Tailoring Hydrogen Storage Performance by Novel Mg-Catalyst Nano-Architectures
University Of Georgia Research Foundation Inc, Athens GA
Investigators
Abstract
0853130 Zhao Intellectual Merits: Hydrogen storage is the bottleneck for using hydrogen energy in on-board vehicle applications. In the pursuit of metal hydrides as solid state hydrogen storage media, magnesium hydride is considered to be a good candidate because of its lightweight, low cost, and high theoretical hydrogen storage capacity of 7.6 wt.%. Unfortunately, its high thermodynamic stability and sluggish reaction kinetics limit its practical applications. By tailoring the structural properties of nanomaterials, the thermodynamics and kinetics of hydrogen adsorption can be designed to satisfy the future hydrogen storage requirements. A fundamental understanding of hydrogen-nanostructure interactions also depends largely on the ability to fabricate nanostructures with the desired structural properties. In this proposal, the main goal is to use a novel nanofabrication technique, glancing angle deposition (GLAD), to design and produce novel Mg-catalyst nano-architectures with different topography, structure, and composition. This fabrication technique provides one with a vehicle to investigate the following important questions for hydrogen storage applications: (1) How would different nanoscale structures change the hydrogen storage behavior? (2) Would nanoscale catalysts, incorporated into nanostructured hydrogen storage materials in different forms, greatly enhance the storage behavior? Using this nanofabrication technique, the PI proposes to fabricate metal hydride nanostructures with different topographic structures to investigate the hydrogen storage ability and sorption performance. The hydrogen sorption performances of the nanostructures will be further improved by depositing different catalysts with different sizes and geometric forms. Broader Impacts: The success of this project will generate the following benefits: (1) It provides a generic methodology to fabricate well-designed metal hydride nanostructures or multilayered nanostructures. Therefore, the metal hydride materials that can be tailored into nanostructures are not limited to the proposed materials. (2) With the systematically designed metal hydride nanostructures and advanced characterization techniques, one can study at a fundamental level how hydrogen interacts with well-defined metal hydride nanostructures. (3) Optimal structures and conditions for fabricating the best metal hydride nanostructures for highly efficient hydrogen storage could be found. The lab-based nanotechnology course module that the PI will create will allow undergraduate and high school students to obtain provide hands-on experience on nanofabrication.
View original record on NSF Award Search →