Rational design of high performance metal organic framework stationary phase for gas chromatography

doi:10.3724/SP.J.1123.2023.05002

Abstract

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

CLC Number:

O658

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.

Figures/Tables 9

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

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]

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]

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]

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]

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]

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]

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]

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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