氢气储存
氢
氢经济
能量载体
可再生能源
工作(物理)
氢技术
工艺工程
氢燃料
材料科学
储能
纳米技术
化学
机械工程
工程类
热力学
物理
电气工程
功率(物理)
有机化学
作者
Qiwen Lai,Yahui Sun,Ting Wang,Poojan Modi,Claudio Cazorla,Umit B. Demirci,J.R. Ares,Fabrice Leardini,Kondo‐François Aguey‐Zinsou
标识
DOI:10.1002/adsu.201900043
摘要
Abstract As the world shifts toward renewable energy, the need for an effective energy carrier is pressing. Hydrogen has often been touted as a universal clean energy vector and the fuel of the future. Unfortunately, mass adoption of the hydrogen economy is slow due to a lack of incentives and technical difficulties in storing hydrogen. Better materials capable of reversible hydrogen uptake/release with hydrogen capacity surpassing 5 mass% at the ambient must emerge. So far, finding such materials has been elusive; alloys capable of ambient hydrogen uptake/release have a low storage capacity while high capacity hydrides have a very high hydrogen release temperature. From metal alloys to complex hydrides, a better understanding of the behavior of hydrogen in hydrides is essential to fine‐tune their properties toward application. Herein, the latest approaches to design hydrogen storage materials based on known hydrides are reviewed with the aim to facilitate the emergence of alternative thinking toward the design of better hydrogen storage materials. Synthetic methods and conceptual approaches to achieve particular hydrogen thermodynamics and kinetics are discussed. These include metallurgical alloying, mechanochemical modification, chemical destabilization, the nanosizing approach, and theoretical modeling and machine learning techniques to guide experimental work.
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