无有机模板合成离散CHA沸石纳米晶体用于选择性CO捕集

Synthesis of Discrete CHA Zeolite Nanocrystals without Organic Templates for Selective CO Capture.

作者信息

Debost Maxime, Klar Paul B, Barrier Nicolas, Clatworthy Edwin B, Grand Julien, Laine Fabien, Brázda Petr, Palatinus Lukas, Nesterenko Nikolai, Boullay Philippe, Mintova Svetlana

机构信息

Normandie Université, ENSICAEN, UNICAEN, CNRS, LCS, 14000, Caen, France.

Institute of Physics of the Czech Academy of Sciences, Na Slovance 2, Prague, Czech Republic.

出版信息

Angew Chem Int Ed Engl. 2020 Dec 21;59(52):23491-23495. doi: 10.1002/anie.202009397. Epub 2020 Oct 16.

DOI:10.1002/anie.202009397

PMID:32902156

Abstract

Small-pore zeolites such as chabazite (CHA) are excellent candidates for the selective separation of CO ; however, the current synthesis involves several steps and the use of organic structure-directing agent (OSDA), increasing their cost and energy requirements. We report the synthesis of small-pore zeolite crystals (aluminosilicate) with CHA-type framework structure by direct synthesis in a colloidal suspension containing a mixture of inorganic cations only (Na , K , and Cs ). The location of CO molecules in the host structure was revealed by 3D electron diffraction (3D ED). The high sorption capacity for CO (3.8 mmol g at 121 kPa), structural stability and regenerability of the discreate CHA zeolite nanocrystals is maintained for 10 consecutive cycles without any visible degradation. The CHA zeolite (Si:Al=2) reaches an almost perfect CO storage capacity (8 CO per unit cell) and high selectivity (no CH was adsorbed).

摘要

小孔沸石，如菱沸石（CHA），是选择性分离CO的优秀候选材料；然而，目前的合成方法涉及多个步骤且使用有机结构导向剂（OSDA），这增加了成本和能源需求。我们报道了通过在仅含有无机阳离子（Na、K和Cs）混合物的胶体悬浮液中直接合成，制备具有CHA型骨架结构的小孔沸石晶体（铝硅酸盐）。通过三维电子衍射（3D ED）揭示了CO分子在主体结构中的位置。离散的CHA沸石纳米晶体对CO具有高吸附容量（121 kPa下为3.8 mmol g）、结构稳定性和可再生性，连续10个循环保持不变，无任何可见降解。CHA沸石（Si:Al = 2）达到几乎完美的CO储存容量（每晶胞8个CO）和高选择性（未吸附CH）。

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无有机模板合成离散CHA沸石纳米晶体用于选择性CO捕集

Synthesis of Discrete CHA Zeolite Nanocrystals without Organic Templates for Selective CO Capture.

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