Mechanical ball milling preparation and electrochemical hydrogen storage properties of amorphous Mg-Fe composites, Chemical Journal of Chinese Universities-Chinese, 2006; 27: 116-120.
[8] X. H. Wang, X. Z. Xiao, L. X. Chen, S. Q. Li, C. P. Chen. Microstructure and hydrogen storage properties of Ti-doped NaH/Al composites prepared by ball-milling, Chemical Journal of Chinese Universities-Chinese, 2006; 27: 1360-1362.
[7] L. Wang, X. H. Wang, L. X. Chen, C. P. Chen, X. Z. Xiao, L. H. Gao, Q. D. Wang. Electrode properties of La2Mg17 alloy ball-milled with xwt.% cobalt powder (x=50, 100, 150 and 200), Journal of Alloys and Compounds, 2006; 414: 248-252.
[6] L. Wang, X. H. Wang, L. X. Chen, C. P. Chen, X. Z. Xiao, L. H. Gao, Q. D. Wang. Effects of ball-milling time and Bi2O3 addition on electrochemical performance of ball-milled La2Mg17+200 wt.% Ni composites, Journal of Alloys and Compounds, 2006; 416: 194-198.
[5] Y. Tang, X. H. Wang, X. Z. Xiao, S. L. Du, Y. Q. Lei. Microstructure and electrochemical properties of amorphous composites of ball-milled Mg2Ni0.95Sn0.05 + x wt% Ni, Rare Metal Materials and Engineering, 2006; 35: 1303-1307.
[4] S. L. Du, X. H. Wang, L. X. Chen, S. Q. Li, C. P. Chen, Y. Tang, X. Z. Xiao. Microstructure and hydrogen storage properties of Ti1.0VxMn2-x(x=0.6 to 1.6) alloys, Rare Metal Materials and Engineering, 2006; 35: 1285-1288.
[3] X. Z. Xiao, C. P. Chen, X. H. Wang, L. X. Chen, L. Wang, L. H. Gao. Microstructure and electrochemical properties of amorphous Mg-Fe-Ni hydrogen storage electrode material, Acta Physico-Chimica Sinica, 2005; 21: 565-568.
[2] L. Wang, X. H. Wang, C. P. Chen, X. Z. Xiao. Electrochemical properties of CeMg12+x%Ni composites (x=0 similar to 200) prepared by ball-milling, Journal of Rare Earths, 2005; 23: 382-385.
[1] L. H. Gao, C. P. Chen, L. X. Chen, X. H. Wang, J. W. Zhang, X. Z. Xiao, Q. D. Wang. Hydriding/dehydriding behaviors of La1.8Ca0.2Mg14Ni3 alloy modified by mechanical ball-milling under argon, Journal of Alloys and Compounds, 2005; 399: 178-182.
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