电动膜过滤实现高效无金属硝酸盐还原

Yingzheng Fan, Xiaoxiong Wang, Claire Butler, Amma Kankam, Abdessamad Belgada, Julia Simon, Yuanzuo Gao, Eric Chen, Lea R. Winter
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摘要

目前,饮用水中硝酸盐的电催化破坏方法需要使用金属催化剂才能充分去除硝酸盐。然而,金属催化剂涉及复杂的合成,会增加处理成本,并可能导致金属渗入处理过的水中。在这里,我们通过含有未经改性的原始碳纳米管(CNTs)的无金属纳米多孔电化膜(EM)进行电过滤,实现了与金属催化剂相当的硝酸盐还原性能。实验结果与计算流体动力学模拟相结合,阐明了流动的 CNT-EM 中扩散边界层的减少如何缓解扩散限制,从而提高整体硝酸盐反应活性。此外,通过比较含有经酸处理的无金属 CNT 和添加了缺陷的 CNT 的 EM 的活性,确定了 CNT 中的缺陷是催化活性位点。通过密度泛函理论和分子动力学计算,我们证明了内在缺陷位点的*NO2 和*NO 吸附能增强,这些缺陷位点存在于大多数商用 CNT 中,在流动操作下更容易被硝酸根离子吸附。最后,研究人员在实际地表水中演示了这种无金属 CNT-EM 的长期稳定性、对环境干扰的耐受性、足够的硝酸盐去除率以及满足饮用水标准的可扩展性,从而展示了其在实际应用中的卓越性能。通过阐明纳米多孔电过滤如何实现反应和传输速率的动态匹配,本研究展示了一种无需创新复杂催化剂材料就能大幅提高电催化反应性能的新策略,弥补了饮用水处理中与使用金属基催化剂有关的硝酸盐去除方面的现有差距。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Highly efficient metal-free nitrate reduction enabled by electrified membrane filtration

Highly efficient metal-free nitrate reduction enabled by electrified membrane filtration

Highly efficient metal-free nitrate reduction enabled by electrified membrane filtration
Current methods for electrocatalytic destruction of nitrate in drinking water require metal catalysts to achieve sufficient nitrate removal. However, metal-based catalysts involve complicated synthesis, increase treatment costs and can lead to leaching of metals into treated water. Here we achieved nitrate reduction performance comparable to that of metal-based catalysts via electrofiltration through a metal-free nanoporous electrified membrane (EM) containing unmodified pristine carbon nanotubes (CNTs). Experimental results coupled with computational fluid dynamics simulations elucidated how the decreased diffusion boundary layer in the flow-through CNT-EM mitigates diffusion limitations to enhance overall nitrate reaction activity. Furthermore, defects in CNTs were identified as the catalytic active sites by comparing the activity of EMs containing acid-treated metal-free CNTs and CNTs with added defects. Through density functional theory and molecular dynamics calculations, we demonstrated enhanced *NO2 and *NO adsorption energies at intrinsic defect sites, which are present in most commercial CNTs and become more accessible to nitrate ions under flow-through operation. Finally, the long-term stability, tolerance of environmental interferences, and sufficient nitrate removal and scalability to meet drinking water standards were demonstrated in real surface water, exhibiting the outstanding performance of the metal-free CNT-EM for practical applications. By elucidating how nanoporous electrofiltration enables dynamic matching of reaction and transport rates, this study demonstrates a new strategy to drastically improve electrocatalytic reaction performance without complex catalyst materials innovation, bridging existing gaps for nitrate removal in drinking water treatment related to the use of metal-based catalysts. Current methods for electrocatalytic destruction of nitrate in drinking water require metal catalysts to achieve sufficient nitrate removal. Electrified membranes containing pristine carbon nanotubes operated under flow-through mode provide an alternative approach for efficient nitrate reduction without the use of metals.
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