基于金属有机骨架材料固定相的气相色谱分离应用

doi:10.3724/SP.J.1123.2020.06028

色谱 ›› 2021, Vol. 39 ›› Issue (1): 57-68.DOI: 10.3724/SP.J.1123.2020.06028

基于金属有机骨架材料固定相的气相色谱分离应用

汤雯淇, 孟莎莎, 徐铭, 古志远^*()

南京师范大学化学与材料科学学院, 江苏南京 210023

收稿日期:2020-06-24 出版日期:2021-01-08 发布日期:2020-12-20
通讯作者: 古志远
作者简介:

古志远: 南京师范大学教授、博导,国家自然科学基金优秀青年基金项目获得者。2006年和2011年在南开大学分别获学士、博士学位。2011至2014年在美国德州农工大学进行博士后研究。研究方向为分离分析,以二维金属有机骨架纳米片(2-D MOF nanosheets)为基础构建高效捕集和分离介质,建立了一系列分析化学新方法和新体系,包括高效气相色谱分离方法、磷酸化肽富集方法、基质辅助离子化方法、仿生纳米酶传感方法等。以通讯作者/第一作者在J Am Chem Soc(3篇), Angew Chem Int Ed(2篇), Nat Commun(1篇), Acc Chem Res(1篇), Chem Sci(1篇), Anal Chem(4篇), Chem Commun(3篇)等化学高水平刊物上发表SCI论文31篇。总发表论文数44篇,其中14篇入选ESI Top 1%高被引论文。论文引用6500余次,个人h因子为25。主持各类科研及人才项目累计600余万元。曾获高等学校科学研究自然科学奖一等奖(排名第三)、全国优秀博士学位论文提名奖等奖励。*E-mail:guzhiyuan@njnu.edu.cn.
基金资助:
国家自然科学基金(21922407);江苏省自然科学基金(BK20190086)

Application of gas chromatography separation based on metal-organic framework material as stationary phase

TANG Wenqi, MENG Shasha, XU Ming, GU Zhiyuan^*()

School of Chemistry and Materials Science, Nanjing Normal University, Nanjing 210023, China

Received:2020-06-24 Online:2021-01-08 Published:2020-12-20
Contact: GU Zhiyuan
Supported by:
National Natural Science Foundation of China(21922407);Natural Science Foundation of Jiangsu Province of China(BK20190086)

摘要/Abstract

摘要：

金属有机骨架材料(MOFs)是一类由有机配体和金属离子(或金属簇)自组装形成的新型多功能材料。MOFs具有孔隙度高、比表面积大、孔径可调、化学和热稳定性高等特点,被广泛应用于吸附、分离、催化等多个领域。近年来,MOFs作为新型气相色谱固定相用于分离异构体受到了广泛关注。与传统无机多孔材料相比,MOFs在结构和功能上展现出高度的可调性,通过合理地选择配体和金属中心,可以设计合成具有不同孔道大小和孔道环境的MOFs,从而分别从热力学和动力学角度优化色谱分离效果,有效提高分离选择性。该文结合MOFs的结构,讨论了MOFs气相色谱固定相分离不同类型分析物的分离机理。分离机理主要包括MOFs孔道的分子筛效应或形状选择性,MOFs不饱和的金属位点与分析物中不同的官能团之间产生的相互作用,分析物与MOFs孔道之间产生的不同范德华力、π-π相互作用和氢键相互作用。此外,MOFs的手性分离可能主要依赖于外消旋体与手性MOFs中手性活性位点之间的相互作用。该文也对不同分析目标物进行了归类,综述了多种MOFs气相色谱固定相对烷烃、二甲苯异构体和乙基甲苯、外消旋体、含氧有机物、环境有机污染物的气相色谱分离效果。最后,该文还对MOFs在该领域的应用进行了总结与展望,旨在为MOFs气相色谱高效分离的研究提供参考。

关键词: 气相色谱, 固定相, 手性分离, 金属有机骨架

Abstract:

Metal-organic frameworks (MOFs) are a new class of porous materials, which are synthesized using organic ligands and inorganic metal ions or metal clusters. MOFs possess tunable structures through the self-assembly of a large number of organic linkers and metal nodes, which is beyond the scope of conventional porous materials. In addition, MOFs have excellent properties, including the lowest density (as low as 0.13 g/cm), highest specific surface area (as high as 10400 m²/g), and largest pore aperture (as large as 9.8 nm) among all porous materials reported till date. Because of their high porosity, large surface area, tunable apertures, as well as high chemical and thermal stabilities, MOFs have been widely applied in the fields of adsorption, separation, and catalysis. In addition, MOFs have been successfully applied as stationary phases for isomer separation in gas chromatography (GC). Since the use of the first MOF (MOF-508) packed column for the separation of alkane isomers in GC, several other MOFs (e. g., MIL-47, MOF-5, and ZIF-8) have been employed for the GC separation of isomers. However, packed-column-type separation not only requires gram-scale quantities of MOFs, thereby increasing the analysis cost, but also results in poor separation efficiency. The first MOF (MIL-101) capillary column designed toward cost reduction allowed for the baseline separation of xylene and ethylbenzene isomers within 100 s under constant-temperature conditions. Since then, the capillary-type column has been widely utilized in the MOF-based stationary phase for GC separation.
Alkanes, xylene isomers and ethyl toluene, oxy-organics and organic pollutants are not only important chemicals in industry but also harmful environmental pollutants. Thus, the separation of these analytes is of practical importance environmental monitoring and industrial quality control. However, it is difficult to realize the efficient separation and detection of these isomers or racemates because of their similar boiling points and molecular sizes. In the past decades, GC was utilized as a rapid and efficient technique for the separation of the abovementioned analytes. The stationary phase used in GC plays a dominant role in the separation processes. This review summarizes the MOF-based GC separation of the abovementioned targets based on the different classification of analytes, including alkanes, xylenes, racemates, oxy-organics and persistent organic pollutants.
The separation mechanisms of different analytes are also discussed according to the structural benefits of MOFs. The separation mechanisms mainly involve van der Waals forces between the MOFs and analytes, interactions between the unsaturated metal sites and different functional groups of the analytes, molecular sieve effect or shape selectivity, and hydrogen-bond or π-π interactions. In addition, the chiral recognition abilities of MOFs possibly depend on the interactions between the chiral active sites in chiral MOFs and racemates.
Furthermore, efficient GC separation is influenced by thermodynamic and kinetic factors. The thermodynamic factor is mainly the difference between the partition coefficients of the separated components, which also reflects the properties of the analytes as well as the interactions between the stationary phase and the analytes. The kinetic factor also affects the column efficiency and chromatographic peak shape. Compared with traditional inorganic porous materials, MOFs with tunable structures are more favorable for optimizing the separation of isomers from both thermodynamic and kinetic standpoints. Therefore, this review summarizes the separation mechanism when using MOFs as stationary phases for isomer separation via thermodynamic and kinetic analyses. We hope the review would aid the state-of-art design of MOF stationary phases for high efficient isomer separations in GC.

Key words: gas chromatography (GC), stationary phase, chiral separation, metal-organic frameworks (MOFs)

中图分类号:

O658

汤雯淇, 孟莎莎, 徐铭, 古志远. 基于金属有机骨架材料固定相的气相色谱分离应用[J]. 色谱, 2021, 39(1): 57-68.

TANG Wenqi, MENG Shasha, XU Ming, GU Zhiyuan. Application of gas chromatography separation based on metal-organic framework material as stationary phase[J]. Chinese Journal of Chromatography, 2021, 39(1): 57-68.

图/表 11

图 1 MOFs作为固定相用于气相色谱分离示意图

Fig. 1 Schematic diagram of MOFs used as stationary phase for gas chromatography separation MOFs: metal-organic frameworks.

图 2 二甲苯和乙基甲苯(a)在UiO-66毛细管柱和(b)在MIL-101毛细管柱中的气相色谱图[31,32]

Fig. 2 Gas chromatograms of xylene and ethylbenzene on the (a) UiO-66 and (b) MIL-101 capillary columns[31,32]

表 1 MOFs和MOFs复合材料作为气相色谱固定相分离烷烃异构体

Table 1 MOFs and MOFs composite materials used as gas chromatography stationary phase to separate alkane isomers

Stationary phase	Formula	Surface area/ (m²/g)	Thermal stability/ ℃	Column	Ref.
UiO-66	Zr₆O₄(OH)₄(BDC)₆	614	500	capillary	[31]
MOF-508	Zn(BDC)(4,4'-Bipy)_0.5	946	360	packed	[35]
ZIF-8	Zn(mim)₂	1504	380-500	packed	[36]
ZIF-8	Zn(mim)₂	1504	380-500	capillary	[37,38]
Graphene-ZIF-8 composite			400	capillary	[39]
UiO-66	Zr₆O₄(OH)₄(BDC)₆	614	500	packed	[40]
MOF-CJ3	[HZn₃(OH)(TBC)₂(2H₂O)(DMF)]·H₂O	525	250	capillary	[41]
ZIF-90	Zn(C₄H₃N₂O)₂	1270	300	capillary	[42]

图 3 (a)MOF-508结构图和(b)MOF-508填充柱分离烷烃异构体的色谱图[35]

Fig. 3 (a) Structure of MOF-508 and (b) chromatogram of the alkane isomers separated by MOF-508 packed column[35]

表 2 MOFs和MOFs复合材料作为气相色谱固定相分离二甲苯和乙基甲苯异构体

Table 2 MOFs and MOFs composites as GC stationary phases for the separation of xylene and ethylbenzene isomers

Stationary phases	Formula	Surface area/(m²/g)	Thermal stability/ ℃	Column
MIL-101	Cr₃O(H₂O)₂F(BDC)₃	2376-2907	300	capillary	[32]
Zr-BTB	[Zr₆O₄(OH)₄(BTB)₂](H₂O)₄(OH)₄(FA)_0.5	338.3	400	capillary	[33]
MIL-47	V^IVO(BDC)	800	350	packed	[52]
MOF-5	Zn₄O(BDC)₃		500	packed	[53]
MCF-50	[Zn(Hpidba)]·2.6DMF H₂O	1319	350	capillary	[54]
MAF-6	RHO-[Zn(eim)₂]	1695	400	capillary	[55]
ZIF-8@PDMS core-shell microspheres		1290	500	packed	[56]

图 4 (a)二维Zr-BTB-FA纳米片的结构图和(b~g)2D-Zr-BTB-FA色谱柱分离6组苯取代物异构体的色谱图[33]

Fig. 4 (a) Structure of 2D-Zr-BTB-FA nanosheet and (b-g) gas chromatograms of six groups of substituted aromatic isomers separated on the 2D-Zr-BTB-FA coated column[33]

表 3 MOFs和MOFs复合材料作为气相色谱固定相分离二甲苯和乙基甲苯异构体

Table 3 MOFs and MOFs composites as GC stationary phases for the separation of racemates

Chiral stationary phases	Surface area/(m²/g)	Thermal stability/ ℃	Racemates	Ref.
[Cu(sala)]_n	11	220	1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11	[44]
Co(D-Cam)_1/2(bdc)_1/2(tmdpy)		250	1, 7, 9, 11, 12, 13, 14	[45]
InH(D-C₁₀H₁₄O₄)₂	497	230	1, 7, 9, 11, 14, 12, 15	[46]
Ni(D-Cam)(H₂O)₂		250	1, 3, 4, 7, 9, 10, 13, 14, 15	[47]
[(CH₃)₂NH₂][Cd(bpdc)_1.5]·2DMA	43	350	1, 4, 13, 15, 16, 17	[48]
Zn(ISN)₂·2H₂O	150	350	1, 3, 7, 9, 10, 11	[49]
In₃O(obb)₃(HCO₂)(H₂O)		350	4, 7, 9, 12, 17	[58]
[Zn₂(D-Cam)₂(4,4'-bpy)]_n		400	1, 9, 12, 14, 17, 21,	[59]
Co(D-Cam)_1/2(bdc)_1/2(tmdpy)+β-CD		250	1, 4, 12, 18, 19, 20, 22, 25, 43	[60]
InH(D-C₁₀H₁₄O₄)₂+β-CD			1, 4, 11, 12, 18, 19, 20	[61]
[Cd(LTP)₂]_n+β-CD		220	1, 3, 8, 11, 12, 14, 19, 20, 22, 23, 24, 25, 26, 27	[62]
MIL-101(Al)-NH₂-Xs	441-1292	250-350	1, 14, 23, 36, 37, 38, 39, 40, 41, 42	[63]

图 5 (a)手性[Cu(sala)]n的三维结构图和[Cu(sala)]n手性柱分离(b)异亮氨酸、(c)香茅醛、(d)1-苯基-1,2-乙二醇外消旋体的气相色谱图[44]

Fig. 5 (a) Structure of chiral [Cu(sala)]n and gas chromatograms of racemates of (b) isoleucine derivative,(c) citronellal and (d) 1-phenyl-1,2-ethandiol separated on the [Cu(sala)]n coated column[44]

图 6 手性MIL-101(Al)-Xs的后合成示意图[63]

Fig. 6 Schematic diagram of the post-synthesis of chiral MIL-101(Al)-Xs[63]

表 4 MOFs和MOFs复合材料分离含氧有机物和有机污染物

Table 4 Separation of oxy-organics and organic pollutants on MOFs and MOFs composites

Stationary phase	Surface area/(m²/g)	Thermal stability/ ℃	Analyte	Ref.
Ni(pybz)₂	228	220	oxy-organic	[65]
Cd(D-Cam)(tmdpy)		215	oxy-organics	[66]
Zn₂(bdc)(L-lac)	190	350	oxy-organics	[67]
[Mn₃(HCOO)₂(D-cam)₂(DMF)₂]_n		230	oxy-organics	[68]
HKUST-1 (Cu₃(BTC)₂)	404-629	220-280	oxy-organics	[69]
IRMOF-1 (Zn₄O(BDC)₃)	2517	400	organic pollutants	[71]
IRMOF-3 (Zn₄O(NH₂-BDC)₃)	1957	320	organic pollutants	[71]
IRMOF-8 (Zn₄O(NDC)₃)	1343	500	organic pollutants	[72]
184 silicone@MAF5		400	organic pollutants	[73]

图 7 (a) IRMOF-3柱和(b) IRMOF-1柱分离多氯联苯的色谱图[71]

Fig. 7 Chromatograms of the polychlorinated biphenyls (PCBs) separation on (a) IRMOF-3 and (b) IRMOF-1 columns[71] 1. PCB-28; 2. PCB-52; 3. PCB-77; 4. PCB-81; 5. PCB-101; 6. PCB-105; 7. PCB-118; 8. PCB-114; 9. PCB-126; 10. PCB-138; 11. PCB-153; 12 PCB-167; 13. PCB-156; 14, PCB-157; 15. PCB-169.

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基于金属有机骨架材料固定相的气相色谱分离应用

Application of gas chromatography separation based on metal-organic framework material as stationary phase

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