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多孔氢氧化镍的表面水合作用促进了从环境空气中可逆吸附CO。

Surface Hydration of Porous Nickel Hydroxides Facilitates the Reversible Adsorption of CO from Ambient Air.

作者信息

Wu Xiaowei, Pandey Rahul, Zhang Junyan, Polo-Garzon Felipe, Robles Hernandez Fransisco Carlos, Krishnamoorti Ramanan, Bollini Praveen

机构信息

William A. Brookshire Department of Chemical and Biomolecular Engineering, University of Houston, Houston, Texas 77204, United States.

SRI International, Palo Alto, California 94304, United States.

出版信息

JACS Au. 2025 Mar 17;5(4):1649-1662. doi: 10.1021/jacsau.4c01083. eCollection 2025 Apr 28.

DOI:10.1021/jacsau.4c01083
PMID:40313810
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12042040/
Abstract

Direct air capture (DAC) under humid ambient conditions typically requires the use of organic components, with sorbents that are purely inorganic in composition for the most part operating hundreds of degrees above room temperature. In this work, we report porous metal hydroxides as a novel class of water-tolerant, oxidatively and hydrothermally stable low-temperature sorbents that exhibit competitive DAC working capacities of 1.25 mmol/g over 5 consecutive temperature swing adsorption-desorption cycles in the presence of steam and oxygen. Aqueous miscible organic solvent treatments are used to create highly porous structures with surface areas exceeding 700 m/g that capture CO in the form of bicarbonates under dry conditions, and carbonates under wet conditions. Water exerts a facilitative rather than an inhibiting effect on CO binding, and the presence of hydrating multilayers serves to stabilize carbonate species-akin to moisture swing adsorbents-except for the fact that solvation results in a remarkable (upto 10-fold) increase, not decrease, in DAC capacity. High-valent doping with cerium is used to improve DAC capacities by amplifying surface basicity, evidencing porous nickel hydroxides specifically (and porous metal hydroxides more generally) as a novel class of robust, earth-abundant DAC sorbents.

摘要

在潮湿环境条件下进行的直接空气捕获(DAC)通常需要使用有机成分,而大多数成分纯无机的吸附剂在比室温高数百摄氏度的温度下运行。在这项工作中,我们报告了多孔金属氢氧化物作为一类新型的耐水、氧化稳定和水热稳定的低温吸附剂,在存在蒸汽和氧气的情况下,经过5个连续的变温吸附-解吸循环,其DAC工作容量达到1.25 mmol/g,具有竞争力。使用与水混溶的有机溶剂处理来创建表面积超过700 m/g的高度多孔结构,该结构在干燥条件下以碳酸氢盐形式捕获CO,在潮湿条件下以碳酸盐形式捕获CO。水对CO结合起到促进而非抑制作用,并且水合多层的存在有助于稳定碳酸盐物种——类似于湿度摆动吸附剂——不同的是溶剂化导致DAC容量显著增加(高达10倍),而非降低。用铈进行高价掺杂用于通过增强表面碱性来提高DAC容量,证明了多孔氢氧化镍(更普遍地说是多孔金属氢氧化物)是一类新型的坚固、储量丰富的DAC吸附剂。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d815/12042040/0c22bb6a78c8/au4c01083_0008.jpg
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