Pathways towards Boosting Solar‐Driven Hydrogen Evolution of Conjugated Polymers

Liu, Yaoyao; Li, Bingjie; Xiang, Zhonghua

doi:10.1002/smll.202007576

Cited by 48 publications

(42 citation statements)

References 236 publications

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“…[ 6–8 ] To date, various organic polymers with conjugated skeletons have been developed as photocatalysts for hydrogen evolution. [ 9–11 ] In particular, significant advances in the preparation of conjugated microporous polymer (CMP) photocatalysts with high photocatalytic activity have been achieved. [ 12–14 ]…”

Section: Introductionmentioning

confidence: 99%

“…[6][7][8] To date, various organic polymers with conjugated skeletons have been developed as photocatalysts for hydrogen evolution. [9][10][11] In particular, significant advances in the preparation of conjugated microporous polymer (CMP) photocatalysts with high photocatalytic activity have been achieved. [12][13][14] Many studies revealed that designing a donor-acceptor (D-A) molecular structure is an efficient strategy to boost the photocatalytic activity of conjugated polymer photocatalysts, [15][16][17][18] since the intrinsic electron push-pull effect in a D-A conjugated polymer could promote the separation of light-induced hole/ electron.…”

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An Efficient Electron Donor for Conjugated Microporous Polymer Photocatalysts with High Photocatalytic Hydrogen Evolution Activity

Han

Xiang

et al. 2022

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electronic structure. [3][4][5] Nevertheless, most inorganic photocatalysts suffer from low activity under visible light, complexity in the preparation, and the limited natural resources. Recent studies demonstrated that organic semiconductors could be a promising class of photocatalysts for hydrogen evolution because of their diverse structures, various synthetic strategies, and tunable electronic properties. [6][7][8] To date, various organic polymers with conjugated skeletons have been developed as photocatalysts for hydrogen evolution. [9][10][11] In particular, significant advances in the preparation of conjugated microporous polymer (CMP) photocatalysts with high photocatalytic activity have been achieved. [12][13][14] Many studies revealed that designing a donor-acceptor (D-A) molecular structure is an efficient strategy to boost the photocatalytic activity of conjugated polymer photocatalysts, [15][16][17][18] since the intrinsic electron push-pull effect in a D-A conjugated polymer could promote the separation of light-induced hole/ electron. The nature of electron donor and acceptor units plays a key point in the charges transfer and separation, which affect significantly the photocatalytic activity. Therefore, the selection of electron donor and acceptor is of great importance for constructing organic polymer photocatalysts with high photocatalytic activity. In general, aromatic heterocyclic compounds with narrow band gap are commonly used as electron acceptors, and aromatic hydrocarbons with delocalized π-electron are employed as electron donors to build D-A type polymer photocatalysts. Based on the developed D-A polymer photo catalysts to date, [15,[19][20][21][22] dibenzo[b,d]thiophene-S,S-dioxide (BTDO) might be the most effective acceptor unit due to its strong electronwithdrawing capability and high hydrophilicity, [23][24][25] and pyrene with planar molecular structure and large delocalized π-electron system is the most effective electron donor to prepare high performance polymer photocatalysts. [26,27] Although there have been significant advances in the photo catalytic activity of polymer photocatalysts by structure optimization, [28,29] the limited scope of high efficient electron donors and acceptors hinders the further development of organic polymer photo catalysts. To further improve the photocatalytic activity and enrich the D-A) molecular structure show high photocatalytic activity for hydrogen evolution due to the efficient light-induced electron/hole separation, which is mostly determined by the nature of electron donor and acceptor units. Therefore, the selection of electron donor and acceptor holds the key point to construct high performance polymer photocatalysts. Herein, two dibenzo[b,d]thiophene-S,Sdioxide (BTDO) containing CMP photocatalysts using tetraphenylethylene (TPE) or dibenzo[g,p]chrysene (DBC) as the electron donor to investigate the influence of the geometry of electron donor on the photocatalytic activity are design and synthesized. Compared with the twisted TPE donor,...

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Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

An Efficient Electron Donor for Conjugated Microporous Polymer Photocatalysts with High Photocatalytic Hydrogen Evolution Activity

Han

Xiang

et al. 2022

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“…Several papers have reviewed the applications of 2D nanomaterials, [2,3,6,14,15] conjugated networks, [4,7,12,16,17] porous organic polymers (POPs), [5,13,[18][19][20][21][22] hypercrosslinked porous polymer (HCPs), [23] porous aromatic frameworks (PAFs), [24] and carbonaceous materials, [25,26] in which CTFs are involved as a subclass material, and specific fields deploying CTFs-related systems, [9,11,27] such as separation [28][29][30][31] and catalysis, [10,[32][33][34] while systematic summarization and comparison of graphitic aza-fused π-conjugated networks including and beyond CTFs have rarely been covered. Considering the blossom of the material category related to graphitic aza-fused π-conjugated networks, it is highly required to figure out the pivotal factors in structure-property-application relationship from diverse levels, which will provide guidance in monomer design and synthesis pathway selection to achieve far-reaching applications.…”

Section: Doi: 101002/adma202107947mentioning

confidence: 99%

“…Generally, the photocatalytic activity of these materials is determined by their band structures, charge separation and transfer efficiency, porosity, dispersibility, and so on. [14] Relying on the vast structure-to-property regulating methodologies being developed, the photocatalytic applications of related systems have been witnessed in water splitting, [16,20,34] H 2 O 2 generation, CO 2 reduction, organic coupling reaction, and pollutant degradation.…”

Section: As Catalyst Components In Photocatalysismentioning

confidence: 99%

Graphitic Aza‐Fused π‐Conjugated Networks: Construction, Engineering, and Task‐Specific Applications

et al. 2022

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The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/adma.202107947.2D π-conjugated networks linked by aza-fused units represent a pivotal category of graphitic materials with stacked nanosheet architectures. Extensive efforts have been directed at their fabrication and application since the discovery of covalent triazine frameworks (CTFs). Besides the triazine cores, tricycloquinazoline and hexaazatriphenylene linkages are further introduced to tailor the structures and properties. Diverse related materials have been developed rapidly, and a thorough outlook is necessitated to unveil the structure-property-application relationships across multiple subcategories, which is pivotal to guide the design and fabrication toward enhanced taskspecific performance. Herein, the structure types and development of related materials including CTFs, covalent quinazoline networks, and hexaazatriphenylene networks, are introduced. Advanced synthetic strategies coupled with characterization techniques provide powerful tools to engineer the properties and tune the associated behaviors in corresponding applications. Case studies in the areas of gas adsorption, membrane-based separation, thermo-/ electro-/photocatalysis, and energy storage are then addressed, focusing on the correlation between structure/property engineering and optimization of the corresponding performance, particularly the preferred features and strategies in each specific field. In the last section, the underlying challenges and opportunities in construction and application of this emerging and promising material category are discussed.

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“…By comparing the properties of the solvent, it seemed that the activity was positively correlated with the polarity. 24 Therefore, methanol was added to compare the effects of solvents with similar structure on the properties. It can be seen from the test results (Fig.…”

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Biomimetic control of charge transfer in MOFs by solvent coordination for boosting photocatalysis

et al. 2022

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Pathways towards Boosting Solar‐Driven Hydrogen Evolution of Conjugated Polymers

Cited by 48 publications

References 236 publications

An Efficient Electron Donor for Conjugated Microporous Polymer Photocatalysts with High Photocatalytic Hydrogen Evolution Activity

An Efficient Electron Donor for Conjugated Microporous Polymer Photocatalysts with High Photocatalytic Hydrogen Evolution Activity

Graphitic Aza‐Fused π‐Conjugated Networks: Construction, Engineering, and Task‐Specific Applications

Biomimetic control of charge transfer in MOFs by solvent coordination for boosting photocatalysis

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