Photocatalysts Based on Organic Semiconductors with Tunable Energy Levels for Solar Fuel Applications

Koščo, Ján; Moruzzi, Floriana; Willner, Benjamin; McCulloch, Iain

doi:10.1002/aenm.202001935

Cited by 108 publications

(91 citation statements)

References 177 publications

(339 reference statements)

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“…[ 33 ] The high photocatalytic activity of PyDOBT‐1 can be ascribed to not only the advantages of BTDO but also the pyrene unit, which features with strong electron‐donating ability, high coplanarity, and extended π‐electron delocalization. [ 26,31,36,40 ] In order to get in‐depth insight into the influence of chemical structure and the monomer compositions on the photocatalytic activity, we constructed here a series of D–π–A CMP photocatalysts using statistical copolymerization by insetting a “π‐bridge” of benzene between the pyrene donor and BTDO acceptor units. The influence of chemical structure and particularly the monomer compositions on the photocatalytic activity of the resulting D–π–A copolymers was systematically investigated by tuning the feed ratio of donor to acceptor.…”

Section: Introductionmentioning

confidence: 99%

Boosting the Photocatalytic Hydrogen Evolution Activity for D–π–A Conjugated Microporous Polymers by Statistical Copolymerization

et al. 2021

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Recently, great progress has been achieved in the design and preparation of conjugated organic polymer photocatalysts for hydrogen generation. However, it is still challenging to develop an organic polymer photocatalyst with high photoconversion efficiency. Rational structure design of organic polymer photocatalysts holds the key point to realize high photocatalytic performance. Herein, a series of donor–π–acceptor (D–π–A) conjugated organic copolymer photocatalysts is developed using statistical copolymerization by tuning the feed molar ratio of pyrene (donor) to dibenzothiophene‐S,S‐dioxide (acceptor) units. It reveals that the photocatalytic activity of the resulting copolymers is significantly dependent on the molar ratio of donor to acceptor, which efficiently changes the polymer structure and component. When the monomer feed ratio is 25:75, the random copolymer PyBS‐3 of 10 mg with Pt cocatalyst shows a high hydrogen evolution rate of 1.05 mmol h−1 under UV/Vis light irradiation using ascorbic acid as the hole‐scavenger, and an external quantum efficiency of 29.3% at 420 nm, which represents the state‐of‐the‐art of organic polymer photocatalysts. This work demonstrates that statistical copolymerization is an efficient strategy to optimize the polymer structure for improving the photocatalytic activity of conjugated organic polymer catalysts.

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Section: Introductionmentioning

confidence: 99%

Boosting the Photocatalytic Hydrogen Evolution Activity for D–π–A Conjugated Microporous Polymers by Statistical Copolymerization

et al. 2021

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“…Fortunately, photocatalysis with the aid of semiconductor photocatalysts could be employed to facilitate these reduction reactions. However, suitable redox potentials and strong solar light absorption properties are necessary for efficient photocatalytic reactions, which most of the semiconductors do not possess [12,13]. So far, TiO 2 has gained considerable attention in photocatalysis owing to its low cost, high stability, high performance, and nontoxicity.…”

Section: Introductionmentioning

confidence: 99%

Plasmon Assisted Highly Efficient Visible Light Catalytic CO2 Reduction Over the Noble Metal Decorated Sr-Incorporated g-C3N4

et al. 2021

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The photocatalytic performance of g-C3N4 for CO2 conversion is still inadequate by several shortfalls including the instability, insufficient solar light absorption and rapid charge carrier’s recombination rate. To solve these problems, herein, noble metals (Pt and Au) decorated Sr-incorporated g-C3N4 photocatalysts are fabricated via the simple calcination and photo-deposition methods. The Sr-incorporation remarkably reduced the g-C3N4 band gap from 2.7 to 2.54 eV, as evidenced by the UV–visible absorption spectra and the density functional theory results. The CO2 conversion performance of the catalysts was evaluated under visible light irradiation. The Pt/0.15Sr-CN sample produced 48.55 and 74.54 µmol h−1 g−1 of CH4 and CO, respectively. These amounts are far greater than that produced by the Au/0.15Sr-CN, 0.15Sr-CN, and CN samples. A high quantum efficiency of 2.92% is predicted for the Pt/0.15Sr-CN sample. Further, the stability of the photocatalyst is confirmed via the photocatalytic recyclable test. The improved CO2 conversion performance of the catalyst is accredited to the promoted light absorption and remarkably enhanced charge separation via the Sr-incorporated mid gap states and the localized surface plasmon resonance effect induced by noble metal nanoparticles. This work will provide a new approach for promoting the catalytic efficiency of g-C3N4 for efficient solar fuel production.

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“…This unique feature could substantially lower the thermodynamic driving force for the competitive CO 2 ‐to‐CO conversion and H 2 evolution, facilitating the thermodynamically favored CO 2 ‐to‐CH 4 conversion. [ 11,26 ]…”

Section: Resultsmentioning

confidence: 99%

Selective CO₂‐to‐CH₄ Photoconversion in Aqueous Solutions Catalyzed by Atomically Dispersed Copper Sites Anchored on Ultrathin Graphdiyne Oxide Nanosheets

Wang

et al. 2021

Solar RRL

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Photocatalytic conversion of carbon dioxide (CO2) into chemical fuels using sunlight represents an intriguing approach to simultaneously address energy and environmental issues. However, steering the reaction pathways during the photocatalytic reduction of CO2 to selectively produce desirable hydrocarbon fuels such as methane (CH4) remains a significant challenge. Meanwhile, suppressing the hydrogen evolution reaction is extremely difficult when the photocatalytic process is carried out in aqueous solutions. Herein, ultrathin graphdiyne oxide nanosheets prepared by oxidizing and exfoliating from as‐synthesized graphdiyne are used to activate coordinated Cu2+ sites without using additional organic ligands for selective reduction of CO2 to CH4 in aqueous solutions. It is shown that the reaction selectivity toward CH4 and CO production can reach 87% and 13%, respectively, whereas the hydrogen evolution reaction can be completely inhibited. The atomically anchored Cu2+ ions can effectively trap photogenerated electrons and serve as active sites for the selective CO2‐to‐CH4 conversion. Considering the rich coordination chemistry of polymer materials, the methodology presented in this study can be extended to prepare various polymer‐based photocatalysts with precisely engineered metallic centers toward the selective reduction of CO2 to chemical fuels.

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Photocatalysts Based on Organic Semiconductors with Tunable Energy Levels for Solar Fuel Applications

Cited by 108 publications

References 177 publications

Boosting the Photocatalytic Hydrogen Evolution Activity for D–π–A Conjugated Microporous Polymers by Statistical Copolymerization

Boosting the Photocatalytic Hydrogen Evolution Activity for D–π–A Conjugated Microporous Polymers by Statistical Copolymerization

Plasmon Assisted Highly Efficient Visible Light Catalytic CO2 Reduction Over the Noble Metal Decorated Sr-Incorporated g-C3N4

Selective CO₂‐to‐CH₄ Photoconversion in Aqueous Solutions Catalyzed by Atomically Dispersed Copper Sites Anchored on Ultrathin Graphdiyne Oxide Nanosheets

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Photocatalysts Based on Organic Semiconductors with Tunable Energy Levels for Solar Fuel Applications

Cited by 108 publications

References 177 publications

Boosting the Photocatalytic Hydrogen Evolution Activity for D–π–A Conjugated Microporous Polymers by Statistical Copolymerization

Boosting the Photocatalytic Hydrogen Evolution Activity for D–π–A Conjugated Microporous Polymers by Statistical Copolymerization

Plasmon Assisted Highly Efficient Visible Light Catalytic CO2 Reduction Over the Noble Metal Decorated Sr-Incorporated g-C3N4

Selective CO2‐to‐CH4 Photoconversion in Aqueous Solutions Catalyzed by Atomically Dispersed Copper Sites Anchored on Ultrathin Graphdiyne Oxide Nanosheets

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Selective CO₂‐to‐CH₄ Photoconversion in Aqueous Solutions Catalyzed by Atomically Dispersed Copper Sites Anchored on Ultrathin Graphdiyne Oxide Nanosheets