| 599 | 8 | 408 |
| 下载次数 | 被引频次 | 阅读次数 |
金属有机框架(MOF)材料具有高比表面积、高孔隙率、精准的孔道形貌和可调的孔道尺寸等独特性质,在气体分离/净化/存储、非均相催化反应、水处理以及生物医药等领域有着巨大的应用潜能,作为重要的新型功能材料引起了国内外的广泛关注。经过近二十多年的深入研究,在MOF材料的制备方法和物理化学性质等方面已经取得了很大的进展,当前的主要焦点在于如何实现MOF材料的工业化大规模实际应用。然而,MOF材料自身的诸多内在缺陷,尤其是化学不稳定性特别是易水解、较弱的力学强度以及多晶粉末导致难以加工成型等严重制约了其工业应用。在本综述中,我们将对MOF材料实际应用过程中面临的一些主要挑战和最新的对应策略进行简单综述。
Abstract:Metal-organic frameworks(MOFs) have unique properties such as high specific surface area, abundant porosity, as well as rich micropores with precise morphologies and tunable sizes. MOFs have great potential applications in separation, purification and storage of gas, heterogeneous catalysis, water treatment and biomedicines, etc. Therefore, MOFs have attracted ever-growing attention in the past decades. After nearly two decades of intensive investigation, significant progress has been made in preparation of countless kinds of MOFs and their physicochemical properties. The current focus is on how to implement the large-scale industrial applications of MOF materials with promising functionalities as demonstrated at the lab scale. However, many inherent shortcomings of MOF materials have delayed the process of extending MOFs into practical industrial applications. Especially, the following three properties of many MOFs have been the main bottlenecks that are needed to be considered: chemical instability such as vulnerability to hydrolysis, weak mechanical strength, and difficulty in processing into practical material forms due to polycrystalline powders. In this review, we provide a brief overview of these three main challenges facing the practical applications of MOFs and the state-of-the-art strategies that have been reported to address such challenges.
[1] Deng H, Grunder S, Cordova K E, Valente C, Furukawa H, Hmadeh M, Gándara F, Whalley A C, Liu Z, Asahina S. Large-pore apertures in a series of metal-organic frameworks[J].Science, 2012, 336:1018-1023.
[2] Furukawa H, Cordova K E, O'Keeffe M, Yaghi O M. The chemistry and applications of metal-organic frameworks[J]. Science, 2013, 341:1230444.
[3] Xu L-H, Li S-H, Mao H, Li Y, Zhang A-S, Wang S, Liu W-M, Lv J, Wang T, Cai W-W.Highly flexible and superhydrophobic MOF nanosheet membrane for ultrafast alcohol-water separation[J]. Science, 2022, 378:308-313.
[4] Herm Z R, Wiers B M, Mason J A, van Baten J M, Hudson M R, Zajdel P, Brown C M,Masciocchi N, Krishna R, Long J R. Separation of hexane isomers in a metal-organic framework with triangular channels[J]. Science, 2013, 340:960-964.
[5] Rowsell J L, Spencer E C, Eckert J, Howard J A, Yaghi O M. Gas adsorption sites in a largepore metal-organic framework[J]. Science, 2005, 309:1350-1354.
[6] Czaja A U, Trukhan N, Müller U. Industrial applications of metal-organic frameworks[J].Chemical Society Reviews, 2009, 38:1284-1293.
[7] Chen B, Ockwig N W, Millward A R, Contreras D S, Yaghi O M. High H2 adsorption in a microporous metal-organic framework with open metal sites[J]. Angewandte Chemie International Edition, 2005, 44:4745-4749.
[8] Bobbitt N S, Mendonca M L, Howarth A J, Islamoglu T, Hupp J T, Farha O K, Snurr R Q.Metal-organic frameworks for the removal of toxic industrial chemicals and chemical warfare agents[J]. Chemical Society Reviews, 2017, 46:3357-3385.
[9] DeCoste J B, Peterson G W. Metal-organic frameworks for air purification of toxic chemicals[J]. Chemical Reviews, 2014, 114:5695-5727.
[10] Mondloch J E, Katz M J, Isley Iii W C, Ghosh P, Liao P, Bury W, Wagner G W, Hall M G,DeCoste J B, Peterson G W. Destruction of chemical warfare agents using metal-organic frameworks[J]. Nature Materials, 2015, 14:512-516.
[11] Aubrey M L, Long J R. A dual-ion battery cathode via oxidative insertion of anions in a metalorganic framework[J]. Journal of the American Chemical Society, 2015, 137:13594-13602.
[12] Colón Y J, Snurr R Q. High-throughput computational screening of metal-organic frameworks[J]. Chemical Society Reviews, 2014, 43:5735-5749.
[13] Rubio-Martinez M, Avci-Camur C. Thornton A W, Imaz I, Maspoch D, Hill M R, New synthetic routes towards MOF production at scale[J]. Chemical Society Reviews, 2017, 46:3453-3480.
[14] Silva P, Vilela S M, ToméJ P, Paz F A A. Multifunctional metal-organic frameworks:from academia to industrial applications[J]. Chemical Society Reviews, 2015, 44:6774-6803.
[15] Chen Z, Wasson M C, Drout R J, Robison L, Idrees K B, Knapp J G, Son F A, Zhang X,Hierse W, Kühn C. The state of the field:from inception to commercialization of metalorganic frameworks[J]. Faraday Discussions, 2021, 225:9-69.
[16] Freund R, Zaremba O, Arnauts G, Ameloot R, Skorupskii G, Dinc?M, Bavykina A, Gascon J, Ejsmont A, Goscianska J. The current status of MOF and COF applications[J]. Angewandte Chemie International Edition, 2021, 60:23975-24001.
[17] Faust T. MOFs move to market[J]. Nature chemistry, 2016, 8:990-991.
[18] Burtch N C, Jasuja H, Walton K S. Water stability and adsorption in metal-organic frameworks[J]. Chemical Reviews, 2014, 114:10575-10612.
[19] Gelfand B S, Shimizu G K. Parameterizing and grading hydrolytic stability in metalorganic frameworks[J]. Dalton Transactions, 2016, 45:3668-3678.
[20] Howarth A J, Liu Y, Li P, Li Z, Wang T C, Hupp J T, Farha O K. Chemical, thermal and mechanical stabilities of metal-organic frameworks[J]. Nature Reviews Materials, 2016,1:15018.
[21] McHugh L N, McPherson M J, McCormick L J, Morris S A, Wheatley P S, Teat S J,McKay D, Dawson D M, Sansome C E, Ashbrook S E. Hydrolytic stability in hemilabile metal-organic frameworks[J]. Nature Chemistry, 2018, 10:1096.
[22] Al-Janabi N, Hill P, Torrente-Murciano L, Garforth A, Gorgojo P, Siperstein F, Fan X.Mapping the Cu-BTC metal-organic framework(HKUST-1)stability envelope in the presence of water vapour for CO2 adsorption from flue gases[J]. Chemical Engineering Journal, 2015, 281:669-677.
[23] Greathouse J A, Allendorf M D. The interaction of water with MOF-5 simulated by molecular dynamics[J]. Journal of the American Chemical Society, 2006, 128:10678-10679.
[24] Lv X-L, Yuan S, Xie L-H, Darke H F, Chen Y, He T, Dong C, Wang B, Zhang Y-Z, Li J-R.Ligand rigidification for enhancing the stability of metal-organic frameworks[J]. Journal of the American Chemical Society, 2019, 141:10283-10293.
[25] Taylor J M, Vaidhyanathan R, Iremonger S S, Shimizu G K. Enhancing water stability of metal-organic frameworks via phosphonate monoester linkers[J]. Journal of the American Chemical Society, 2012, 134:14338-14340.
[26] Cadiau A, Belmabkhout Y, Adil K, Bhatt P M, Pillai R S, Shkurenko A, Martineau-Corcos C, Maurin G, Eddaoudi M. Hydrolytically stable fluorinated metal-organic frameworks for energy-efficient dehydration[J]. Science, 2017, 356:731-735.
[27] Ding N, Li H, Feng X, Wang Q, Wang S, Ma L, Zhou J, Wang B. Partitioning MOF-5 into confined and hydrophobic compartments for carbon capture under humid conditions[J].Journal of the American Chemical Society, 2016, 138:10100-10103.
[28] Sun Q, He H, Gao W-Y, Aguila B, Wojtas L, Dai Z, Li J, Chen Y-S, Xiao F-S, Ma S. Imparting amphiphobicity on single-crystalline porous materials[J]. Nature Communications, 2016, 7:1-7.
[29] Nguyen J G, Cohen S M. Moisture-resistant and superhydrophobic metal-organic frameworks obtained via postsynthetic modification[J]. Journal of the American Chemical Society, 2010, 132:4560-4561.
[30] Decoste J B, Peterson G W, Smith M W, Stone C A, Willis C R. Enhanced stability of CuBTC MOF via perfluorohexane plasma-enhanced chemical vapor deposition[J]. Journal of the American Chemical Society, 2012, 134:1486-1489.
[31] Yang C, Kaipa U, Mather Q Z, Wang X, Nesterov V, Venero A F, Omary M A. Fluorous metal-organic frameworks with superior adsorption and hydrophobic properties toward oil spill cleanup and hydrocarbon storage[J]. Journal of the American Chemical Society, 2011,133:18094-18097.
[32] Zhang W, Hu Y, Ge J, Jiang H-L, Yu S-H. A facile and general coating approach to moisture/water-resistant metal-organic frameworks with intact porosity[J]. Journal of the American Chemical Society, 2014, 136:16978-16981.
[33] Zhang Z, Nguyen H T H, Miller S A, Ploskonka A M, DeCoste J B, Cohen S M. Polymermetal-organic frameworks(polyMOFs)as water tolerant materials for selective carbon dioxide separations[J]. Journal of the American Chemical Society, 2016, 138:920-925.
[34] Burtch N C, Heinen J, Bennett T D, Dubbeldam D, Allendorf M D. Mechanical properties in metal-organic frameworks:emerging opportunities and challenges for device functionality and technological applications[J]. Advanced Materials, 2018, 30:1704124.
[35] Redfern L R, Farha O K. Mechanical properties of metal-organic frameworks[J]. Chemical Science, 2019, 10:10666-10679.
[36] Chapman K W, Halder G J, Chupas P J. Pressure-induced amorphization and porosity modification in a metal-organic framework[J]. Journal of the American Chemical Society,2009, 131:17546-17547.
[37] Sarkisov L, Martin R L, Haranczyk M, Smit B. On the flexibility of metal-organic frameworks[J]. Journal of the American Chemical Society, 2014, 136:2228-2231.
[38] Su Z, Miao Y-R, Zhang G, Miller J T, Suslick K S. Bond breakage under pressure in a metal organic framework[J]. Chemical Science, 2017, 8:8004-8011.
[39] Nandasiri M I, Jambovane S R, McGrail B P, Schaef H T, Nune S K. Adsorption,separation, and catalytic properties of densified metal-organic frameworks[J]. Coordination Chemistry Reviews, 2016, 311:38-52.
[40] Iizuka T, Honjo K, Uemura T. Enhanced mechanical properties of a metal-organic framework by polymer insertion[J]. Chemical Communications, 2019, 55:691-694.
[41] Peng L, Yang S, Jawahery S, Moosavi S M, Huckaba A J, Asgari M, Oveisi E, Nazeeruddin M K, Smit B, Queen W L. Preserving porosity of mesoporous metal-organic frameworks through the introduction of polymer guests[J]. Journal of the American Chemical Society,2019, 141:12397-12405.
[42] Kapustin E A, Lee S, Alshammari A S, Yaghi O M. Molecular retrofitting adapts a metalorganic framework to extreme pressure[J]. ACS Central Science, 2017, 3:662-667.
[43] Li Z, Zeng H C. Armored MOFs:enforcing soft microporous MOF nanocrystals with hard mesoporous silica[J]. Journal of the American Chemical Society, 2014, 136:5631-5639.
[44] Connolly B M, Madden D G, Wheatley A E, Fairen-Jimenez D. Shaping the future of fuel:Monolithic metal-organic frameworks for high-density gas storage[J]. Journal of the American Chemical Society, 2020, 142:8541-8549.
[45] Falcaro P, Ricco R, Doherty C M, Liang K, Hill A J, Styles M J. MOF positioning technology and device fabrication[J]. Chemical Society Reviews, 2014, 43:5513-5560.
[46] Ren J, Langmi H W, North B C, Mathe M. Review on processing of metal-organic framework(MOF)materials towards system integration for hydrogen storage[J].International Journal of Energy Research, 2015, 39:607-620.
[47] Chen Y, Huang X, Zhang S, Li S, Cao S, Pei X, Zhou J, Feng X, Wang B. Shaping of metalorganic frameworks:from fluid to shaped bodies and robust foams[J]. Journal of the American Chemical Society, 2016, 138:10810-10813.
[48] Longley L, Collins S M, Li S, Smales G J, Erucar I, Qiao A, Hou J, Doherty C M, Thornton A W, Hill A J. Flux melting of metal-organic frameworks[J]. Chemical Science, 2019, 10:3592-3601.
[49] Cui X-Y, Gu Z-Y, Jiang D-Q, Li Y, Wang H-F, Yan X-P. In situ hydrothermal growth of metal-organic framework 199 films on stainless steel fibers for solid-phase microextraction of gaseous benzene homologues[J]. Analytical Chemistry, 2009, 81:9771-9777.
[50] Liu J, W?ll C. Surface-supported metal-organic framework thin films:fabrication methods,applications, and challenges[J]. Chemical Society Reviews, 2017, 46:5730-5770.
[51] Li S C, Hu B C, Shang L M, Ma T, Li C, Liang H W, Yu S H. General synthesis and solution processing of metal-organic framework nanofibers[J]. Advanced Materials, 2022:2202504.
[52] Brown A J, Brunelli N A, Eum K, Rashidi F, Johnson J, Koros W J, Jones C W, Nair S.Interfacial microfluidic processing of metal-organic framework hollow fiber membranes[J]. Science, 2014, 345:72-75.
[53] Ma X, Kumar P, Mittal N, Khlyustova A, Daoutidis P, Mkhoyan K A, Tsapatsis M. Zeolitic imidazolate framework membranes made by ligand-induced permselectivation[J]. Science,2018, 361:1008-1011.
[54] Kitao T, Zhang Y, Kitagawa S, Wang B, Uemura T. Hybridization of MOFs and polymers[J]. Chemical Society Reviews, 2017, 46:3108-3133.
[55]曹香慧,张珍坤,李建垚,郑春熊,叶子涵,吴松海.通过“graft from”方法对金属有机框架进行聚合物接枝构建疏水性质的mof@polymer复合纳米粒子[J].离子交换与吸附,2020, 36(5):394-403
[56] Yao Y, Wang C, Na J, Hossain M S A, Yan X, Zhang H, Amin M A, Qi J, Yamauchi Y, Li J.Macroscopic MOF architectures:effective strategies for practical application in water treatment[J]. Small, 2022, 18:2104387.
[57] Kalaj M, Bentz K C, Ayala Jr S, Palomba J M, Barcus K S, Katayama Y, Cohen S M. MOFpolymer hybrid materials:from simple composites to tailored architectures[J]. Chemical Reviews, 2020, 120:8267-8302.
[58]李建垚,张珍坤,郑春熊,曹香慧,叶子涵,吴松海.常压开放体系下UIO-66纳米粒子有机金属框架材料的合成方法[J].离子交换与吸附, 2020, 36(11):530-540
基本信息:
DOI:10.16026/j.cnki.iea.2023010075
中图分类号:O641.4
引用信息:
[1]陈亿昂,耿玘薇,曹香慧,等.金属有机框架材料工业应用中面临的挑战以及最新应对策略[J].离子交换与吸附,2023,39(01):75-86.DOI:10.16026/j.cnki.iea.2023010075.
基金信息:
国家自然科学基金面上项目(No.52273022)