Abstract
Amorphous porous organic polymers (aPOPs) are a type of highly crosslinked polymers. These polymers are generally constructed from rigid organic building blocks, which have become an important subclass of POPs with diverse applications. In the early stage of development, a wide range of carbon-based building blocks and network forming chemistry afforded a large library of aPOPs with rich structures and properties. Recently, implanting main group elements with diverse geometric structures and electronic configurations into aPOPs has proven to be a useful tool to fine-tune the structures and properties of these polymers. Herein, we outline the recent advances in the field of main group (MG)-aPOPs where main-group elements either played unique roles in tuning the structures and properties of MG-aPOPs, or offered new strategies in the synthesis of MG-aPOPs. Furthermore, this Review discusses various challenges remaining in the field from the perspectives of synthetic strategies and characterization techniques, and presents some specific studies that may potentially address the challenges.
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Introduction
Porous organic polymers (POPs) have gained significant attention in the diverse applications, such as gas storage/separation, heterogeneous catalysis, energy storage, sensing, and other optoelectronic devices1,2,3,4,5. Different from zeolites and metal-organic frameworks containing metal ions, POPs are a subclass of porous materials containing only organic building blocks. Generally, POPs can be grouped into crystalline (c)POPs, such as covalent organic frameworks (COFs)4, covalent triazine frameworks (CTFs)6,7, and amorphous (a)POPs, such as conjugated microporous polymers (CMPs)2,8,9, porous aromatic frameworks (PAFs)3,10,11,12, hypercrosslinked polymers (HCPs)13,14,15, and polymers of intrinsic microporosity (PIMs)16,17,18.
As the first report of cPOPs, Yaghi and coworkers reported the synthesis and porous structures of COFs in 200519, in which the highly ordered and tunable porous structures endowed the cPOPs with unprecedented opportunities in wide applications4. As the twin sister of cPOPs, research of aPOPs has witnessed a long historical development. In late 1960s, Davankov and coworkers reported the first example of HCPs synthesized by the Friedel-Crafts catalyzed self-condensation of p-dichloroxylene. The HCPs exhibited the apparent Brunauer-Emmett-Teller (BET) surface areas up to 1106 m2 g-1 20. Using the similar synthetic method, Tan and coworkers recently reported a new series of HCPs with layered microporous structures, which exhibited the BET surface area as high as 3002 m2 g-1 21. Being a unique member of aPOPs, the first kind of PIMs was reported by McKeown and Budd in 200416. The porous character of these polymers is originated from the high rigid structures and the contorted shapes in the linear polymeric backbone, in which the polymers cannot pack efficiently. The solution processable character makes PIMs highly distinctive from other aPOPs.
Later on, the rich and well-developed synthetic protocols further accelerated the development of aPOPs. For example, transition-metal catalyzed carbon–carbon (C–C) cross-coupling reactions, such as Sonagashara-Hagishara8,9, Suzuki-Miyaura22,23,24, Yamamoto 10,25,26,27, Heck28,29, etc. became the widely used synthetic protocols to construct aPOPs. Leveraging on the well-documented C–C coupling reactions, a mix and polymerize strategy has become very popular and appealing in the field of aPOPs. In 2007, Cooper and coworkers reported the first example of CMPs with various π-conjugated structures8. Although some optimizations were required, Sonagashara-Hagishara coupling reaction generally afforded the CMPs with high surface areas and microporous structures8,30. Later, the tunable porous structures and optoelectronic properties were realized by carefully choosing monomers with different chemical and electronic nature8,30,31. In 2009, using Yamamoto cross-coupling reactions, Ben and coworkers reported the first example of PAF containing tetrahedral tetrakisphenyl methane (TPM) building block, The PAF exhibited an extremely high BET surface area of 5640 m2 g-110. The high surface-area character is highly beneficial for the applications in gas storage and gas separation.
Along with maturing of synthetic protocols, research of exploring diverse functions has been blooming in the field of aPOPs1,2,3,5,9,15,32. The structures and properties of aPOPs are highly dictated by the chemical structures and porous structures. Gas storage (H2, CH4, and CO2) and separation have been the largest area of study for designing new aPOPs with the high surface area33,34,35. Tunability of the porous diameters and compositions (electron rich or electron poor) offered aPOPs with the improved adsorption capacity and selectivity12,26,36. Recently, extensive usages of organic π-conjugated building blocks in the rigid polymeric structures further extended aPOPs in the light-emitting related applications27,37. The light-emitting properties were highly tunable by modulating the chemical structures of the building blocks. aPOPs with light-emitting characters were further applied for the detection of various chemicals by monitoring the changes of light-absorption and photoluminescence38,39,40,41. The large open sites also allowed the strong interactions of aPOPs with the various chemicals, thus enhancing the signal sensitivities for the detections. Furthermore, the high chemical and topological stability provided a good platform for aPOPs in the application of heterogeneous catalysis5,42,43,44. Reactants were able to easily access the open porous structures and reach to the catalytic sites on the backbones. Besides, aPOPs with various photo-active building blocks became the promising candidates as the photoredox catalysts for chemical conversions45,46 and water splitting47,48,49. In addition to the applications mentioned above, aPOPs also found interests in energy storage50,51, biosensing52,53, drug delivery54, antibacterial55,56, and phototherapy57.
As a special subgroup of aPOPs, main group element (such as boron, nitrogen, phosphorus, silicon, sulfur, etc.) containing (MG)-aPOPs slowly draw attention in recent years38,39,40,58,59,60,61. The rich electronic configurations and geometries of the main group elements provided a new dimension to fine-tune the structures, properties and functions of aPOPs. For example, incorporating trivalent B-center with an empty p-orbital endowed aPOPs with excellent toxic anions and chemicals (fluoride, cyanide anoins, amines, etc.) sensing properties38,39. In presence of Lewis base N-center, aPOPs exhibited the enhanced Lewis basicidity where the polymers exhibited better Lewis acid gas (CO2, SO2, etc.) takeup62,63,64. The strong interactions between S-center and lithium ion allowed aPOPs to show the promising redox characteristics in lithium-ion batteries51. Thus, these unusual characteristics and applications that are not easily accessible to the traditional pure-carbon based aPOPs can be realized in MG-aPOPs.
In this review, we present the recent developments of MG-aPOPs. The review does not aim to comprehensively cover the whole field of MG-aPOPs, but rather a personal selection of recent papers where the main-group elements either play important roles in tuning the structures and properties, and/or offering new strategies in the synthesis of the MG-aPOPs. This review organizes MG-aPOPs into Group-13 aPOPs, Group-14 aPOPs, Group-15 aPOPs, and Group-16 aPOPs, in which the specific main-group elements are involved. With the disussions of recent developments in MG-aPOPs, the review seeks to clarify the challenges remaining in the field, and propose alternative approaches potentially to address the challenges.
Group 13 containing amorphous POPs
Compared with other elements in group 13, boron element is one of the most extensively studied in the field of MG-aPOPs. Having an empty p-orbital, trivalent B-center exhibits strong Lewis acid character and electron-accepting character. Therefore, doping trivalent B-center into small molecules and macromolecules endowed the systems with excellent toxic chemicals sensing properties and electron accepting/transporting properties51,65,66. Leveraging on extensive research on B-based small molecules and macromolecules in the literature, a number of new B-aPOPs were rationally designed and constructed in recent studies.
Liu and coworkers reported the first example of B-aPOPs (B-P1 and B-P2) containing triaryl B-building blocks (Fig. 1a)38. Similar to previous studies65,66,67, the triaryl B-building block contained multiple methyl groups to protect the B-center in Sonagashira-Hagihara polymerization. Solid-state 11B nuclear magnetic resonance spectroscopy (NMR) experiments confirmed the presence of trivalent B-center in the B-aPOPs. B-P1 and B-P2 showed the BET surface areas of 815 m2 g−1 and 911 m2 g−1, respectively. Later, the same group also reported B-P3 that was synthesized by Suzuki-Miyaura coupling reaction38. These B-aPOPs generally displayed strong photoluminescence in both the dispersed solution and the solid state. Due to the presence of donor (N-containing moiety)—acceptor (B-containing moiety) type structure, B-P2 and B-P3 exhibited the strong solvent dependent emission via intermolecular charge transfer (ICT) state (Fig. 1b). Their studies further uncovered that B-P3 showed a highly selective photoluminescence responsive property towards fluoride anion (Fig. 1c). Almost at the same time, Feng and coworkers reported similar B-aPOPs (B-P2’ and B-P4 in Fig. 1a). B-P2’ and B-P4 exhibit very similar porosity characteristics and photophysical properties to these of B-P1,2,340.
In addition to trivalent B-building blocks, tetravalent B-building blocks were also recently explored in the synthesis of B-aPOPs. Compare with trivalent B-center, tetravalent B-center generally exhibits better stabilities towards water and oxygen. In 2013, Thomas and coworkers reported a new type of B-aPOP containing tetrahedral anionic B-center (TPFB in Fig. 2a)68. A strong signal at −5.8 ppm observed in solid state 11B NMR spectroscopy experiments suggested that B-P5 maintains a uniform tetravalent B-center in the polymeric backbones (Fig. 2b). Having TPFB unit structurally related to TPM, B-P5 exhibited a BET surface area of 890 m2 g−1. The microporous structure facilitated a facile ion-exchange between lithium ion and sodium ion in B-P5, which resembles to the silicon-aluminum exchange reaction in inorganic zeolites69. Further ion exchange with manganese bipyridine complexes allowed the converted Mn@B-P5 to be a promising catalyst for the oxidation of alkenes (Fig. 2a).
Later, leveraging on strong binding between trivalent B-center and fluoride anion, Zhuang and coworkers used a post-polymerization chemical modification strategy to access tetravalent B-center (Fig. 3). B-aPOPs (B-P6, B-P7, and B-P8) reacted with tetrabutylammonium fluoride as fluoride anion source70. Their studies revealed that most of the B-centers were successfully converted to the tetravalent B-centers by binding with fluoride anion. Presence of unreacted trivalent B-centers was correlated to the porous structure character in the different B-aPOPs. They further applied ion-exchange reactions to the B-aPOPs by reacting with various metal salts (cobalt acetate, nickel acetate, and iron nitrate). As a proof of concept, Co@BF-POP was used for the homocoupling reactions of aryl Grignard reagents where a distinct size selectivity was observed in the various porous structures. The study nicely demonstrated that the boron chemistry can be used as a ship in bottle technique in aPOPs.
So far, transition metal catalyzed C–C coupling reactions are the main synthetic protocol to access aPOPs in the literature. Recently, Ren and coworkers explored boron-tin (B-Sn) exchange reaction as a new synthetic protocol to build B-aPOPs (Fig. 4a, B-P9a,b, B-P10a,b, B-P11a,b and B-P12a,b)39. The new synthetic protocol allows the construction of the first examples of B-aPOPs without sterically protected trivalent B-centers. The studies revealed that the B-aPOPs maintained well-define chemical structures and microporous structures. Particularly, solid state 11B NMR spectroscopy experiments uncovered the highly uniform trivalent B-centers in the B-aPOPs. They found that, compared with B-aPOPs synthesized by trimethyltin oligothiophenes, B-aPOPs synthesized by tributyltin oligothiophenes show better porous structures, such as high BET surface areas and high ratios of microporous structures. It was rationalized that the better solubility and low reactivity of tributyltin oligothiophenes were beneficial for constructing B-aPOPs with the better porosity in the B-Sn exchange reaction.
Furthermore, B-aPOPs with the unprotected B-center showed strong p-π* electronic coupling compared with the steric protected B-center, thus increasing Lewis acidity. With the enhanced Lewis acidity, these B-aPOPs exhibited excellent amine and pyridine sensing and absorptivity (Fig. 4b, c). The B-aPOPs showed reversible pyridine absorption properties. The pyridine absorptivity of B-P9b reached as high as 570 mg g−1. Solid state 11B NMR experiments of B-P9b futher confirmed the cooridination of the B-centers with pyridine molecules (Fig. 4d).
The high Lewis acidity of thienylborane towards various pyridine moieties (such as 4-bromopyridine, 4,4’-bipyridine, and 1,3,5-tri(pyridinyl)benzene) further inspired Ren and coworkers to design new thienylboran-pyridine (TB-py) Lewis pairs (Fig. 5a)71. BN-crosslinked polythiophene networks with the diverse topological TB-py Lewis pairs were constructed by using typical Stille type coupling reaction (Fig. 5a, b). The nonplanar TB-py Lewis pairs endowed the polymers with strong intramolecular charge separation characteristics (Fig. 5c, d). The theoretical studies of model molecules revealed that negligible molecular orbital coupling between the HOMO (thiophene moieties) and the LUMO (pyridine moieties) was responsible for the strong intramolecular charge separation characteristics (Fig. 5d). Furthermore, B-P13 is highly stable towards the high temperature and water, which showed promising photocatalytic hydrogen production properties in the preliminary studies (Fig. 5e). It needs to be noted that the BN-crosslinked polythiophene network is not the first examples of B-aPOPs that were applied in the application of photocatalytic hydrogen production. For example, Pan’s group reported a new example of B-aPOPs with trivalent B-center showing competitive hydrogen evolution rate (HER) as high as 1603 μmol h−1 g−1 under visible light72.
In line with exploring new synthetic protocols, Jiang and coworkers successfully introduced the electro-polymerization protocol to construct B-aPOPs on the surface of various electrodes (Fig. 6a)73. Based on the well-documented electro-polymerization of carbazole units in the literature, B-aPOP (B-P16) with carbazole moiety was synthesized by harnessing the similar in-situ electro-polymerization. According to high-resolution transmission electron microscopy (HR-TEM) and Kr adsorption isotherm measurements, B-P16 exhibited the porous structure with a BET surface area of 1074 m2 g−1 and a pore size of 1.5 nm. Importantly, the surface polymerized B-P16 was able to effectively modify the work function of the various electrodes, such as ITO, Au, ZnO, and PEDOT:PSS. Leveraging on the Lewis acidity of the trivalent B-center, binding fluoride anion to B-P16 was further explored as a new strategy to elevate the work functions of the modified electrodes (Fig. 6b, c). Organic solar cells and light-emitting diodes using the modified ITO electrodes showed the excellent performances. Particularly, the organic solar cells based on oxidized F@B-P16 modified ITO exhibited a power conversion efficiency as high as 7.93% (Fig. 6d–f), which was the highest reported for the solar cells with porous polymers as interlayers. Overall, the research opened a new door for B-aPOPs as new type materials to fine-tune the work function of the electrodes in various organic optoelectronic devices.
The developments of B-aPOPs clearly showed two stages. In the first stage, the B-aPOPs extensively borrowed the material design principles from the previous B-systems, including of using the protected B-building blocks, exploring the sensing properties of the B-aPOPs towards fluoride and cyanide anions. Although some functionalized B-aPOPs exhibited the promising catalytic properties in the oxidation of alkenes and homocoupling reactions of aryl Grignard reagents, the Lewis acidity character of the B-aPOPs were rarely explored in new Lewis acid catalyzed synthesis. The second stage witnessed the advances of B-aPOPs in the perspective of both new synthetic protocols and new applications. The B-Sn exchange reaction promised a new research direction that fully harness the Lewis acidity of the B-aPOPs without the large protecting group. More applications of the B-aPOPs in the Lewis acid catalyzed synthesis may become possible. With maturing of the structure design and synthesis, B-aPOPs with new chemical structures were further tested in the various energy related applications, such as photocatalytic hydrogen production and electrode materials in organic electronic devices.
Group 14 based amorphous POPs
In group 14, the light carbon element played very important roles in the early development of aPOPs1,2,3. Not only the well-developed C–C coupling reactions provided the rich synthetic protocols, but also the introduction of tetrahedral C-center as the topological building block afforded C-aPOPs with the stable porous structures and high surface areas. In 2009, Zhu and coworkers reported the first example of C-aPOPs (C-P1 in Fig. 7a, b) containing tetrahedral TPM10. C-P1 was synthesized by the Nickel-catalyzed Yamamoto-type Ullmann coupling polymerization, which opened up a new subdiscipline of aPOPs, namely PAFs. Due to the rigid 3D structure of TPM, C-P1 exhibits a BET surface area as high as 5600 m2 g−1. The excellent porosity and stability made C-P1 an promising candidate for gas storage applications, such as CO2 capture and H2 storage. C-P1 absorbed 1300 mg⋅g-1 CO2 at 40 bar at 298 K. The H2 uptake capacity of C-P1 (10.7 wt%, at 48 bar, 77 K) is comparable to the best performed MOFs and COPs at the time.
Following the research of C-P1, Zhou and coworkers reported several new examples of group-14 aPOPs (Si-P1 and Ge-P1 in Fig. 7a) with tetrahedral Si-/Ge-building blocks60. As expected, Si-P1 and Ge-P1 exhibited high BET surface areas of 6461 m2 g−1 and 4267 m2 g−1, respectively. Particularly, Si-P1 showed the highest BET surface area among all porous materials reported at the time. Si-P1 also exhibited high H2 (91 mg g−1, 55 bar, 77 K, Fig. 7d), CH4 (389 mg g−1, 55 bar, 295 K, Fig. 7e), and CO2 (1710 mg g−1, 50 bar, 295 K, Fig. 7f) uptake capacity, which is very a promising candidate for the gas storage applications. Later, aPOPs with various new topological C-/Si-/Ge-building blocks (Fig. 7c) were designed and synthesized, which also showed excellent porosity characteristics, such as high surface area and stable porous structure3,33,74,75,76,77. The results advocated the important role of the rigid 3D building blocks for designing aPOPs with excellent porosity.
Recently, Bunz and coworkers reported a new type of Sn-aPOPs (Fig. 8, Sn-P1) via Pd/Cu catalyzed homocoupling of tetrakis(4-ethynylphenyl)stannane78. Sn-P1 exhibits a BET surface area of 747 m2 g−1. As another important progress in aPOPs, they were able to utilize liable Sn–C bond to probe the chemical compositions of Sn-P1. In the model digestion reaction (Fig. 8b), Sn-M1 was quantitatively converted to diyne derivative in the presence of chloroacetic acid. After applying a similar digestion reaction to Sn-P1’ synthesized by lithiation method (Fig. 8a), quantitative diphenylbutadiyne also was obtained. On the contrary, the digestion reaction of Sn-P1 only gave a small amount of diphenylbutadiyne (Fig. 8a). Most of the digestion products were the enyne-based dimers, trimers, and tetramers of phenyl-acetylene. The results suggested that the heterogeneous C–C cross-coupling polymerization did not always result in the uniform structures as we expected. This study provided a new strategy to elucidate the chemical structures of aPOPs when they contain liable chemical bonds, such as Sn–C and Si–C bonds. Using similar Sn–C digestion method, Bunz’s group further investigated the chemical structures of similar Sn-aPOPs synthesized under different reaction conditions. The acid-mediated digestion method further helped them uncover useful chemical structure information of the Sn-aPOPs synthesized under different reaction conditions by changing catalysts, solvents, and bases78.
Later, the same group carried out the systematic studies on Group-14 aPOPs (Fig. 8c, C-P4, Si-P4, Ge-P2, and Sn-P2)79. These aPOPs exhibited a decreasing trend of BET surface areas with increasing atomic number of the central atom (C, Si, Ge, Sn). They hypothesized that the flexibility of the Group-14 building blocks has a strong impact on the BET surface areas, in which increasing atomic number and metallic character from C to Sn increased the flexibility. The observation that changing from C-center, over Si-center and Ge-center, to Sn-center showed the increasing deviation from the ideal tetrahedral angle is consistent with the hypothesis (Fig. 8d).
As shown in the section, the C-aPOPs played an irreplaceable role and position in the developments of aPOPs. The stable and rigid topological group-14 building blocks, particularly, C- and Si-building blocks, became the benchmark “legos” for constructing aPOPs with high surface areas. The high stability of the C- and Si-building blocks also allowed the rich chemical modifications of the polymeric backbones, thus optimized the selectivity of the aPOPs towards toxic chemicals, such as CO2 and ammonia80,81. Along with helping to maintain the excellent porosity, the group-14 building blocks further helped us to identify the chemical structures of aPOPs. The study of the digestion reaction of the tetrakis(4-ethynylphenyl)stannane network clearly suggested that the chemical structures aPOPs were not always uniform as we expected. Therefore, the chemical structures of new aPOPs should be carefully studied, which is beneficial for establishing the clear and reliable relationship between chemical structure, properties, and functions.
Group 15 Based Amorphous POPs
Similar to the above Group-14 derivatives, Group-15 element-based building blocks also exhibit nonplanar chemical structures. Incorporating Group-15 elements with lone pair electrons are expected to enhance the Lewis basicity of aPOPs. Early reports revealed that N-aPOPs (examples: N-P1-4, Fig. 9a) exhibited the promising Lewis acid gases (such as CO2, SO2, etc.) capture capability62,63,82. In a recent example, Han and coworkers applied oxidative coupling reaction to N-electron rich carbazole building block (Fig. 9b), which gave N-P5 with a BET surface area as high as 2220 m2 g−1 83. N-P5 exhibited excellent hydrogen (2.8 wt %, 1.0 bar and 77 K) and CO2 (21.2 wt %, 1.0 bar and 273 K) storage capacities, which were competitive with the best reported results for porous polymers at the time. Furthermore, N-P1 showed a good selectivity toward CO2 over N2 and CH4, which also made them very promising materials for the gas separation (Fig. 9c). Later, more related N-aPOPs were synthesized by using similar oxidative coupling polymerization, which showed promising photocatalysis performances in organic synthesis84,85. Band-gap engineerig of conjugated polymers is important for controlling the photophysical properties, redox properties, and energy conversions. Combining the electron-rich N-building block with electron-poor benzothiadiazole building block further resulted in new N-aPOPs with narrow band-gap (N-P6-8, Fig. 9d)86. Compared with N-P6, N-P7 and N-P8 synthesized by the Suzuki coupling showed stronger photoluminescence. After doping with C60 as the electron-acceptor, the photoluminescence of N-P7 was significantly quenched (Fig. 9e). The studies suggested efficient charge transfer character in the N-P7-C60 complex, which could open up a new strategy for constructing efficient light harvesting or energy conversion architectures.
In a recent study, Faul and coworkers found that Buchwald-Hartwig (BH) cross-coupling reaction can be an efficient synthetic protocol for synthesizing N-aPOPs (Fig. 10, N-P9)87. They found that the cross-coupling reaction conditions significantly influenced the porous structures of N-P9. With the presence of inorganic salts, such as sodium halides (NaF, NaCl, NaBr, and NaI), the BET surface areas of N-P9 increased to as high as 1152 m2 g−1 compared with that (58 m2 g−1) synthesized in the absence of salts. Along with the increased surface area, N-P9 synthesized in the presence of inorganic salts also exhibited a narrowed pore size distribution (PSD). The addition of the salts is believed to balance the Hansen solubility parameters (HSPs) between the polymers and the solvents, consequently results in the late-stage phase separation during the porous structure formation88. The improved porosity characteristics also enhanced the CO2 uptake capacity (from 0.70 mmol g−1 to 3.60 mmol g−1, 1.0 atm, 273 K, Fig. 10b).
In Group 15, rich phosphorus chemistry, such as oxidation, borylation, alkylation, metal coordination, etc., allowed to further enrich the chemical structures and properties of small molecules and macromolecules89,90. Using classical C–C cross-coupling polymerizations, diverse building blocks with various P-centers, such as P-lp (lp: lone pair of electrons), P-O, P-S, cationic P-R centers, P-metal centers were designed to synthesize P-aPOPs in the literature91,92,93. Zhang and coworkers reported the first example of P-aPOPs with a quaternary phosphonium center (Fig. 11a)91. Similar to TPM-type building blocks, the tetrahedral phosphonium cation building block was polymerized via the Yamamoto-type cross-coupling protocol, thus affording the target P-P1. Solid state 31P NMR spectra of P-P1 showed two signals at 23 ppm and −8.8 ppm. The former peak was assigned to the quaternary phosphonium center. While, the later high-field peak was attributed to the tertiary P-lp center, which was rationalized to be due to the P–C bond cleavage as the side reaction in the polymerization. The BET surface areas of P-P1 were highly tunable via the ionic exchange of counter anions. Decreasing the counter anion size from Br (650 m2 g−1) to Cl (750 m2 g−1) and F (980 m2 g−1) increased the BET surface areas of the P-aPOPs. After depositing Pd nano-particle via the ionic exchange reaction (Fig. 11b), Pd@P-P1 exhibited a good catalytic C–C cross-coupling performance in the reaction between aryl halides and phenylboronic acid. Furthermore, similar catalytic reaction was even applicable to phenyl fluoride derivative by using Pd@P-P1 as the catalyst. Later, the same group also synthesized P-P2 with P-lp center and P-P3 with P-O center by using similar Yamamoto-type reactions92. Both P-P2 and P-P3 showed high BET surface areas. Pd@P-P2 with deposited Pd nanoparticle showed good catalytic performance in the coupling reactions between aryl chlorides and p-tolylboronic acid.
Although a great number of Lewis basic and Lewis acidic porous polymers were reported in the literature, these porous polymers were rarely applied for catalytic applications. In 2017, Thomas and coworkers reported two new semi-immobilized frustrated Lewis pairs aPOPs (Fig. 11c, B@P-P4 and B@P-P5) and explore their potential catalytic applications94. B@P-P4 and B@P-P5 were prepared by mixing Lewis basic P-aPOPs (P-P4 and P-P5) and Lewis acidic tri(pentafluororophenyl)borane (B(C6F5)3) additive. Interestingly, solid state 31P NMR spectra of B@P-P4 and B@P-P5 show down-field shifted signal compared to these of P-P4 and P-P5. Generally, the formations of frustrated Lewis base-acid adducts are not observed at ambient temperature in solution. It was rationalized that the favorable interactions gained from the weak association of the polymer and B(C6F5)3 dominated by the entropic contribution of the dissociation process. Importantly, B@P-P4 and B@P-P5 are able to cleave dihydrogen heterolytically at ambient temperature and low hydrogen pressure (Fig. 11c).
Very recently, Ren’s group reported a new series of P-aPOPs containing Phospha-alkyene structure (Fig. 12a, P-P6, P-P7, and P-P8)58. Unlike previous aPOPs synthesized by C–C cross-coupling reactions, P-P5, P-P6, and P-P7 were synthesized by CuI catalyzed P–C cross-coupling reaction between PCl3 and various aryl alkynes. P-aPOPs exhibited high surface areas (ca. 1000 m2 g−1) and ultra-microporous structure with PSD as small as 6.7 Å (Fig. 12b, c). More importantly, the study revealed that the choice of organic bases has the strong impact on the degree of crosslinking P-centers, thus resulting in the different porosities. CO2 uptake of P-P6 with most uniform P-crosslinking centers and highest microporous surface are is as high as 4.23 mmol g−1 (1 bar, 273 K, Fig. 12d), which is highest value among the polymers. The study provides important information on the relationship between the crosslinking environments, porous structures, and CO2 uptake capability, in which the higher the percentage of crosslinked P-centers, the higher the micro-surface areas of P-aPOPs, and higher the CO2 uptake capability.
Following the CuI catalyzed formation of P-aPOPs, Ren’s group recently extended the classical Stille C–C coupling reaction to the P–C bond formation where three P–C bonds are able to form at a single P-center (Fig. 13a)95. Upon the oxidation of P–C bond, electrophilic character of catalytic Pd(II) center was suppressed by the electron-rich P-center, which is distinct from the classical Still coupling reaction. The efficient P–C bond formation allowed us to synthesize a new series of P-aPOP (P-P9, P-P10, and P-P11, Fig. 13b). Various P-chemistry was also applicable to the systems that gave the polymers with phosphonium center (P-P9Me, P-P10Me, and P-P11Me, Fig. 13b), and the polymer with P(O)-center (P-P10O, Fig. 13b). Although not showing microporours structures, the P-aPOPs exhibited the promising visual-light photocatalytic hydrogen production properties (Fig. 13b). Compared with those of P-P10 and P-P10O (Fig. 13c), the lower valence band energy of P-P10Me is benificial for hole transport from sacrificial electron donor to the polymer. More importantly, adjusting the chemistry P-center of the polymers offered a new strategy to fine-tune the photocatalytic H2 production properties (Fig. 13d). P-P10Me with an ionic P(Me)-center exhibit a H2 evolution rate up to 2050 mmol h−1 g−1, which is much higher than those of P-P10 with P(O)-center (900 mmol h−1 g−1) and P-P10 with P(III)-center (155 mmol h−1 g−1).
The previous studies clearly showed that the lone pair of electrons and non-planar structures of group-15 elements furnished new functions and opportunities to aPOPs. For example, introducing N-element into B-aPOPs endowed the excellent responsive photoluminescence towards fluoride and cyanide anions96. The presence of N- and P-elements with strong Lewis base characters in the backbones improved the CO2 capture and H2 splitting of the GM-POPs58,97. Furthermore, the group-15 aPOPs also found new platform in the applications of photocatalysis85. The study that the tunable visible light photocatalytic H2 production by the rich P-chemistry of P-P10 series clearly promise more opportunities for the photocatalytic applications95. The very recent studies of the group-15 aPOPs also shed light on how the reaction conditions (such as solvents, temperature, catalysts, bases, etc.) affects the crosslinking centers, porous structures, and properties of the aPOPs58,87.
Group 16 element based amorphous POPs
Lately, group-16 element chemistry also brought some intriguing aspects into the filed of aPOPs in the perspectives of exploring new synthetic protocols and functions. In 2018, Swager and coworkers reported the use of nucleophilic aromatic substitution reaction (SNAr) to construct S-aPOP61. They found that the dynamic and self-correcting nature of the SNAr between ortho-aryldithiols and ortho-aryldifluorides is responsible for the regioselectivity of thermodynamic products (Fig. 14a, b). Applying the SNAr in polycondensation, they were able to obtain new S-aPOPs (Fig. 14c) with BET surface areas of 189 m2 g−1 for S-P1 and 813 m2 g−1 for S-P2 (Fig. 14d), respectively. Recent studies also showed that similar dynamic SNAr polycondensations between phenol derivatives and activated aryl halides gave O-based COFs with highly ordered structures by the careful optimization of polymerization conditions98. The detailed discussion of these studies is out of the scope of this review.
In addition to showing the intriguing synthetic reactivities, the introduction of S-center was also found to endow S-aPOPs with photocatalytic H2 production properties. In 2016, Cooper and coworkers found that converting S-center to sulfone (SO2) center in linear conjugated polymers (Figs. 15a, S-P3,4) significantly enhanced the photo-hydrogen evolution performance, in which HER up to 5.8 mmol h−1 g−1 was obtained for the SO2-containing conjugated polymer99. Encouraged by the promising photocatalytic H2 production properties, Cooper and coworkers further synthesized several series of S-aPOPs (Examples shown in Figs. 15, S-P5,6) where SO2-aPOPs consistently exhibited better photocatalytic hydrogen production performance compared with their S-aPOP counterparts100. The ultrafast spectroscopy and theoretical studies suggested the several important roles of the sulfone group played in the photocatalytic properties:101,102 (a) The presence of sulfone groups improved the hydrophilic character of polymeric backbones, in which the charge and proton transfer could be accelerated at the interface between the polymeric backbones and water/triethylamine molecules. (b) The polymer containing SO2-group exhibits the improved charge transfer and triethylamine deprotonation, presumably due to the high polarity of sulfone group. (c) The yields of polaron generated by photoexcitation increase with the number of SO2-groups in the polymeric backbones. Recently, Jiang and coworkers reported new series of S-aPOPs (Figs. 15, S–P7–12)103,104,105. By judiciously choosing organic π-conjugated building blocks, they were able to synthesize SO2-aPOP (S-P12) with HER as high as 115 mmol h−1 g-1 under visible light (λ > 420 nm)104. Jiang’s group further demonstrated that, under natural sunlight, the polymer-film based S-P12 were also highly active in the outdoor photocatalytic H2 production (Fig. 15b, c, d). The total 1224 mL of H2 and an everage HER of 312 mmol h−1 g−1 was achieved under the irradiation of natural sunlight for 7 h (Fig. 15b–d)104.
As shown in the section, the group-16 elements were not generally used for constructing the aPOPs with good porous stuctures (such as high surface areas and uniform pore sizes) compared with the other MG-aPOPs. Altough the dynamic chemistry between ortho-aryldithiols and ortho-aryldifluorides brought some interesting porosity for aPOPs, the universality of the chemistry limited the developments of new MG-aPOPs with the excellent porous stuctures. At contrary, the group-16 aPOPs were extensively investigated in the application of photocatalytic H2 production, which hold promise for advancing the photocatalytic applications.
Exploring new synthetic protocols for MG-Amorphous POPs
Rich organic synthetic methods provided a large pool of synthetic protocols for constructing aPOPs with various chemical structures, porous structures, and properties. The “mix and polymerize” strategy powered by the rich synthetic chemistry are very appealing, which attracted both chemistry and materials researchers into the field of aPOPs, including MG-aPOPs. For example, the synthetic methods based on transistion metal catalyzed C–C cross-coupling reactions were benchmarked for introducing diverse functional building blocks into MG-aPOPs.
To expand the diversity of chemical structures and properties, recent research of MG-aPOPs has been mainly focusing on the design of new building blocks with more complex structures. Although the diverse building blocks enriched the structures and functions, these complex building blocks generally required multiple-step syntheses and non-trivial purification processes. Therefore, it is envisioned that using simple and commercially available MG-building blocks could be alternative strategy for considerably streamlining the synthesis and diversifying the properties of aPOPs. For example, Ren’s group was able to use BBr3 and PCl3 as the simple starting materials to build MG-aPOPs with active MG-centers39,58. It was found that the B–Sn exchange reaction and CuI catalyzed P–C coupling reaction are highly efficient at the single B-atom and P-atom, which afforded new MG-aPOPs with good porous characteristics.
It is worthy of mentioning that Kaskel’s group and Hausoul group used similar halides (PCl3 and SiCl4) and aryl-lithium and aryl-Grignard reagents as the starting materials to construct MG-aPOPs106,107,108. However, the use of highly reactive organometallic reagents limited the scope of starting materials that are sensitive to the strong nucleophilic organometallic reagents. In another recent example, Chan and coworkers reported a new series of Bi-containing crosslinked organic polymers by using Bi–S polycondensation109,110. Although the porosimetry measurements revealed the low surface areas of the Bi-polymers, the study is a nice demonstration of the heavier main-group chemistry in the synthesis of MG-aPOPs. However, the high toxicity of heavier main group element Bi should also be paid attention.
Different from the synthesis of cPOPs generally involved reversible bond-forming and bond-breaking processes,(MG-)aPOPs are synthesized by irreversible chemical bond formation1,2,3,111,112,113,114,115,116. The intrinsic bond formation mechanism of (MG-)aPOPs is believed to be detrimental to constructing the well-controlled chemical and porous structures. The nature of heterogeneous polymerization condtions further restricted the better controls in the chemical and porous structures. Recent studies that identified some important reaction characteristics for the better-controlled chemical and porous structures of aPOPs are highly appealing. For example, Faul’s group discovered that the inorganic salts have the strong impacts on the BET surface areas and PSD of N-P8 synthesized by Buchwald-Hartwig reaction (Fig. 16)87. They proposed that the salts act similarly to the addition of porogens, which helps to tune the HSPs between polymers and reaction solvents. According to the classic HSP principle, solvent with poor thermodynamic compatibility and weak matching of the HSPs with the resultant polymeric networks could lead to the formation of microgels and early phase separation. In this situation, the aPOPs with large average diameter pores and low surface areas were rationalized to be obtained. The addition of the salts is believed to match the HSPs between the polymers and the solvents, consequently resulting in the late-stage phase separation of the polymerization. Therefore, N-P8 with lower PSD and larger surface area was expected to be obtained in the presence of the salts. The hypothesis was further supported by the calculation of the HSP in various solvents. This mechanism also explains that the permanent dipole interactions and the hydrogen-bonding interactions of the ions enhance with the decrease of their ionic radius, consequently giving a better adjustment of the compatibility of the HSPs with the polymers.
In another recent example, Ren’s group identified that the self-accelerating kinetic character of Cu-catalyzed P–C coupling reaction is beneficial for constructing the better-controlled and better-defined crosslinking environments and porosity in P-aPOPs (Fig. 17a)58. In the kinetic study of model reactions, the reaction rate constant k3 is higher than the reaction rate constants k1 and k2 (Fig. 17b, c). Furthermore, the choice of base also influnenced the kinectic of the model reactions (Fig. 17d). In line with the model studies, the P−C polymerizations with the high reaction-rate conditions afforded P-aPOPs with more uniform crosslinking environments, better-controlled porosity, high ultramicroporous surface areas, and high CO2 uptake (Fig. 17e). More fully crosslinked P-centers are expected to be achieved for a reaction with the ideal self-accelerating characteristic (k3 ≫ k1, k2) where three P–C bonds at a single P-center almost instantly form at the same time. In the ideal scenario, the local crosslinked microporous environments may form uniformly within a very short time scale. It is believed that other types of reactions with the similar kinetic reaction characteristics may be also applicable to the synthesis of aPOPs with better-controlled chemical and porous structures.
Exploring experimental characterization techniques for MG-Amorphous POPs
Experimental characterization techniques are very useful to shed light on the relationship between chemical structures, porosity and functions of MG-aPOPs, which will accelerate the finding of new strategies for designing new functional MG-aPOPs. All the experimental characterization techniques used in aPOPs are also applicable to MG-aPOPs. Like typical porous materials, gas sorption experiments are the main characterization technique to provide the porous structure information, such as surface area, porous diameter, and shape of porous structures in MG-aPOPs117,118,119,120,121.
The chemical composition of MG-aPOPs can be readily examed by the well-established materials characterization techniques, such as Fourier transform infrared (FTIR), elemental analysis (EA), inductively coupled plasma optical emission spectroscopy (ICP-OES), X-ray photoelectron spectroscopy (XPS), and solid state NMR. In addition to revealing the chemical compositions, these techniques with appropriate modifications were also able to uncover useful information on the porous structure formation of MG-aPOPs. For instance, in-situ FTIR experiments were used to track the process of C–C bond forming in the porosity formation progress of C-aPOPs111. In another example of the “digesting and probing” method, 1H NMR experiments of the digested Sn-aPOPs indirectly identified the chemical compositions78,122. The results of these modified experiments clearly suggest that the polymerizations of the aPOPs were not always as uniform as expected, and various side reactions may occur during the polymerizations of monomers.
Solid state multinuclear (11B, 31P, 19F, etc.) NMR spectroscopy is another powerful technique that is able to provide the important chemical information of aPOPs containing NMR active MG elements, such as the chemical purifty and valence of the MG-centers. For example, solid state 11B and 31P NMR experiments were widely used to identify the presence of various B centers and P centers in MG-aPOPs39,58,95. Compared with those of solid state 13C NMR experiments, the signals of 11B and 31P NMR experiments are more sensitive to the chemical environments. The 11B and 31P NMR experiments were also able to track the chemical environment changes of the element centers39,58,95, such as Lewis acid-base interactions at the B-center (Fig. 4d) and the chemical valence of P-centers (Fig. 18a, b).
Although the chemical compositions of MG-aPOPs, like all the aPOPs, can be well characterized by the typical material characterization techniques mentioned above, precisely probing the solid-state structures of MG-aPOP are still very challenging. With the intrinsically amorphous nature, the solid-state structures of aPOPs including MG-aPOPs cannot be investigated by X-ray diffraction experiments. Without the reliable structural information, the relationship between structures, properties and functions of MG-aPOPs are hard to be generalized, which further limited the design of new MG-aPOPs with improved properties.
In the solid-state structure, the environments of crosslinking centers not only play important roles in determining the chemical uniformity, but also governing the porous structures of aPOPs including MG-aPOPs. Very recently, characterizing the chemical environments of crosslinking centers in MG-aPOPs became possible by using various NMR active MG elements (such as B and P) as the direct crosslinking centers in the synthesis, which readily shed light on the solid-state structures. Although solid state 13C NMR experiments were successfully used to qualitatively track the polymerization progress of C-aPOPs in a previous study115, the characteristics of weak solid state 13C NMR signals and possible indistinguishable peaks of the probed C-centers (mostly sp2 and sp3 carbons) with other similar C-centers make the solid state 13C NMR experiments rarely provided quantitative information on the chemical environments of the crosslinking C-centers. Leveraging on the highly sensitive solid state 31P NMR signals under various environments, solid state 31P NMR experiments directly revealed the crosslinking degree of the P-aPOPs under different reaction conditions (Fig. 18c, d)39,58,95. The higher of the reaction rates, the more uniform of crosslinking P-centers.
In addition to the above solid state NMR technique, Tsotsalas and coworkers also explored the use of solid state electron paramagnetic resonance spectroscopy technique to quantify the crosslinking degree in N-aPOPs (Fig. 19)123. The nitroxide exchange reaction allowed them to not only modify the EPR active crosslinking TEMPO nitroxide center, but also reveal the impacts of the crosslinking center on the porosity of the materials.
Challenges and future directions for MG-Amorphous POPs
As a subgroup of aPOPs, the unique family of MG-aPOPs just started its journy recently. Although the rich chemical and electronic configurations of main group elements successully endowed the aPOPs with the diverse chemical structures, properties, and functions in the unprecedent areas, there are still lots of challenges from the prospective of the chemical-structure and solid-state-structure probing, the porous-structure tuning, and the thin-film state developing.
Solid state NMR/FTIR experiments were widely used to probe the chemical structures of MG-aPOPs in previous studies. Due to the limited sensitivity and resolution, these experiments hardly provided the full and precise chemical information of MG-aPOPs. According to the polymer digestion method designed by Bunz and coworkers, the chemical compositions of MG-aPOPs may not always be the same as the small molecule reactions78. Therefore, for any newly synthesized MG-aPOPs, multiple chemical characterization methods, such as solid state FTIR/NMR, EA, ICP-OES, XPS, etc., are strongly suggested to apply, which can provide the more detailed and reliable chemical information. Even though, under some specific situations, as such in full carbon-based aPOPs, the full and precise chemical information is still difficult to obtain due to the very similar chemical environments of the carbon elements within the reaction mixtures. Therefore, new experimental techniques with high sensitivity and resolution are exceedingly desirable for the developments of MG-aPOPs in the future.
Different from cPOPs where the solid-state structures can be successfully probed by the X-ray diffraction experiments, the solid-state stucture information of MG-aPOPs is hard to uncover due to the lack of long-range order. Previous studies showed that porous structures of aPOPs is not crystallographically defined by the monomer structures as observed in the crysalline porous materials8,30. It is generally believed that the porosity is due to less efficient struct packings in the amorphous polymeric networks, in which the average pore sized distribution envelop is related statistically to the stuctures of monomers (average length, conformational freedom and topological geometries) and the interpenetration of polymer chains. We believe that the same situation is also applicable to MG-aPOPs in term of porosity formation.
As discussed in the previous section, few of the classical materials characterization techniques were able to reveal the solid-state structure information of MG-aPOPs. Although the solid-structures cannot be fully revealed, the solid-state structure information of MG-aPOPs, such as porous environments and crosslinking environments, was able to be quanitatively uncovered by using solid state NMR experiments in the recent studies58. The solid state NMR experiments harnessed a new strategy to probe the environments of crosslinking centers, in which NMR active main group elements (such as B and P) were used as the direct crosslinking centers. In the future, it is believed that polymerizations having other NMR active main group elements (such as Si, Al, Ga, etc.) as the direct crosslinking points will also allow the solid state NMR experiments to directly probe the chemical environments of these crosslinking centers.
With more reliable information on the crosslinking environments, more insightful information on the relationship between the chemical structures, porosity characteristics, and functions was able to be obtained. Therefore, the design of new polymerization chemistry involving NMR active main group elements and carbon bond formation could be one promising area for the better controlled chemical and porous stuctures of aPOPs in the future. Particularly, a great number of heavier main group elements will be also suitable for constructing MG-aPOPs when choosing appropriate synthetic chemistry. The different synthetic protocols, oxidation state, and coordination chemistry of heavier main group elements will lead to new horizons in the field. For example, compared with trivalent B-center, Al-center may endow polymeric structures with enhanced Lewis acid characteristics and tunable topological structures where Al-center can adopt trigonal planar, tetrahedral, and trigonal bipyramid structures.
Along with probing the solid structures, controlling the chemical and porous structures is another challenge that limited the advance of MG-aPOPs. The irreversible chemical bond formation character of aPOPs intrinsically constrained the control of porous structure formation. Altough constructing MG-aPOPs with uniform microporosity, even ultramicroporosity are not impossible in the recent studies8,58,83,84,85,87,97, the fundemental principles for achieving the uniform microporosity and ultramicroporosity are yet to be uncovered and generallized. Recent studies clearly showed that reaction conditions, such as monomer ratios, catalysts, ligands, and solvents, have strong impacts on the chemical structures and porous structures of aPOPs synthesized by classical transistion metal catalyzed coupling reactions1,2,3,8,38,58,78,87,113,114,115,116,122. For example, the same monomers afforded the very different porous structures under the different polymerization conditions, such as reaction rates58,115. Therefore, exerting more efforts on revealing the fundamental principles is expected as the new reserch directions for MG-aPOPs in the future.
The insoluble character of aPOPs also limitd their potential applications in some specific areas, such as organic electronic devices where materials in the thin-film state are generally required. Recent progress showed that the in-situ surface electropolymerization method can be nicely harnessed to construct the thin-film state of B-aPOPs that maintain good porosity characters and better surface morphologies73. Furthermore, the thin film of MG-aPOPs with large surface areas and uniform surface morphologies are expected to find various applications of electronic devices, photocatalysis, and toxic gases sensing. However, the in-situ surface electro-polymerization strategy has not been fully recognized in the field of aPOPs. Recent bloom of electrochemical organic synthesis involved main group elements and carbon bond formations potentially provide new opportunities for constructing MG-aPOP based thin films as the new research direction in the future124.
Conclusion and outlook
As a subgroup of aPOPs, MG-aPOPs indeed witnessed the fast development in recent years. This review highlighted some distinct examples of MG-aPOPs containing Group-13, Group-14, Group-15, and Group-16 elements. The unique chemical geometries and electronic configurations of main group elements played important roles in tuning the chemical structures, porosities, and properties of the MG-aPOPs. Topological structures of the various main group element showed the strong impacts on the porous characteristics of MG-aPOPs. Particularly, the rigid 3D main-group centers endowed MG-aPOPs with the significantly high surface areas. The electron-rich and electron-poor characters of main group element fruther modulated the redox, optical and electronic properties of the MG-aPOPs in another dimension. The review also discussed the new main group element chemistry applied for synthesizing MG-aPOPs. These studies will catalyze more new synthetic protocols involving unexplored main group element chemistry for designing new functional MG-aPOPs in the future.
Later, the review further covered the main characterization techniques designed for MG-aPOPs. The amorphous nature of MG-aPOPs made the structure elucidation very challenging. Using the unique main group elements as the direct crosslinking centers may offer an alternative method to shed light on the relationships between crosslinking environments, porosities and properties. It was anticipated that the uncovered insights can provide guidance, and enlighten future research efforts in advancing the field. Bridging rich main-group chemistry and the porous structure is clearly appealing. More unexpected and exciting findings on the structures and properties of MG-aPOPs are to be discovered in the emerging field through the merry marriage.
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This research was financially supported by ShanghaiTech University start-up funding and Natural Science Foundation of Shanghai (19ZR1433700).
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Y.R. conceptualized the paper. Z.Z., Z.L., C.X., H.C. and X.H. searched the literature and drew figures. Z.Z., Z.L., C.X. and Y.R. co-wrote, proofread and edited the paper.
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Zhang, Z., Liu, Z., Xue, C. et al. Amorphous porous organic polymers containing main group elements. Commun Chem 6, 271 (2023). https://doi.org/10.1038/s42004-023-01063-5
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DOI: https://doi.org/10.1038/s42004-023-01063-5