AI Article Synopsis
- Carbon monoxide (CO) is crucial for some chemical processes but is very toxic and can harm noble metal catalysts, making it necessary to have an effective adsorbent for CO, especially at low levels.
- The study created zeolite Y-based adsorbents with Cu(I) ions to improve CO capture, using methods like solid-state ion exchange and finding enhanced adsorption due to π-complexation.
- Interestingly, these adsorbents displayed high selectivity, allowing CO to pass through while blocking smaller molecules, with simulations indicating strong interactions between CO and the copper ions, leading to remarkable CO capturing capabilities.
Article Abstract
Carbon monoxide (CO) is a key reactant in several Fischer-Tropsch processes, including those used in light olefin and methanol syntheses. However, it is highly toxic and causes serious poisoning of noble metal catalysts. Thus, a solid adsorbent that can selectively capture CO, especially at low concentrations, is required. In this study, zeolite Y-based adsorbents in which Cu(I) ions occupy the supercage cation sites (CuCl/Y) are prepared via solid-state ion exchange. Volumetric adsorption measurements reveal that the Cu(I) ions significantly enhance CO adsorption in the low-pressure range by π-complexation. Furthermore, unexpected molecular sieving behavior, with extremely high CO/CO selectivity, is observed when excess CuCl homogeneously covers the zeolite pore structures. Thus, although CO has a larger kinetic diameter, it can penetrate the zeolite supercage while smaller molecules (i.e., Ar and CO) cannot. Density functional theory calculations reveal that CO molecules can remain adsorbed in pseudoblocked pores by CuCl, thanks to the strong interaction of C 2p and Cu 3d states, resulting in the high CO/CO selectivity. One of the prepared adsorbents, CuCl/Y with 50 wt % CuCl, is capable of selectively capturing 3.04 mmol g of CO with a CO/CO selectivity of >3370.
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| http://dx.doi.org/10.1021/acsami.3c04849 | DOI Listing |
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