Cho YongJun, Li Sichi, Snider Jonathan L, Marple Maxwell A T, Strange Nicholas A, Sugar Joshua D, El Gabaly Farid, Schneemann Andreas, Kang Sungsu, Kang Min-Ho, Park Hayoung, Park Jungwon, Wan Liwen F, Mason Harris E, Allendorf Mark D, Wood Brandon C, Cho Eun Seon, Stavila Vitalie
Sandia National Laboratories, 7011 East Avenue, Livermore, California 94550, United States.
Department of Chemical and Biomolecular Engineering (BK21+ Program), Korea Advanced Institute of Science and Technology (KAIST), Daejeon 34141, Republic of Korea.
ACS Nano. 2021 Jun 22;15(6):10163-10174. doi: 10.1021/acsnano.1c02079. Epub 2021 May 24.
A general problem when designing functional nanomaterials for energy storage is the lack of control over the stability and reactivity of metastable phases. Using the high-capacity hydrogen storage candidate LiAlH as an exemplar, we demonstrate an alternative approach to the thermodynamic stabilization of metastable metal hydrides by coordination to nitrogen binding sites within the nanopores of N-doped CMK-3 carbon (NCMK-3). The resulting LiAlH@NCMK-3 material releases H at temperatures as low as 126 °C with full decomposition below 240 °C, bypassing the usual LiAlH intermediate observed in bulk. Moreover, >80% of LiAlH can be regenerated under 100 MPa H, a feat previously thought to be impossible. Nitrogen sites are critical to these improvements, as no reversibility is observed with undoped CMK-3. Density functional theory predicts a drastically reduced Al-H bond dissociation energy and supports the observed change in the reaction pathway. The calculations also provide a rationale for the solid-state reversibility, which derives from the combined effects of nanoconfinement, Li adatom formation, and charge redistribution between the metal hydride and the host.
设计用于能量存储的功能纳米材料时的一个普遍问题是难以控制亚稳相的稳定性和反应活性。以高容量储氢候选材料LiAlH为例,我们展示了一种通过与氮掺杂CMK-3碳(NCMK-3)纳米孔内的氮结合位点配位来实现亚稳金属氢化物热力学稳定的替代方法。所得的LiAlH@NCMK-3材料在低至126°C的温度下释放氢气,在240°C以下完全分解,绕过了在块状材料中常见的LiAlH中间态。此外,在100 MPa氢气压力下,超过80%的LiAlH可以再生,这一成果此前被认为是不可能实现的。氮位点对这些改进至关重要,因为未掺杂的CMK-3没有观察到可逆性。密度泛函理论预测Al-H键解离能大幅降低,并支持所观察到的反应路径变化。计算结果还为固态可逆性提供了理论依据,这源于纳米限域、锂原子形成以及金属氢化物与主体之间电荷重新分布的综合作用。
