CO₂ capture on micro/mesoporous composites of (zeolite A)/(MCM-41) with Ca²⁺ located: Computer simulation and experimental studies

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• 作者：Jianhai Zhou ; Huiling Zhao ; Jinxia Li ; Yujun Zhu ; Jun Hu ; Honglai Liu ; Ying Hu
• 关键词：5A-MCM-41 composite ; Micro/mesoporous ; Computer simulation ; Experiment
• 刊名：Solid State Sciences
• 出版年：2013
• 出版时间：October, 2013
• 年：2013
• 卷：24
• 期：Complete
• 页码：107-114
• 全文大小：3890 K

文摘

Composing of both zeolite and mesoporous structures, micro/mesoporous composites exhibit promising CO₂ capture capabilities. In this work, a full-atomic mimetic 5A-MCM-41 structure with bimodal pores has been constructed, in which the microporous structure of 5A zeolite is constructed and optimized based on zeolite A with Ca and Na cations introduced; whereas the mesoporous MCM-41 structure is produced by caving the cylindrical pores in the obtained 5A zeolite matrix. CO₂ adsorption on 5A-MCM-41 has been simulated by the grand canonical Monte Carlo (GCMC). The simulation results demonstrated that CO₂ is preferentially adsorbed in micropores, and the CO₂ adsorption capacity and its isosteric heat on 5A-MCM-41 are much larger than those of N₂. The CO₂ selectivity of 5A-MCM-41 results from the electrostatic interaction of the quadrupole CO₂ molecule with Ca²⁺ cations of the zeolite. Furthermore, the hierarchical micro/mesoporous composites are synthesized to verify the simulated predictions. By the hydrothermal reaction using 5A zeolite ¡°seeds¡± as the silicon source and hexadecyl trimethylammonium bromide (CTAB) as the mesoporous template, 5A-MCM-41 composites are obtained, the characteristic results show that typical 5A microporous structure is remained and disordered mesoporous networks are produced in the composites. Moreover, the CO₂ adsorption capacity of the 5A-MCM-41 composites can reach as high as 4.08?mmol/g at 100?kPa and 298?K. These observations have been strongly supported that micro/mesoporous composites with metal ions located would be promising adsorbents for CO₂ separation.