Porous Aromatic Frameworks as a Platform for Multifunctional

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Porous Aromatic Frameworks as a Platform for Multifunctional Applications Ye Yuan and Guangshan Zhu*

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Key Laboratory of Polyoxometalate Science of Ministry of Education, Northeast Normal University, Changchun 130024, China

ABSTRACT: Porous aromatic frameworks (PAFs), which are well-known for their large surface areas, associated porosity, diverse structures, and superb stability, have recently attracted broad interest. Taking advantage of widely available building blocks and various coupling strategies, customized porous architectures can be prepared exclusively through covalent bonding to satisfy necessary requirements. In addition, PAFs are composed of phenyl-ring-derived fragments that are easily modified with desired functional groups with the help of established synthetic chemistry techniques. On the basis of material design and preparative chemistry, this review mainly focuses on recent advances in the structural and chemical characteristics of PAFs for potential utilizations, including molecule storage, gas separation, catalysis, and ion extraction. Additionally, a concise outlook on the rational construction of functional PAFs is discussed in terms of developing next-generation porous materials for broader applications.



INTRODUCTION Porous materials are divided into inorganic porous materials (zeolites, carbon, etc.), inorganic−organic hybrid porous materials (MOFs, CPs, etc.), and organic porous materials in accordance with structural compositions.1 Emerging as a novel functional platform, organic porous materials are a new research hotspot in the fields of physics, chemistry, and material science.2 As a result of the combined advantages of both porous solids and polymers, organic porous materials are endued with high surface areas, tunable architectures, welldefined porosities, and facile machinabilities.3−5 In addition, a variety of synthetic techniques facilitate the design and preparation of diverse organic porous materials that incorporate key physical properties and chemical functionalities into a porous skeleton or at the pore surface.6,7 To date, substantial advances have been made in the use of these materials in gas storage and separation,8−17 catalysis,18−23 energy storage,24−35 sustained drug release,36 and many other applications.37−47 Despite rapid progress, the variety of talents involved in this research encourage the preparation of a universal strategy to synthesize organic porous materials with tailor-made pore structures and specific functionalities. Thanks to the continual developments of organic chemistry, organic porous materials can be customized with unique textures, such as crystalline structures and amorphous © XXXX American Chemical Society

structures, through diverse coupling reactions. The crystalline materials are mainly classified as covalent organic frameworks (COFs),48−50 porous organic cages (CCs),51,52 and extrinsic porous molecules (EPMs).53−55 Typical amorphous structures in a timed sequence include hyper-cross-linked polymers (HCPs),56,57 polymers of intrinsic microporosity (PIMs),58,59 conjugated microporous polymers (CMPs),60,61 covalent triazine frameworks (CTFs),62 and porous aromatic frameworks (PAFs),63 among others (Figure 1).64−75 In this Outlook, we focus on PAFs as a representative organic porous material to investigate the correlation between structure and function and propose some feasible strategies to guide the preparation and development of porous materials for practical applications. PAFs are constructed by the effective assembly of organic building blocks through covalent coupling reactions, because they predominantly consist of 2D/3D periodic aromatic frameworks.76−79 Unlike conventional COFs, which are obtained by reversible organic condensation reactions, PAFs are prepared via irreversible cross-coupling reactions (generally, C−C coupling) and concomitantly possess high surface areas, open architectures, robust skeletons, and excellent Received: January 17, 2019

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Figure 2. Ullmann coupling reaction for porous framework with large surface area. Reprinted with permission from ref 63. Copyright 2009, Wiley-VCH.

block, tetrakis(4-bromophenyl)methane, and found that PAF-1 exhibits an ultrahigh specific surface area (BET: 5600 m2 g−1, Langmuir: 7100 m2 g−1) which is close to that of the ordered, crystalline versions.63 This high porosity is mainly attributed to the fact that the solvent templating effect of framework− solvent or solvent−solvent interactions prevents the structural interpenetration calculated using the Forcite module compared to the amorphous and dia Models.76,80 PAF-1 reveals excellent stability and provides open and interconnected channels for guest molecules, making it useful for molecular storage; it can hold 29.5 mmol g−1 of carbon dioxide at 298 K and 40 bar, 75.3 mg g−1 of hydrogen at 77 K and 48 bar, or 1.86 g g−1 of iodine vapor at 298 K and 40 Pa.81 Using the same coupling strategy, a series of PAFs with quadricovalent Si (PAF-3) and Ge (PAF-4) atoms in lieu of the C center were synthesized with high surface areas (up to 2932 m2 g−1).11 They possess considerable adsorption capacities for gas molecules, including hydrogen, methane, and carbon dioxide. Coincidentally, Prof. Zhou’s group replaced the central carbon of PAF-1 with other quadricovalent centers to develop porous structures that also illustrate exceptionally high surface areas.66 On the basis of this solid foundation, the target synthesis of functional PAF materials has harvested the rapid development by conditioning the surface area, pore size, and functionalization sites (Figure 3).82−88 Normally, the specific features can be regulated by the accommodation of building blocks with precise shape, size, hybridization, or heterocyclic units, followed by convenient synthetic methodologies to transform monomers into cross-linked textures, such as (1) ionization of porous frameworks or (2) molecularly imprinted porous aromatic frameworks. In regard to (1), the charges and electrostatically bound counterions along the channel walls result in a pore skeleton with intrinsic charge repulsion/affinity effects for guest molecules through polarization effects/ chemical bonding.89−91 In regard to (2), using a PAF as a novel scaffold, the introduction of molecular imprinting technology into porous skeletons will endow polymeric matrices with selective recognition capabilities.92−94

Figure 1. Chemical structures of diversified porous materials.

stabilities. The free rotation of polyhedral monomers and uncorrected orientation of condensed oligomeric fragments leads to framework defects and an irregular internal structure. Sharing unordered structures, PAF materials featuring rigid building blocks, topology-oriented construction, short-range ordered structure, superb stability, and intrinsic porosity differ from other cross-linked polymers, such as HCPs, in an apparent manner. Obtained from the interlinked polymer chains after being untangled by the solvent, HCPs reveal conspicuous swelling and a complete disordered structure; PIMs, whose 1D rigid chains with contorted/disfigured aromatic fragments lose their ability to pack efficiently, render the solubility and intrinsic microporosity.56,58,77

Unlike conventional COFs, which are obtained by reversible organic condensation reactions, PAFs are prepared via irreversible cross-coupling reactions (generally, C−C coupling) and concomitantly possess high surface areas, open architectures, robust skeletons, and excellent stabilities.

Normally, the specific features can be regulated by the accommodation of building blocks with precise shape, size, hybridization, or heterocyclic units, followed by convenient synthetic methodologies to transform monomers into cross-linked textures.

The groundbreaking work on PAFs is evaluated from computational studies that filled the C−C spaces of a diamond with multiple phenyl rings to produce highly porous architectures with theoretical surface areas ranging from 2000 to 6000 m2 g−1 (Figure 2).63,80 In 2009, Profs. Qiu and Zhu synthesized the porous aromatic framework PAF-1 via a one-step Ullmann polycondensation of a tetrahedral building

On the basis of our summary, a universal methodology is infeasible for the field to achieve high yields and great B

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Figure 3. Targeted design and preparation of PAFs for gas separation, molecular storage, ion extraction, and catalysis.

homogeneity, multivariate behavior, surface area, and hybrid materials. As for the unique superiority of each strategy, this review focuses on the advantages of postsynthetic functionalization for preparing well-defined porous structures and addresses the ongoing efforts to establish function-oriented design methods for PAF products. Because of the amount of work that has been performed in this field, this article only builds upon representative works published after 2015. PAF-1 as a Platform. A high surface area is a fascinating characteristic for porous materials that will provide accessible space for guest molecule storage. However, it is difficult to challenge the conventional routine for the construction of high porosity.95,96 Inspired by the study of PAF-1, our group designed and synthesized two PAF materials, named PAF-100 and PAF-101, via a strategy of engineering specific building units. PAF-100 and PAF-101 present high BET surface areas exceeding 5000 m2 g−1 together with uniform pore size distributions (Figure 4).97 PAF-100 and PAF-101 rendered high methane uptake values of 742 and 622 cm3 g−1, respectively, at 298 K and 70 bar. A similar concept was investigated by Prof. Eddaoudi’s group, who implemented a molecular-building-block strategy to isolate three porous frameworks, namely, KPOP-1, KPOP-2, and KPOP-3 (KPOP = KAUST’s POP).98 KPOP-1 and KPOP-2 exhibit high specific BET surface areas (ca. 5120 and 5730 m2 g−1) and outstanding gravimetric methane storage properties (0.515 g g−1 at 298 K and 80 bar). Renowned for its ultrahigh surface area, PAF-1 demonstrates outstanding molecular adsorption capacities.63 Its periodic

Figure 4. Synthetic route of PAF-100 (a) and PAF-101 (b) using dimer-type molecular building block units. Reprinted with permission from ref 97. Copyright 2018, Wiley-VCH.

aromatic components constructed through covalent bonds possess high physicochemical stability even under extreme conditions (strong acid/base or organic solvent systems). Some attempts at postsynthetic functionalization, such as optimization of the pore sizes and modification of the existing constituents, have been exploited to improve the capabilities of this material. Incorporating diarylethene (DArE) into PAF-1 modulates its channel environment to afford a new type of photodynamic material (DArE@PAF-1), as shown in Figure 5.99 The successful inclusion of DArE in the PAF framework was indicated by a reduction in the pore surface and pore size C

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Figure 5. PAF-1 loaded with the diarylethene dye o-DArE will release the adsorbed CO2 under visible light (a). The reversible cyclization reaction of the dye (b). Reprinted with permission from ref 99. Copyright 2015, Wiley-VCH.

distributions. As a result of the confinement effect, the PAF-1 cavity provides a sterically hindered environment and inhibits the photocyclization of DArE molecules through aromatic stacking and H-bonding interactions. The photoswitching of DArE@PAF-1 enhances the binding affinity between DArE and CO2, which triggers carbon capture and release. In addition, during the formation of a parallel o-DArE conformer, the competition of DArE and CO2 with PAF-1 weakens the intermolecular interactions between the adsorption sites and CO2 molecules, resulting in the instantaneous CO2 release. The modulation of the photoresponse in porous skeletons offers an advantageous route for the capture and release of gas molecules. PAFs combine the substantial merits of inorganic materials and inorganic−organic hybrids, giving rise to a tunable pore environment and physicochemical stability. Their open pores are accessible to various functional groups or molecular assemblies for further decoration. The considerable stability and readily modified chemistry motivate the introduction of various desired chemical functionalities in a facile and dense manner. Upon postsynthetic functionalization, the phenyl skeletons of PAFs can be densely functionalized to allow advanced applications.78,82

Hyperaccumulation of copper, an essential nutrient for life, in organisms is a sign of Wilson’s and Menkes diseases and other various neurodegenerative diseases. To create simple, selective, and sensitive diagnostic tools for copper monitoring, Profs. Long and Chang synthesized a robust three-dimensional PAF-1 that was densely functionalized with thioether groups (PAF-1−SMe).100 This material was able to selectively capture and concentrate copper ions from biological fluids and tissues (Figure 6). When combined with 8-hydroxyquinoline as a colorimetric indicator, PAF-1−SMe can be used in a noninvasive diagnostic technique to identify aberrant copper levels in urine or serum. Significantly, this work reveals a starting point to adopt functionalized porous materials for compatible, facile, and targeted diagnostic applications.

PAFs combine the substantial merits of inorganic materials and inorganic−organic hybrids, giving rise to a tunable pore environment and physicochemical stability.

Figure 6. PAF-1−SMe as a selective capture material for copper detection. Reprinted with permission from ref 100. Copyright 2016, American Chemical Society. D

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functional groups into porous materials to achieve isolated and stable functional sites for practical applications. Previous investigations on porous aromatic frameworks modified with Brønsted acid groups manifest clear merits, such as indefinite stability in strong acids and bases, allowing for multiple adsorption/stripping cycles for ammonia capture.104 Because phenyl constituents in domain positions are suitable for targeted surface functionalization, Prof. Long presented a densely functionalized PAF structure with carboxylic groups, BPP-7 (Berkeley Porous Polymer-7).105 As a result of the appropriately sized binding pocket and dense carboxylic acid groups, BPP-7 displays stronger binding affinities for neodymium than strontium ions (Figure 8) and also exhibits excellent metal loading capacities, high adsorption selectivities, and desirable recyclability. PAF-11 possesses hierarchical pore size distributions, and its mesopores can accommodate diverse organocatalysts for various reaction substrates. An amine-tagged PAF (PAF70− NH2) can covalently immobilize large organocatalysts inside its mesopores to create the thiourea-containing PAF resultant PAF70−thiourea, which catalyzes N-bromosuccinimide (NBS)-mediated oxidation of alcohols and shows a higher catalytic activity than that of the homogeneous catalyst.106 Our group then adopted mesoporous PAF70−NH2 as a support to develop a palladium (Pd)-based molecular catalyst (PAF70Pd).107 The unique porous skeleton of PAF allows an ultrahigh Pd content, and thus, PAF70-Pd has extremely high catalytic activity in Suzuki−Miyaura coupling reactions (Figure 9). The modified PAF solid manifests a perfect example of using PAF as an authentic scaffold for heterogeneous organocatalysis. As a result of their facile preparation, good activity, and benign stability, bimetallic Ni−W and Ni−Mo sulfides were fixed on a PAF platform by decomposition of [(n-Bu)4N]2[Ni(MeS4)2] (Me = W, Mo) complexes to serve as sulfide catalysts.108 The activities of PAF catalysts have been investigated using naphthalene as a model substrate, and these catalysts show the highest reported naphthalene conversion rates in hydrogenation and can catalyze hydrocracking of naphthalene. Moreover, PAF supports can be extended to bifunctional catalysis systems that mediate multiple reactions in a single reaction platform. A rhodium complex and a pyrrolidine were combined to a PAF structure based on tetraphenyladamantane and tetraphenylmethane subunits (Figure 10).109 The new PAF compound catalyzes tandem Knoevenagel condensation and olefin hydrogenation reactions. The obtained bifunctional PAF exhibits high activity

Endowed with rapid kinetics and water/chemical stability, PAF-1 has also been utilized to address the energy demand associated with extracting uranium from seawater. PAF-1 was surface functionalized with poly(acrylonitrile) through atomtransfer radical polymerization.101 After conditioning with potassium hydroxide (KOH), the poly(acrylonitrile)-functionalized PAF-1 revealed a maximum capacity of 4.81 mg g−1 after 42 days of contact with the uranium-spiked seawater. Similarly, Prof. Ma functionalized a PAF-1 skeleton with noted uranylchelating amidoxime groups to obtain a PAF-1−CH2AO for uranium extraction from water (Figure 7).102 After PAF-1 was

Figure 7. PAF-1 sample modified into PAF-1−CH2AO for uranium extraction. Reprinted with permission from ref 102. Copyright 2017, American Chemical Society.

grafted, the resultant PAF-1−CH2AO exhibited a high uranium uptake capacity of 300 mg g−1 and a rapid enrichment speed (i.e., the uranium concentration decreased from 4.1 ppm to 1.0 ppb within 90 min). Postsynthetic functionalization of PAF-1 to obtain materials with enhanced capacities for guest molecules demonstrates a task-specific design strategy for the development of functional porous materials for advanced applications. PAF-11-Derived Functional Materials. PAF-11 was polymerized through a facile Suzuki coupling reaction by using tetrakis(4-bromophenyl)methane (TBPM) and diboronic acid as building units.103 The easily modified monomers and readily manipulated synthetic procedure allow dramatic structural transformations and the incorporation of different

Figure 8. Porous structure, BPP-7, densely functionalized with carboxylic groups for selective extraction of lanthanide ions. Reprinted with permission from ref 105. Copyright 2016, American Chemical Society. E

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Figure 9. Schematic illustration of the modification of PAF-11 into PAF70−NH2 and PAF70−thiourea. Reprinted with permission from ref 107. Copyright 2018, Royal Society of Chemistry.



SUMMARY AND PERSPECTIVE This Outlook summarizes the considerable progress in the construction of functional PAFs by postsynthetic functionalization techniques. In summary, several strategies allow rational design of PAFs aimed at specific applications. First, a high conversion degree of the coupling reaction and high purity of raw materials are essential to achieve a high polymerization degree and yield and large surface area of organic porous materials. A porous framework with a high surface area is a desirable scaffold, because it has a large amount of free space to accommodate guest molecules, facilitating condensation of active species packed inside pores. Second, the incorporation of units with optical, thermodynamic, or kinetic properties and precise shapes and sizes will afford porous skeletons with inherently high capacities. Therefore, some well-designed building blocks can be exploited for the unique features. Finally, easily modified constituents in open pores are advantageous for decorating PAFs with complementary functional groups to obtain advanced activities. After

Figure 10. Schematic illustration of the preparation of bifunctionalized PAF materials with base and metal sites. Reprinted with permission from ref 109. Copyright 2016, American Chemical Society.

and excellent stability in cascade reactions, and it can be recycled more than 10 times in a production process. F

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(10) Huang, N.; Chen, X.; Krishna, R.; Jiang, D. Two-Dimensional Covalent Organic Frameworks for Carbon Dioxide Capture through Channel-Wall Functionalization. Angew. Chem., Int. Ed. 2015, 54, 2986−2990. (11) Ben, T.; Pei, C.; Zhang, D.; Xu, J.; Deng, F.; Jing, X.; Qiu, S. Gas Storage in Porous Aromatic Frameworks (PAFs). Energy Environ. Sci. 2011, 4, 3991−3999. (12) Zhao, Y.; Yao, K. X.; Teng, B.; Zhang, T.; Han, Y. A Perfluorinated Covalent Triazine-based Framework for Highly Selective and Water-tolerant CO2 Capture. Energy Environ. Sci. 2013, 6, 3684−3692. (13) Li, B.; Zhang, Y.; Krishna, R.; Yao, K.; Han, Y.; Wu, Z.; Ma, D.; Shi, Z.; Pham, T.; Space, B.; Liu, J.; Thallapally, P. K.; Liu, J.; Chrzanowski, M.; Ma, S. Introduction of π-Complexation into Porous Aromatic Framework for Highly Selective Adsorption of Ethylene over Ethane. J. Am. Chem. Soc. 2014, 136, 8654−8660. (14) Hasell, T.; Miklitz, M.; Stephenson, A.; Little, M. A.; Chong, S. Y.; Clowes, R.; Chen, L.; Holden, D.; Tribello, G. A.; Jelfs, K. E.; Cooper, A. I. Porous Organic Cages for Sulfur Hexafluoride Separation. J. Am. Chem. Soc. 2016, 138, 1653−1659. (15) Fu, J.; Das, S.; Xing, G.; Ben, T.; Valtchev, V.; Qiu, S. Fabrication of COF-MOF Composite Membranes and Their Highly Selective Separation of H2/CO2. J. Am. Chem. Soc. 2016, 138, 7673− 7680. (16) Qiao, Z.-A.; Chai, S.-H.; Nelson, K.; Bi, Z.; Chen, J.; Mahurin, S. M.; Zhu, X.; Dai, S. Polymeric Molecular Sieve Membranes via in situ Cross-linking of Non-porous Polymer Membrane Templates. Nat. Commun. 2014, 5, 3705. (17) Song, Q.; Jiang, S.; Hasell, T.; Liu, M.; Sun, S.; Cheetham, A. K.; Sivaniah, E.; Cooper, A. I. Porous Organic Cage Thin Films and Molecular-Sieving Membranes. Adv. Mater. 2016, 28, 2629−2637. (18) Ding, S.-Y.; Gao, J.; Wang, Q.; Zhang, Y.; Song, W.-G.; Su, C.Y.; Wang, W. Construction of Covalent Organic Framework for Catalysis: Pd/COF-LZU1 in Suzuki−Miyaura Coupling Reaction. J. Am. Chem. Soc. 2011, 133, 19816−19822. (19) Fang, Q.; Gu, S.; Zheng, J.; Zhuang, Z.; Qiu, S.; Yan, Y. 3D Microporous Base-Functionalized Covalent Organic Frameworks for Size-Selective Catalysis. Angew. Chem., Int. Ed. 2014, 53, 2878−2882. (20) Xu, H.; Gao, J.; Jiang, D. Stable, Crystalline, Porous, Covalent Organic Frameworks as a Platform for Chiral Organocatalysts. Nat. Chem. 2015, 7, 905−912. (21) Kamiya, K.; Kamai, R.; Hashimoto, K.; Nakanishi, S. Platinum Modified Covalent Triazine Frameworks Hybridized with Carbon Nanoparticles as Methanol-tolerant Oxygen Reduction Electrocatalysts. Nat. Commun. 2014, 5, 5040. (22) Iwase, K.; Yoshioka, T.; Nakanishi, S.; Hashimoto, K.; Kamiya, K. Copper-Modified Covalent Triazine Frameworks as Non-NobleMetal Electrocatalysts for Oxygen Reduction. Angew. Chem., Int. Ed. 2015, 54, 11068−11072. (23) Thomas, P.; Pei, C.; Roy, B.; Ghosh, S.; Das, S.; Banerjee, A.; Ben, T.; Qiu, S.; Roy, S. Site Specific Supramolecular Heterogeneous Catalysis by Optically Patterned Soft Oxometalate−Porous Organic Framework (SOM−POF) Hybrid on a Chip. J. Mater. Chem. A 2015, 3, 1431−1441. (24) Kou, Y.; Xu, Y.; Guo, Z.; Jiang, D. Supercapacitive Energy Storage and Electric Power Supply Using an Aza-Fused π-Conjugated Microporous Framework. Angew. Chem., Int. Ed. 2011, 50, 8753− 8757. (25) Slater, A. G.; Reiss, P. S.; Pulido, A.; Little, M. A.; Holden, D. L.; Chen, L.; Chong, S. Y.; Alston, B. M.; Clowes, R.; Haranczyk, M.; Briggs, M. E.; Hasell, T.; Day, G. M.; Cooper, A. I. ComputationallyGuided Synthetic Control over Pore Size in Isostructural Porous Organic Cages. ACS Cent. Sci. 2017, 3, 734−742. (26) Xu, F.; Xu, H.; Chen, X.; Wu, D.; Wu, Y.; Liu, H.; Gu, C.; Fu, R.; Jiang, D. Radical Covalent Organic Frameworks: a General Strategy to Immobilize Open-Accessible Polyradicals for HighPerformance Capacitive Energy Storage. Angew. Chem., Int. Ed. 2015, 54, 6814−6818.

postsynthetic functionalization, the hybrid skeleton with heteroatoms, nanoparticles, ionic groups, or chiral fragments will render multivariate behaviors in catalysis, energy conversions, and removal of contaminants. In addition to their widely investigated applications, including molecular storage, gas separation, and catalysis, PAFs with tailorable compositions, structure, and pore environments can serve as advanced platforms for other farreaching utilizations not encountered in MOFs/COFs, such as removal of contaminants (especially organic pollutants) and extraction of precious metals from an aquatic environment and catalysis under extreme (strong acid/alkali/oxidant) conditions. Moreover, the excellent stability and compatibility of PAFs lead to a great ease of operation and flexibility for largescale coatings, films, and membranes in an antibacterial device, gas separation, nuclear material capture, and nuclear waste remediation applications. Further, efforts should be directed toward the scalable preparation of PAFs using mild and lowcost methods for industrial mass production.



AUTHOR INFORMATION

Corresponding Author

*E-mail: [email protected]. ORCID

Guangshan Zhu: 0000-0002-5794-3822 Notes

The authors declare no competing financial interest.



ACKNOWLEDGMENTS We are grateful for financial support from the National Basic Research Program of China (973 Program, Grant nos. 2012CB821700 and 2014CB931800), the National Natural Science Foundation of China (NSFC Grant nos. 21401069, 21501024, 91622106, and 21604008), the Major International (Regional) Joint Research Project of NSFC (Grant no. 21120102034), and the Natural Science Foundation of Jilin Province of China (Grant no. 20180520144JH).



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(66) Yuan, D.; Lu, W.; Zhao, D.; Zhou, H. C. Highly Stable Porous Polymer Networks with Exceptionally High Gas-uptake Capacities. Adv. Mater. 2011, 23, 3723−3725. (67) Palma-Cando, A.; Brunklaus, G.; Scherf, U. Thiophene-Based Microporous Polymer Networks via Chemical or Electrochemical Oxidative Coupling. Macromolecules 2015, 48, 6816−6824. (68) Katsoulidis, A. P.; Kanatzidis, M. G. Phloroglucinol Based Microporous Polymeric Organic Frameworks with − OH Functional Groups and High CO2 Capture Capacity. Chem. Mater. 2011, 23, 1818−1824. (69) Rabbani, M. G.; Reich, T. E.; Kassab, R. M.; Jackson, K. T.; ElKaderi, H. M. High CO2 Uptake and Selectivity by Triptycenederived Benzimidazole-linked Polymers. Chem. Commun. 2012, 48, 1141−1143. (70) Rose, M.; Bohlmann, W.; Sabo, M.; Kaskel, S. Element−organic Frameworks with High Permanent Porosity. Chem. Commun. 2008, 2462−2464. (71) Mohanty, P.; Kull, L. D.; Landskron, K. Porous Covalent Electron-Rich Organonitridic Frameworks as Highly Selective Sorbents for Methane and Carbon Dioxide. Nat. Commun. 2011, 2, 401. (72) Thirion, D.; Kwon, Y.; Rozyyev, V.; Byun, J.; Yavuz, C. T. Synthesis and Easy Functionalization of Highly Porous Networks through Exchangeable Fluorines for Target Specific Applications. Chem. Mater. 2016, 28, 5592−5595. (73) Dogan, N. A.; Hong, Y.; Ö zdemir, E.; Yavuz, C. T. Nanoporous Polymer Microspheres with Nitrile and Amidoxime Functionalities for Gas Capture and Precious Metal Recovery from E-Waste. ACS Sustainable Chem. Eng. 2019, 7, 123−128. (74) Ullah, R.; Patel, H.; Aparicio, S.; Yavuz, C. T.; Atilhan, M. A Combined Experimental and Theoretical Study on Gas Adsorption Performance of Amine and Amide Porous Polymers. Microporous Mesoporous Mater. 2019, 279, 61−72. (75) Aparicio, S.; Yavuz, C. T.; Atilhan, M. Structural Elucidation of Covalent Organic Polymers (COP) and Their Linker Effect on Gas Adsorption Performance via Density Functional Theory Approach. ChemistrySelect 2018, 3, 8294−8305. (76) Pei, C.; Ben, T.; Qiu, S. Great Prospects for PAF-1 and its Derivatives. Mater. Horiz. 2015, 2, 11−21. (77) Díaz, U.; Corma, A. Ordered Covalent Organic Frameworks, COFs and PAFs. From Preparation to Application. Coord. Chem. Rev. 2016, 311, 85−124. (78) Zou, X.; Zhu, G. Microporous Organic Materials for Membrane-Based Gas Separation. Adv. Mater. 2018, 30, 1700750. (79) Li, X.; Zhang, C.; Cai, S.; Lei, X.; Altoe, V.; Hong, F.; Urban, J. J.; Ciston, J.; Chan, E. M.; Liu, Y. Facile Transformation of Imine Covalent Organic Frameworks into Ultrastable Crystalline Porous Aromatic Frameworks. Nat. Commun. 2018, 9, 2998. (80) Cossi, M.; Gatti, G.; Canti, L.; Tei, L.; Errahali, M.; Marchese, L. Theoretical Prediction of High Pressure Methane Adsorption in Porous Aromatic Frameworks (PAFs). Langmuir 2012, 28, 14405− 14414. (81) Pei, C.; Ben, T.; Xu, S.; Qiu, S. Ultrahigh Iodine Adsorption in Porous Organic Frameworks. J. Mater. Chem. A 2014, 2, 7179−7187. (82) Ben, T.; Qiu, S. Porous Aromatic Frameworks: Synthesis, Structure and Functions. CrystEngComm 2013, 15, 17−26. (83) Ren, H.; Ben, T.; Sun, F.; Guo, M.; Jing, X.; Ma, H.; Cai, K.; Qiu, S.; Zhu, G. Synthesis of a Porous Aromatic Framework for Adsorbing Organic Pollutants Application. J. Mater. Chem. 2011, 21, 10348−10353. (84) Yuan, Y.; Ren, H.; Sun, F.; Jing, X.; Cai, K.; Zhao, X.; Wang, Y.; Wei, Y.; Zhu, G. Targeted Synthesis of a 3D Crystalline Porous Aromatic Framework with Luminescence Quenching Ability for Hazardous and Explosive Molecules. J. Phys. Chem. C 2012, 116, 26431−26435. (85) Yuan, Y.; Ren, H.; Sun, F.; Jing, X.; Cai, K.; Zhao, X.; Wang, Y.; Wei, Y.; Zhu, G. Sensitive Detection of Hazardous Explosives via Highly Fluorescent Crystalline Porous Aromatic Frameworks. J. Mater. Chem. 2012, 22, 24558−24562.

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a High Adsorption Capacity for Organic Molecules. J. Mater. Chem. 2011, 21, 13498−13502. (104) Van Humbeck, J. F.; McDonald, T. M.; Jing, X.; Wiers, B. M.; Zhu, G.; Long, J. R. Ammonia Capture in Porous Organic Polymers Densely Functionalized with Brønsted Acid Groups. J. Am. Chem. Soc. 2014, 136, 2432−2440. (105) Demir, S.; Brune, N. K.; Van Humbeck, J. F.; Mason, J. A.; Plakhova, T. V.; Wang, S.; Tian, G.; Minasian, S. G.; Tyliszczak, T.; Yaita, T.; Kobayashi, T.; Kalmykov, S. N.; Shiwaku, H.; Shuh, D. K.; Long, J. R. Extraction of Lanthanide and Actinide Ions from Aqueous Mixtures Using a Carboxylic Acid-Functionalized Porous Aromatic Framework. ACS Cent. Sci. 2016, 2, 253−265. (106) Sun, J.; Jing, L.; Tian, Y.; Sun, F.; Chen, P.; Zhu, G. TaskSpecific Design of a Hierarchical Porous Aromatic Framework as an Ultrastable Platform for Large-sized Catalytic Active Site Binding. Chem. Commun. 2018, 54, 1603−1606. (107) Jing, L.; Sun, J.; Sun, F.; Chen, P.; Zhu, G. Porous Aromatic Framework with Mesopores as a Platform for a Super-Efficient Heterogeneous Pd-based Organometallic Catalysis. Chem. Sci. 2018, 9, 3523−3530. (108) Karakhanov, E.; Kardasheva, Y.; Kulikov, L.; Maximov, A.; Zolotukhina, A.; Vinnikova, M.; Ivanov, A. Sulfide Catalysts Supported on Porous Aromatic Frameworks for Naphthalene Hydroprocessing. Catalysts 2016, 6, 122−127. (109) Verde-Sesto, E.; Merino, E.; Rangel-Rangel, E.; Corma, A.; Iglesias, M.; Sánchez, F. Postfunctionalized Porous Polymeric Aromatic Frameworks with an Organocatalyst and a Transition Metal Catalyst for Tandem Condensation−Hydrogenation Reactions. ACS Sustainable Chem. Eng. 2016, 4, 1078−1084.

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DOI: 10.1021/acscentsci.9b00047 ACS Cent. Sci. XXXX, XXX, XXX−XXX