Ti-V基固溶体/AB_5型镧镁基合金复合储氢材料的结构与电化学性能

两步电弧熔炼法制备Ti0.10Zr0.15V0.35Cr0.10Ni0.30+5wt%La0.85Mg0.25Ni4.5Co0.35Al0.15复合储氢合金,X射线衍射(XRD)和扫描电镜能谱(SEM-EDS)显示:复合储氢合金的主相是体心立方结构的钒基固溶体相和六方结构的C14Laves相,复合过程中生成了第二相.电化学研究表明:复合过程中存在明显的协同效应;在303 K时,复合合金电极的实际最大放电容量为361.8 mAh/g;在233 K时,复合合金电极的低温放电能力(LTD)是母体合金电极的4.05倍.与母体合金电极相比,复合合金电极的高倍率放电性能(HRD)提高了26.87%,电荷转移电阻(Rct)减小了37.25 m,同时交换电流密度(I0)增大了115.45 mA/g,合金体内氢的扩散系数(D)增大了6.13×10 10cm2/s.

Ti_(0.10)Zr_(0.15)V_(0.35)Cr_(0.10)Ni_(0.30)+5wt% LaNi_5复合储氢合金的电化学性能与协同效应

为了改善钛钒基固溶体合金的电化学性能,利用两步电弧熔炼法制备复合储氢合金Ti0.10Zr0.15V0.35Cr0.10Ni0.30+5wt%LaNi5,X-射线衍射(XRD)和场发射扫描电镜-能谱(FESEM-EDS)显示:复合储氢合金的主相是体心立方结构的钒基固溶体相和六方结构的C14 Laves相,复合过程中生成了第二相。电化学测试结果表明:复合合金电极的P-C-T特征、活化性能、最大放电容量、循环稳定性、低温放电性能和动力学特性均较母体合金有显著改善。复合合金电极的活化周期数为5,最大放电容量为353.9 mAh.g-1,233 K时低温放电能力为50.26%。该复合合金电极的最大储氢容量、平台压、电荷转移电阻和交换电流密度均存在协同效应;在任意循环、在高/低温下以及在高倍率放电过程中,该复合合金电极的放电容量均存在协同效应。

TiV1．1Mn0．9Ni0．5＋20％ZrCr2储氢复合材料的循环稳定性

用两步电弧熔炼法制备储氢复合合金材料TiV1.1Mn0.9Ni0.5+20%ZrCr2,用XRD、能谱(EDS)、电感耦合等离子体-光学发射光谱(ICP-OES)和SEM分析研究储氢复合合金材料电极的微观结构、循环稳定性和协同效应。复合合金具有与母体合金相同的双相结构;复合合金电极的最大放电容量存在协同效应,在任何一次循环时,实际放电容量均有明显的协同效应;母体合金电极第15次循环的容量保持率仅为5.84%,复合合金电极第15次和第80次循环的容量保持率分别为96.22%和68.72%,原因可能是ZrCr2合金的添加能提高合金电极在KOH溶液中抗腐蚀、抗氧化和抗粉化的能力。

Electrochemical hydrogen storage characteristics of Ti_(0.10)Zr_(0.15)V_(0.35)Cr_(0.10)Ni_(0.30)-10% LaNi_3 composite and its synergetic effect

Hydrogen storage composite alloy Ti0.10Zr0.15V0.35Cr0.10Ni0.30–10% LaNi3 was prepared by two-step arc-melting to improve the electro-catalytic activity and the kinetic performance of Ti-V-based solid solution alloy. The electrochemical properties and synergetic effect of the composite alloy electrode were systematically investigated by using X-ray diffractometry, field emission scanning electron microscopy, energy-dispersive spectrometry, electrochemical impedance spectroscopy and galvanostatic charge/discharge test. It is found that the main phase of the composite alloy is composed of V-based solid solution phase with a BCC structure and C14 Laves phase with hexagonal structure, while the secondary phase is formed in the composite alloy. The comprehensive electrochemical properties of the composite alloy electrode are significantly improved. The activation cycle number, the maximum discharge capacity and the low temperature dischargeability of the composite alloy are 5 cycles, 362.5 mA-h/g and 65.84% at 233 K, respectively. It is suggested that distinct synergetic effect occurs in the activation process, composite process, cyclic process and discharge process at a low or high temperature under different current densities, in the charge–transfer resistance and exchange current density.

LaNi_5添加对Ti_(1.8)(VFe)CrNi_(0.2)合金电化学性能的影响

采用XRD、SEM+EDS和电化学装置对复合合金Ti_(1.8)(VFe)CrNi_(0.2)+XLaNi_5(X=0,5,10,20,质量分数,%,下同)的组织形貌、相结构及其在323 K下电化学性能进行表征。结果表明,随LaNi_5的添加,合金由胞状晶逐渐转变为树枝晶;相结构由bcc结构的Ti-V-Cr基相和体心四方结构的Cr-Ni-Ti-Fe主相转变为Ti-V-Cr-Fe-Ni为主相的bcc结构和La-Ni第二相。电化学性能显示,随X的变化,复合合金的活化及放电容量等呈规律性变化。X=5时,合金的活化和放电容量明显改善,仅需9次活化就达到最大值360 mAh/g,这是因为棒状晶的形成和第二相Cr-Ni-Ti-Fe相与Ti-V-Cr基相独特的协同作用所致。