利用流式电容去离子法和 ZIF-8 包覆阳离子交换膜从电池废水中回收锂离子的分子动力学研究

IF 4.8 Q1 ENVIRONMENTAL SCIENCES
Terence Zhi Xiang Hong, Kexin Tang, Liming You, Taoqin Chen, Hieu Trung Kieu, Shane Allen Snyder and Kun Zhou*, 
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引用次数: 0

摘要

本研究进行了分子动力学(MD)模拟,以评估在用于流动电容式去离子(FCDI)的阳离子交换膜(CEM)中用作选择层的三种沸石咪唑框架(ZIF)的锂回收性能。三种 ZIF(ZIF-8、ZIF-8-Cl 和 ZIF-8-Br)具有共同的金属节点(Zn 节点),但咪唑链节上的官能团(CH3、Cl 和 Br)不同。ZIF 的性能是根据其 Li+/Na+ 选择性来评估的,选择性是通过计算流动电极中 Li+ 和 Na+ 离子的数量来确定的。此外,还利用描述 ZIF 与阳离子相互作用能量的图表和等值线图研究了 ZIF 对阳离子的吸附情况。此外,还通过实验对模拟结果进行了验证,实验涉及进料溶液中阳离子浓度的量化。结果表明,Li+/Na+ 选择性取决于 ZIF 的阳离子亲和力。从流动电极中回收 Li+ 离子比从 CEM 中回收更可取。此外,阳离子需要外部能量才能进入孔隙,因为它们会受到排斥。为了在流动电极中实现较高的 Li+/Na+ 选择性,ZIF 选择层对 Na+ 的亲和力应强于对 Li+的亲和力。此外,ZIF 表面的空腔应足够小,以限制 Na+ 进入。总之,MD 模拟对于了解在用于 FCDI 的 ZIF 中实现高 Li+/Na+ 选择性所需的机制非常有价值。在测试的三种 ZIF 中,ZIF-8-Br 在模拟和实验中都表现出了最高的 Li+/Na+ 选择性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Molecular Dynamics Study into Lithium-Ion Recovery from Battery Wastewater Using Flow Capacitive Deionization and a ZIF-8-Coated Cation Exchange Membrane

Molecular Dynamics Study into Lithium-Ion Recovery from Battery Wastewater Using Flow Capacitive Deionization and a ZIF-8-Coated Cation Exchange Membrane

Molecular dynamics (MD) simulations are conducted to assess the Li recovery performance of three zeolitic imidazolate frameworks (ZIFs) employed as selective layers in cation exchange membranes (CEMs) for flow capacitive deionization (FCDI). The three ZIFs (ZIF-8, ZIF-8-Cl, and ZIF-8-Br) share a common metal node (Zn node) but differ in their functional groups on the imidazolate linkers (CH3, Cl, and Br). The performance of the ZIFs is evaluated based on their Li+/Na+ selectivity, determined by calculating the number of Li+ and Na+ ions in the flow-electrode. The adsorption of cations by the ZIFs is also investigated using graphs and contour maps depicting the ZIF–cation interaction energy. Additionally, the simulation results are validated through experiments involving the quantification of cation concentration in the feed solution. The results indicate that Li+/Na+ selectivity depends on the cation affinity of the ZIF. It is preferable to recover Li+ ions from the flow-electrode than from the CEM. Moreover, cations require external energy to enter the pores as they experience repulsion. To achieve high Li+/Na+ selectivity in the flow-electrode, the ZIF selective layers should exhibit a stronger affinity for Na+ than for Li+. Additionally, the cavities at the surface of the ZIFs should be sufficiently small to restrict Na+ entry. Overall, MD simulations are valuable for understanding the mechanisms necessary to achieve high Li+/Na+ selectivity in ZIFs for FCDI applications. Among the three ZIFs tested, ZIF-8-Br exhibits the highest Li+/Na+ selectivity in both simulations and experiments.

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