Mg17Al12-hydride (abbreviated as MAH) was selected as a destabilization agent to improve de/rehydrogenation properties of LiBH4. 58LiBH4+Mg17Al12-hydride composite was prepared by ball-milling. It is found that the...Mg17Al12-hydride (abbreviated as MAH) was selected as a destabilization agent to improve de/rehydrogenation properties of LiBH4. 58LiBH4+Mg17Al12-hydride composite was prepared by ball-milling. It is found that the dehydrogenation of ball-milled LiBH4/MAH composite presents a two-step reaction for hydrogen release. The composite starts desorbing hydrogen at about 300 ℃ and yields 9.8%of hydrogen (mass fraction) below 500 ℃. By adding MAH, the dehydrogenation kinetics of LiBH4 is improved and the dehydrogenation temperature of LiBH4 is also lowered by 20 ℃. High rehydriding capacity of 8.3% was obtained for the dehydrogenated composite in the first cycle at 450 ℃. The XRD analysis shows the formation of MgB2 and AlB2 in the dehydrogenation process, which reduces the thermodynamics stability of LiBH4 system and is beneficial to the reversible hydrogen storage behaviors of LiBH4/MAH composite.展开更多
基金Project(2010CB631304)supported by the National Basic Research Program of ChinaProjects(51001090,51171173)supported by the National Natural Science Foundation of ChinaProject(20090101110050)supported by the University Doctoral Foundation of the Ministry of Education,China
文摘Mg17Al12-hydride (abbreviated as MAH) was selected as a destabilization agent to improve de/rehydrogenation properties of LiBH4. 58LiBH4+Mg17Al12-hydride composite was prepared by ball-milling. It is found that the dehydrogenation of ball-milled LiBH4/MAH composite presents a two-step reaction for hydrogen release. The composite starts desorbing hydrogen at about 300 ℃ and yields 9.8%of hydrogen (mass fraction) below 500 ℃. By adding MAH, the dehydrogenation kinetics of LiBH4 is improved and the dehydrogenation temperature of LiBH4 is also lowered by 20 ℃. High rehydriding capacity of 8.3% was obtained for the dehydrogenated composite in the first cycle at 450 ℃. The XRD analysis shows the formation of MgB2 and AlB2 in the dehydrogenation process, which reduces the thermodynamics stability of LiBH4 system and is beneficial to the reversible hydrogen storage behaviors of LiBH4/MAH composite.
