储氢材料

金属Pd是重要的储氢材料。

Palladium is an important hydrogen storage material .

球磨La2Mg（17）复合储氢材料结构及电化学性能研究

Investigation on the Phase Structure and Electrochemical Performances of Ball-milled La_2Mg_ ( 17 ) Composite Hydrogen Storage Material

含Al–H键络合物储氢材料研究进展

Research Progress of Complex Hydrogen Storage Materials with Al – H Bond

储氢材料镁镍合金Mg2NiH4氢化燃烧合成反应机理

Hydriding Combustion Synthesis of Hydrogen Storage Alloy of Mg_2NiH_4 and Its Reaction Mechanism

储氢材料新合成方法的研究&置换-扩散法合成Mg2Cu

A new method for the synthesis of hydrogen storage compounds & replacement-diffusion method for mg_2cu

AB2型储氢材料表面吸氢的光电子谱研究

Investigation of hydrogen adsorption on AB_2 alloy surfaces using UPS

本文首先综述了储氢材料，特别是Mg基储氢合金的研究进展和存在的问题。

The development and key problem of hydrogen storage materials , especially for Mg-based hydrogen storage alloys , were reviewed firstly .

氢化燃烧合成与机械合金化复合制备LaMg（11.5）Ni（0.5）储氢材料

Hydrogen storage material of LaMg_ ( 11.5 ) Ni_ ( 0.5 ) prepared by hydriding combustion synthesis followed by mechanical milling

Mg+40wt.%TiFe（Mn）非晶复合储氢材料吸氢性能研究

Hydriding Properties of Mg + 40wt . % TiFe ( Mn ) Amorphous Composite Material Prepared by Ball Milling

RM5型储氢材料的预处理及对合成氨的催化机制

Preprocessing of the rm_5 series hydrogen storage materials and its catalysis mechanism on synthetic ammonia

Mg2Ni纳米晶储氢材料的机械合金化制备工艺研究

Investigation of the Preparation of Mg_2Ni Nanocrystalline Hydrogen-storage Materials by Mechanical Alloying

LaNi（4.75）Al（0.25）储氢材料的密度泛函理论研究

The Density Functional Theory Study for LaNi_ ( 4.75 ) Al_ ( 0.25 ) Hydrogen Storage Materials

金属有机骨架化合物（MOFs）作为储氢材料的研究进展

Metal-Organic Frameworks ( MOFs ) as Hydrogen Storage Materials

LaNi5基储氢材料微观特性研究

The Research on the Microstructure Characteristics of LaNi_5-based Hydrogen Storage Material

LaNi5储氢材料中储氢状态的理论研究

Theoretical study on state of storage hydrogen in hydrogen storage material lani_5

LaNi5型储氢材料最大储氢量的讨论

Maximum Hydrogen Storage Capacity of LaNi_5 Type Hydrogen Storage Material

采用扩散烧结的工艺制备出Mg-Cu多相储氢材料；

Mg-Cu hydrogen storage composite was prepared by diffusion sintering method .

难活化储氢材料TiFe合金的表面改性

Surface Modification of TiFe Alloy For Hydrogen Sorption

新型储氢材料Li-Mg-N-H体系的储放氢性能研究

Hydrogen Storage Properties of Li-Mg-N-H System

目前广泛研究中的储氢材料有：碳基纳米材料、金属氢化物、MOFs结构储氢材料和有机小分子储氢材料。

At present , extensive research in the hydrogen storage material such as carbon-based nano material , metal hydride , MOFs structures and organic hydrogen storage material .

碳纳米管（CNTs）自被发现以来，由于其独特的结构，在电子器件，储氢材料，催化剂载体等方面有着广泛的应用，特别是它这种独特的结构和晶态非常适合作为催化剂负载材料。

Since the discover of carbon nanotubes ( CNTs ), they have attracted much attention from scientists in the field of electronic material , hydrogen storage material , especially , catalyst support material for their unique and novel structure .

元素替代对LiNH2储氢材料释氢能力影响的第一性原理研究

First-principles study on the influence of component element substitution on the dehydrogenation ability of LiNH_2 hydrogen storage materials

虽然部分作为Ni-MH电池的负极材料的电化学储氢材料已经进入商业化阶段，但是现有材料有限的储氢容量难以满足不断发展的社会的要求。

Though some kinds of electrochemistry hydrogen storage materials , which are used as negative electrode materials for nickel-metal hydride batteries , have entered the commercialization stage , limited capacities of existing materials can hardly meet the growing requirements of society .

结果表明，添加无烟煤制备的微晶碳的储氢材料，其储氢密度最高（为3.71wt.%）、初始放氢温度最低（340.8℃）、粒度最小（100～200nm）。

The results indicated that the hydrogen storage density of materials adding crystallite carbon produced by anthracite reached the maximum , the initial dehydriding temperature was the lowest , and the granularity is smallest .

利用金属Mg易热扩散制合金的特性，以化学镀Ni的碳纳米纤维（Ni-CNFs）为前驱物，制备出了Mg-Ni合金与CNFs的复合储氢材料。

As magnesium can be alloyed with other metals easily , a kind of composite hydrogen storage material of Mg-Ni alloy with carbon nanofibers ( CNFs ) is prepared by thermal diffusion with electroless nickel plated carbon nanofibers ( Ni-CNFs ) as precursor .

该复合储氢材料具有较高的活性和储氢量，在3.0MPa氢气压力和473K~553K之间的条件下，可以在1min之内完成饱和吸氢量的80%以上；

The composite possesses high reactivity and hydrogen storage capacity . Under the condition of 3.0 MPa hydrogen pressure and range of 473 K ~ 553 K , it can absorb more than 80 % of its full capacity at in less than 1 minute .

贵金属或过渡金属修饰的纳米碳管储氢材料

Noble or Transition Metals modified Carbon Nanotubes as Hydrogen Storage Materials

储氢材料性能测试装置设计及应用

Design of properties measuring apparatus and application for hydrogen storage material

氢能及金属基储氢材料

Hydrogen energy and metal ─ base alloy compounds for hydrogen storage

纳米储氢材料贮存使用安全评估方法研究

Safety Evaluation Method of Storage and Application of Nano Hydrogen Storage Materials