Donor–Acceptor Porous Conjugated Polymers for Photocatalytic Hydrogen Production: The Importance of Acceptor Comonomer

Li, Lianwei; Lo, Wai-Yip; Cai, Zhengxu; Zhang, Na; Yu, Luping

doi:10.1021/acs.macromol.6b01764

Cited by 133 publications

(108 citation statements)

References 33 publications

(47 reference statements)

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“…Examples of organic photocatalysts include oligo-and poly(p-phenylene)s [26][27][28][29] and other unbranched conjugated polymers, [30][31][32][33] poly(azomethine)s, 34 triazine-type materials, [35][36][37][38][39][40] covalent organic frameworks, [41][42][43] and a rapidly increasing number of structurally diverse conjugated microporous polymers. 7,[44][45][46][47][48] The activity of these photocatalysts for hydrogen and/or oxygen evolution is a complex function of properties such as the absorption spectrum, the potential of the charge carriers (i.e., the band positions), and the wettability of their surfaces, among other factors. It is challenging to optimize all of these various properties through copolymerisation strategies since they may have contrasting or indeed antagonistic dependencies on the copolymer composition: for example, introduction of polar building blocks might increase the wettability of the polymer while also impacting light absorption in a negative way.…”

Section: Introductionmentioning

confidence: 99%

Maximising the hydrogen evolution activity in organic photocatalysts by co-polymerisation

et al. 2018

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Section: Introductionmentioning

confidence: 99%

Maximising the hydrogen evolution activity in organic photocatalysts by co-polymerisation

et al. 2018

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“…Yu et al investigated the photocatalytic activity of as eries of S-andN -containing polymers achieving hydrogen evolution rates of up to 106.9 mmol h À1 withoutt he addition of ac o-catalyst. [17] However,t he report states ar esidual palladium (Pd) content from the Sonogashira-Hagihara cross-coupling of between 0.73 and 2.13 wt %t hat may facilitatet he hydrogen evolution reaction. [18] In our SNPs andN Ps, we detect residual Pd content between 0.13 and 0.02 wt %( one order of magnitude lower than in previous reports) via inductively coupled plasma optical emissions pectrometry (ICP-OES; Supporting Information, Ta ble S5), energy-dispersive X-ray (EDX) spectroscopy (Supporting Information, Table S6), and XPS (Supporting Information, Ta ble S8).…”

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confidence: 99%

Tailored Band Gaps in Sulfur‐ and Nitrogen‐Containing Porous Donor–Acceptor Polymers

Schwarz

Kochergin

Acharjya

et al. 2017

Chemistry A European J

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Donor-acceptor dyads hold the key to tuning of electrochemical properties and enhanced mobility of charge carriers, yet their incorporation into a heterogeneous polymer network proves difficulty owing to the fundamentally different chemistry of the donor and acceptor subunits. A family of sulfur- and nitrogen-containing porous polymers (SNPs) are obtained via Sonogashira-Hagihara cross-coupling and combine electron-withdrawing triazine (C N ) and electron-donating, sulfur-containing linkers. Choice of building blocks and synthetic conditions determines the optical band gap (from 1.67 to 2.58 eV) and nanoscale ordering of these microporous materials with BET surface areas of up to 545 m g and CO capacities up to 1.56 mmol g . Our results highlight the advantages of the modular design of SNPs, and one of the highest photocatalytic hydrogen evolution rates for a cross-linked polymer without Pt co-catalyst is attained (194 μmol h g ).

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“…The high photocatalytic activity of PrCMP‐3 could be mainly attributed to the high specific surface area and extended π‐conjugation. However, it is still low in comparison with other functionalized CMP photocatalysts, such as spirobifluorene‐containing PCP2e (26 µmol h −1 ), SP‐CMP (28.8 µmol h −1 ), donor–acceptor porous conjugated polymer of PCP11 (106.9 µmol h −1 ), benzothiadiazole‐containing linear polymer of B‐BT‐1,4 (116 µmol h −1 ), dibenzo[b,d]thiophene‐based linear conjugated copolymer photocatalyst (145 µmol h −1 ), and the perylene‐based porous conjugated polymer of PCP3e with bipyridyl acceptor unit (17.8 µmol h −1 ) . The main reason could be attributed to the lack of functional groups in favor of charge transmission in these PrCMPs compared with other organic photocatalysts.…”

Section: Resultsmentioning

confidence: 99%

“…Then, they developed another series of CMP photocatalysts with different monomer linker length . Yu and co‐workers reported that the CMP photocatalysts with donor segments, fully conjugated backbone and ordered local structure, which are important for charge transport, could exhibit high photocatalytic activity for hydrogen evolution. They also revealed that the residual palladium catalyst plays a key role for the catalytic performance of CMPs.…”

Section: Introductionmentioning

confidence: 99%

Perylene‐Containing Conjugated Microporous Polymers for Photocatalytic Hydrogen Evolution

Mao

Shi

et al. 2017

Macro Chemistry & Physics

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Three perylene‐containing conjugated microporous polymers (PrCMPs) are synthesized via Suzuki–Miyaura cross‐coupling reaction from perylene with four polymerizable functional groups and a range of different substituted benzene derivatives. The pore property and bandgap of the resulting PrCMPs can be tuned by changing the comonomer of benzene with different substituted groups and positions. The photocatalytic performances of the polymers are highly dependent on the surface area, geometry, and bandgap of the PrCMPs. It was found that the 1,2,4,5‐linked polymer of PrCMP‐3 shows the highest hydrogen evolution rate (HER) of 12.1 µmol h−1 under UV–vis light irradiation among the three polymers because of its high surface area, broad light absorption, and suitable bandgap. PrCMP‐3 also exhibits good photocatalytic stability for prolonged hydrogen production reaction. This result demonstrates that the crucial role of the linkage geometry offers a general principle for the rational design of conjugated microporous polymer photocatalysts.

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Donor–Acceptor Porous Conjugated Polymers for Photocatalytic Hydrogen Production: The Importance of Acceptor Comonomer

Cited by 133 publications

References 33 publications

Maximising the hydrogen evolution activity in organic photocatalysts by co-polymerisation

Maximising the hydrogen evolution activity in organic photocatalysts by co-polymerisation

Tailored Band Gaps in Sulfur‐ and Nitrogen‐Containing Porous Donor–Acceptor Polymers

Perylene‐Containing Conjugated Microporous Polymers for Photocatalytic Hydrogen Evolution

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