高效金属有机骨架气相色谱固定相的理性设计

doi:10.3724/SP.J.1123.2023.05002

摘要/Abstract

摘要：

金属有机骨架材料(MOFs)由金属离子或金属簇与有机配体组装而成,其中多变的金属中心和有机配体使其具有高度可调性,这为调控高效气相色谱分离性能奠定了良好的结构基础。热力学作用力是描述分析物与固定相相互作用的基本指标,保留因子、麦氏常数、焓变与熵变等热力学值可以反映热力学作用力的相对大小。在微观层面上,可以通过设计MOFs孔隙内的多元作用力以开展热力学性质的研究,如设计金属亲和性、π-π相互作用、极性、手性位点等,这些热力学作用力可为分离具有微小差异的分析物提供有利环境。在动力学方面,MOFs的孔径大小与形状、颗粒尺寸、堆积模式对分析物的动力学扩散速率有着重要的影响,从改善分析物的动力学扩散角度出发,通过选择合适的孔径尺寸与形状、降低MOFs的颗粒尺寸、调控MOFs的堆积模式等手段,均可以提高气相色谱固定相的分离性能。根据色谱动力学统一方程和范蒂姆特方程计算扩散系数、理论塔板高度等动力学值,可有效评价色谱峰峰形和色谱柱柱效。在分离过程中,分析物的热力学作用力和动力学效应是协同作用的,且缺一不可。因此,本文从热力学与动力学两个角度提出了构建高效MOFs气相色谱固定相的设计思路,希望能为相关领域的研究提供一定帮助。

关键词: 金属有机骨架材料, 气相色谱, 固定相, 热力学相互作用, 动力学扩散, 综述

Abstract:

Metal organic frameworks (MOFs) are assembled from metal ions or clusters and organic ligands. The high tunability of these components offers a solid structural foundation for achieving efficient gas chromatography (GC) separation. This review demonstrates that the design of high performance MOFs with suitable stationarity should consider both the thermodynamic interactions provided by these MOFs and the kinetic diffusion of analytes. Thermodynamic parameters are basic indicators for describing the interactions between various analytes and the stationary phase. Thermodynamic parameters such as retention factors, McReynolds constants, enthalpy changes, and entropy changes can reflect the relative intensity of thermodynamic interactions. For example, a larger enthalpy change indicates a stronger thermodynamic interaction between the analytes and stationary phase, whereas a smaller enthalpy change indicates a weaker interaction. In addition, the degree of entropy change reflects the relative degrees of freedom of analytes in the stationary phase. A larger entropy change indicates that the analytes have fewer degrees of freedom in the stationary phase. The higher the degree of restriction, the closer the adsorption of the analytes and, thus, the longer the retention time. Thermodynamic interactions, such as metal affinity, π-π interactions, polarity, and chiral sites, can be rationally introduced into MOF structures by pre- or post-modifications depending on the target analytes. These tailored thermodynamic interactions create a favorable environment with subtle differences for efficient analyte separation. For example, MOF stationarity may require large conjugation centers to provide specific π-π interactions to separate benzenes. Chiral groups may be required in the MOF structure to provide sufficient interactions to separate chiral isomers. The kinetic diffusion rate of the analytes is another critical factor that affects the separation performance of MOFs. The diffusion coefficients of analytes in the stationary phase (D_s) can be used to evaluate their diffusion rates. The chromatographic dynamics equation illustrates that the chromatographic peak of analytes tends to be sharper and more symmetrical when the D_s is large, whereas a wider trailing peak may appear when the D_s is small. The Van Deemter equation also proves that a low D_s may lead to a high theoretical plate height and low column efficiency, whereas a high D_s may lead to a low theoretical plate height and increased column efficiency. Analyte diffusion can be significantly influenced by the pore size, shape, particle size, and packing mode of MOFs. For instance, an excessively small pore size results in increased mass transfer resistance, which affects the diffusion of analytes in the stationary phase, probably leading to serious peak trailing. Thus, a suitable pore size is required to enhance the kinetic diffusion of analytes and improve the separation performance of MOFs. Theoretically, the design of a high performance MOF stationary phase requires the creation of routes for the rapid diffusion of analytes. However, the separation ability of an MOF is determined by not only the kinetic diffusion rate of the analytes but also the thermodynamic interactions it provides. An excessively fast diffusion rate may lead to insufficient interactions between the analytes and MOFs, compromising their ability to effectively separate different analytes. The thermodynamic interactions and kinetic diffusion of analytes are synergistic and mutually essential. Therefore, this review concludes with research on the influence of both the thermodynamic interactions and kinetic diffusion of analytes on the performance of MOF stationary phases. Based on the findings of this review, we propose that high performance MOF stationary phases can be achieved by balancing the thermodynamic interactions and kinetic diffusion of analytes in these phases through the rational design of the MOF structure. We believe that this review provides useful guidelines for the design of high performance MOF stationary phases.

Key words: metal organic frameworks (MOFs), gas chromatography (GC), stationary phase, thermodynamic interaction, kinetic diffusion, review

中图分类号:

O658

杨涵, 汤雯淇, 曾楚, 孟莎莎, 徐铭. 高效金属有机骨架气相色谱固定相的理性设计[J]. 色谱, 2023, 41(10): 853-865.

YANG Han, TANG Wenqi, ZENG Chu, MENG Shasha, XU Ming. Rational design of high performance metal organic framework stationary phase for gas chromatography[J]. Chinese Journal of Chromatography, 2023, 41(10): 853-865.

图/表 9

图 1 基于热力学与动力学效应的MOFs固定相气相色谱分离示意图

Fig. 1 Separation mechanism diagram of metal organic framework (MOF) stationary phase for gas chromatography based on thermodynamic and kinetic effects

图 2 (a)TYUT-96Cr、MIL-100Cr、MIL-101Cr的结构图[26]和 (b)MIL-101毛细管柱、(c)吡啶修饰的MIL-101毛细管柱分离二甲苯异构体的气相色谱图[25]

Fig. 2 (a) Structure diagrams of TYUT-96Cr, MIL-100Cr and MIL-101Cr[26]and gas chromatograms for separation of xylene isomers by (b) MIL-101 capillary column and (c) pyridine-modified MIL-101 capillary column[25]

图 3 (a)手性MOF(Co-L-GG)的三维结构图和Co-L-GG 手性柱分离(b)硝基甲苯异构体、(c)2-乙基己酸的气相色谱图[42]

Fig. 3 (a) Three-dimensional structure diagram of chiral MOF (Co-L-GG) and gas chromatograms for separation of (b) nitrotoluenes and (c) 2-ethylhexanoic acid by Co-L-GG chiral column[42]

图 4 (a)PCN-608、NU-1000、PCN-222的结构图[47?-49]和(b)PCN-608-N、NU-1000-N、PCN-222-N毛细管柱分离乙基甲苯异构体的气相色谱图[35]

Fig. 4 (a) Structure diagrams of PCN-608, NU-1000 and PCN-222[47?-49] and (b) gas chromatograms for separation of ethyltoluene isomers by capillary columns of PCN-608-N, NU-1000-N and PCN-222-N[35]

图 5 (a)ZIF-8的结构图和ZIF-8毛细管柱分离(b)直链烷烃、(c)2,2-二甲基支链烷烃和直链烷烃、(d)己烷及其支链异构体、(e)辛烷及其支链异构体的气相色谱图[53]

Fig. 5 (a) Structure diagram of zeolitic imidazolate frameworks (ZIF-8) and gas chromatograms for separation of (b) linear alkanes, (c) linear alkanes and 2,2-dimethyl-branched alkanes, (d) hexane and its branched isomers, (e) octane and its branched isomers by capillary column of ZIF-8[53]

图 6 (a)SIFSIX-1-Zn、SIFSIX-3-Zn和SIFSIX-1-Cu沿c轴的结构图以及(b)SIFSIX-1-Zn、SIFSIX-3-Zn和SIFSIX-1-Cu毛细管柱对直链烷烃的气相色谱分离图[55]

Fig. 6 (a) Structure diagrams of SIFSIX-1-Zn, SIFSIX-3-Zn, SIFSIX-1-Cu along the c-axis and (b) gas chromatographic separation diagrams of linear alkanes by SIFSIX-1-Zn, SIFSIX-3-Zn and SIFSIX-1-Cu capillary columns[55]

图 7 (a)纳米级与微米级PCN-608、NU-1000的扫描电子显微镜(SEM)图像和(b)纳米级与微米级PCN-608、NU-1000毛细管柱对辛烷及其支链异构体的气相色谱分离对比图[35]

Fig. 7 (a) Scanning electron microscope (SEM) images of nanometer and micron scale PCN-608 and NU-1000 and (b) comparisons of gas chromatographic separation diagrams of octane and its branched isomers by capillary columns of nanoscale and micron scale PCN-608 and NU-1000[35]

图 8 (a)扭曲堆积与规整堆积的Zr-BTB毛细管柱对苯系物的气相色谱分离图[34], (b)利用非共价相互作用调控2D-Zr-BTB堆积模式的示意图[64]以及(c)不同溶剂洗涤的2D-Zr-BTB对二甲苯异构体的气相色谱分离图[64]

Fig. 8 (a) Gas chromatographic separation diagrams of benzene derivative isomers in twisted and untwisted packed Zr-BTB capillary column[34], (b) schematic diagram of regulating 2D-Zr-BTB stacking patterns by non-covalent interactions and (c) gas chromatographic separation diagrams of xylene isomers by capillary columns of 2D-Zr-BTB washed with different solvents[64]

图 9 (a)二取代苯异构体与烷烃异构体在NU-901、NU-1000、MOSS毛细管柱上的分离性能[70]和扩散路径与作用中心对(b)PCN材料和(c)NU材料分离性能的影响示意图[47]

Fig. 9 (a) Separation performance of disubstituted benzene isomers and alkane isomers on NU-901, NU-1000, MOSS capillary columns[70]and schematic diagrams of the influence of diffusion path and interaction centers on the separation performance of (b) PCN materials and (c) NU materials[47]

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