Advanced nanostructured hydride composites based on light elements for solid state hydrogen storage

基于轻元素的先进纳米结构氢化物复合材料用于固态储氢

• 批准号: 6100-2012
• 负责人: Varin, Robert
• 金额: $ 1.46万
• 依托单位: University of Waterloo
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2016
• 资助国家: 加拿大
• 起止时间: 2016-01-01 至 2017-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=592830
• 关键词: Advanced; nanostructured; hydride; composites; based

In the last two decades hydrogen has been perceived as a future energy carrier that may gradually allow the transformation from the fossil fuel based economy to the hydrogen economy. In the future hydrogen economy, hydrogen-powered fuel cells and engines could power our cars, trucks, buses, and other vehicles, airplanes, as well as our homes, offices, and factories. One of the major challenges to the implementation of the widespread hydrogen economy is the development of an efficient hydrogen storage technology for various industrial sectors and particularly for transportation/automotive applications. Solid state hydrogen storage requires hydrides exhibiting high volumetric and gravimetric densities of hydrogen, the operating dehydrogenation/rehydrogenation temperature ranges compatible with the waste heat generated by a fuel cell stack, fast dehydrogenation/rehydrogenation rates, reversibility and a reasonably low price. The present research proposal is focused on further development of advanced nanostructured hydride composites, predominantly based on very light metallic and non-metallic elements such as lithium (Li), boron (B) and nitrogen (N), which form hydrides with the highest theoretical gravimetric hydrogen capacities such as lithium borohydride (LiBH4) and ammonia borane (NH3BH3) exhibiting very high gravimetric hydrogen capacities of 18.4 and 19.6 wt.%, respectively. In order to improve their hydrogen storage properties novel composite hydride systems with nanometric-sized catalytic additives will be synthesized by controlled ball milling in a unique magneto mill which brings about a severe nanostructuring of particles and internal grains creating, in effect, dimensions to the order of 10exp-9 m, many times smaller than the diameter of a human hair. An emphasis will be placed on in-depth understanding of fundamental physical/chemical processes that are responsible for the observed hydrogen storage behavior and finally, create ultimate solid state hydride systems suitable for commercial applications in various industrial sectors.

在过去的二十年里，氢被认为是未来的能源载体，可以逐渐实现从化石燃料经济向氢经济的转变。在未来的氢经济中，氢动力燃料电池和发动机可以为我们的汽车、卡车、公共汽车和其他车辆、飞机以及我们的家庭、办公室和工厂提供动力。实施广泛的氢经济的主要挑战之一是开发用于各种工业部门，特别是用于运输/汽车应用的有效储氢技术。固态氢存储需要表现出高的氢体积和重量密度、与由燃料电池堆产生的废热相容的操作脱氢/再氢化温度范围、快速脱氢/再氢化速率、可逆性和合理低的价格的储氢材料。目前的研究建议集中在进一步开发先进的纳米结构氢化物复合材料，主要基于非常轻的金属和非金属元素，如锂（Li）、硼（B）和氮（N），其形成具有最高理论重量氢容量的氢氧化物，例如硼氢化锂（LiBH 4）和氨硼烷（NH 3BH 3），显示出18.4和19.6重量%的非常高的重量氢容量，分别为了提高其储氢性能的新的复合氢化物系统与纳米尺寸的催化添加剂将合成通过控制球磨在一个独特的磁电机磨，这带来了严重的纳米结构的颗粒和内部晶粒创建，在效果上，尺寸的顺序为10 exp-9 μ m，许多倍小于人的头发的直径。重点将放在深入了解负责观察到的储氢行为的基本物理/化学过程，并最终创建适合各种工业部门商业应用的最终固态氢化物系统。