化工学报
化工學報
화공학보
JOURNAL OF CHEMICAL INDUSY AND ENGINEERING (CHINA)
2014年
5期
1729-1735
,共7页
乔智威%杨仁党%王海辉%周健
喬智威%楊仁黨%王海輝%週健
교지위%양인당%왕해휘%주건
分子模拟%金属-有机骨架材料%吸附%分离%生物甲烷
分子模擬%金屬-有機骨架材料%吸附%分離%生物甲烷
분자모의%금속-유궤골가재료%흡부%분리%생물갑완
molecular simulation%metal-organic framework%adsorption%separation%bio-methanePT
采用巨正则Monte Carlo法(GCMC),对CH4/CO2混合气体体系基于金属-有机骨架材料(MOFs)的吸附分离进行了模拟研究。吸附分离材料涉及3个系列(M-MOF-74、M-MIL-53和[M(atz)(bdc)0.5])(M=Mg, Co, Ni, Zn, Al, Cr)不同金属配位的8种MOF材料。研究表明,Mg-MOF-74的CO2吸附性能在高压下优于其他材料;在低压时,拥有大量氨基官能团的[Zn(atz)(bdc)0.5]和[Co(atz)(bdc)0.5]材料有更高效的CO2分离性能。通过径向分布函数和CO2吸附构型快照重叠图进一步分析发现,各个系列材料不同金属配位对CO2吸附构型的影响造成了材料吸附分离性能有较大的不同。研究结果能够为实验上设计和开发新型高效CO2和CH4吸附分离MOFs材料提供启发。
採用巨正則Monte Carlo法(GCMC),對CH4/CO2混閤氣體體繫基于金屬-有機骨架材料(MOFs)的吸附分離進行瞭模擬研究。吸附分離材料涉及3箇繫列(M-MOF-74、M-MIL-53和[M(atz)(bdc)0.5])(M=Mg, Co, Ni, Zn, Al, Cr)不同金屬配位的8種MOF材料。研究錶明,Mg-MOF-74的CO2吸附性能在高壓下優于其他材料;在低壓時,擁有大量氨基官能糰的[Zn(atz)(bdc)0.5]和[Co(atz)(bdc)0.5]材料有更高效的CO2分離性能。通過徑嚮分佈函數和CO2吸附構型快照重疊圖進一步分析髮現,各箇繫列材料不同金屬配位對CO2吸附構型的影響造成瞭材料吸附分離性能有較大的不同。研究結果能夠為實驗上設計和開髮新型高效CO2和CH4吸附分離MOFs材料提供啟髮。
채용거정칙Monte Carlo법(GCMC),대CH4/CO2혼합기체체계기우금속-유궤골가재료(MOFs)적흡부분리진행료모의연구。흡부분리재료섭급3개계렬(M-MOF-74、M-MIL-53화[M(atz)(bdc)0.5])(M=Mg, Co, Ni, Zn, Al, Cr)불동금속배위적8충MOF재료。연구표명,Mg-MOF-74적CO2흡부성능재고압하우우기타재료;재저압시,옹유대량안기관능단적[Zn(atz)(bdc)0.5]화[Co(atz)(bdc)0.5]재료유경고효적CO2분리성능。통과경향분포함수화CO2흡부구형쾌조중첩도진일보분석발현,각개계렬재료불동금속배위대CO2흡부구형적영향조성료재료흡부분리성능유교대적불동。연구결과능구위실험상설계화개발신형고효CO2화CH4흡부분리MOFs재료제공계발。
The adsorption and separation capabilities of metal-organic frameworks (MOFs) for CO2 and CH4 gas mixtures were studied by grand canonical Monte Carlo (GCMC) simulations. Three sub-families (M-MOF-74, M-MIL-53 and [M(atz)(bdc)0.5]) (M=Mg, Co, Ni, Zn, Al, Cr) MOFs with different metal ligands were investigated. Simulation results showed that the CO2 adsorption capability of Mg-MOF-74 exceeded the others at high pressures; both amine functionalized [Zn(atz)(bdc)0.5] and [Co(atz)(bdc)0.5] MOFs had superior CO2 separation performance at low pressures. The radial distribution functions and the overlapping snapshots of CO2 adsorption showed that in each sub-family of MOFs, different metal ligands affected their CO2 adsorption configuration and resulted in their different adsorption and separation capabilities. This work could provide some guidance for the design and development of new high performance MOFs for CO2 and CH4 separation.
