Highly‐Active Chiral Organic Photovoltaic Catalysts with Suppressed Charge Recombination

Li, Yawen; Zhang, Zhenzhen; Li, Tengfei; Liang, Yuanxin; Si, Wenqin; Lin, Yuze

doi:10.1002/anie.202307466

Cited by 13 publications

(6 citation statements)

References 69 publications

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“…43 However, equivalent modeling of the photophysics of neat Y6 NPs has not been reported. Y6 NPs and Y6 films have significant differences in steady-state absorption, 29–32,43 which broadly indicate a lower degree of ordering in Y6 NPs compared to Y6 films. 59 Due to this difference in molecular packing, further analysis of the photophysics of neat Y6 NPs is required to understand the extent of free charge generation in this more disordered morphology.…”

Section: Resultsmentioning

confidence: 99%

“…1b) and other members of the Y-series. 24,25 Single-component polymeric 26,27 and small-molecule 28–31 NPs as well as donor:acceptor NPs at both conventional 32–36 and unconventional 37 donor:acceptor ratios produced from materials from the organic photovoltaic field have been shown to effectively reduce protons to H 2 under excitation wavelengths across the visible and near-infrared. 38 The highest production rates are typically achieved with donor:acceptor blends, with most reports using a sacrificial electron donor such as ascorbic acid (AA).…”

Section: Introductionmentioning

confidence: 99%

“…Kosco et al reported that AA is a slow hole scavenger (10 μs timescale), 34 but systems without long-lived polarons are also active with AA. 28–31 Understanding the properties that limit or promote transfer of electrons and holes to co-catalysts and sacrificial reagents is important for the future optimization of these systems.…”

Section: Introductionmentioning

confidence: 99%

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From light to hydrogen: the complete life cycle of free charges in photocatalytic nanoparticles

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et al. 2024

Sustainable Energy Fuels

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

From light to hydrogen: the complete life cycle of free charges in photocatalytic nanoparticles

de la Perrelle,

Hudson,

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et al. 2024

Sustainable Energy Fuels

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show abstract

“…With the aim of bringing down the effect of photogenerated carrier recombination on photocatalyst efficiency, an interesting acceptor couple of Y6-R and Y6-S was developed with enantiopure R-and Schiral alkyl side chains. [31] Y6-R and Y6-S showed effective aggregation-induced chirality, which contributed to the suppressed charge recombination and better photocatalytic hydrogen yield rates relative to their achiral counterpart (Y6). For the first time, the positive effects of molecular chirality on organic photosensitizer-based photocatalytic hydrogen production were disclosed.…”

Section: Minireviewsmentioning

confidence: 99%

“…Hydrogen yield rate (mmol h À 1 g À 1 ) Surfactants [a] PTB7-Th/EH-IDTBR [18] 5 wt % Pt 64.4 TEBS PTB7-Th/EH-IDTBR [18] 5 wt % Pt 3.1 SDS PCDTBT/PC 60 BM [20] 3 wt % Pt 105.2 / PFBT/PFODTBT/ITIC [22] 6 wt % Pt 60.8 PS-PEG-COOH PM6/ITCC-M [23] 10 wt % Pt 260 SDBS PM6/ITCC-M/IDMIC-4F [23] 10 wt % Pt 306 SDBS gIDTBT/oIDTBR [24] 10 wt % Pt 18.5 TEBS PM6/Y6 [25] 10 wt % Pt 43.9 TEBS PM6/PC 71 BM [25] 5 wt % Pt 73.7 TEBS PM6/BTP-4F [26] 15 wt % Pt 64.3 TEBS PM6/BTP-FOH [26] 15 wt % Pt 78.4 TEBS PM6/BTP-2OH [26] 15 wt % Pt 102.1 TEBS PM6/TPP [27] 20 wt % Pt 72.7 TEBS F1 [28] 33 wt % Pt 152.6 TEBS PM6/Y6CO [30] 33 wt % Pt 323.2 TEBS PM6/Y6-R [31] 16 wt % Pt 205 TEBS PM6/Y6-S [31] 16 wt % Pt 217 TEBS PBDB-T/ITIC [32] 10 wt % Pt 257 SDBS POZ-M/ITIC [33] 6 wt % Pt 63 PS-PEG-COOH…”

Section: Photosensitizers Catalystsmentioning

confidence: 99%

Emerging Light‐Harvesting Materials Based on Organic Photovoltaic D/A Heterojunctions for Efficient Photocatalytic Water Splitting

Guo,

Sun,

Guo

et al. 2024

Angew Chem Int Ed

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Photocatalytic water splitting to hydrogen is a highly promising method to meet the surging energy consumption globally through the environmentally friendly means. As the initial step before photocatalysis, harvesting photons from sunlight is crucially important, thus making the design of photosensitizers with visible even near‐infrared (NIR) absorptions get more and more attentions. In the past three years, organic donor/acceptor (D/A) heterojunctions with absorptions extending to 950 nm, have emerged as the new star light‐harvesting materials for photocatalytic water splitting, demonstrating exciting advantages over inorganic materials in solar light utilization, hydrogen yielding rate, etc. This Minireview firstly gives a brief discussion about the principle processes and determining factors for photocatalytic water splitting with organic photovoltaic D/A heterojunction as photosensitizers. Thereafter, the current progress is summarized in details by introducing typical and excellent D/A heterojunction‐based photocatalytic systems. Finally, not only the great prospects but also the most challenging issues confronted by organic D/A heterojunctions are indicated along with a perspective on the opportunities and new directions for future material explorations.

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Review on Fundamental and Recent Advances of Strain Engineering for Enhancing Photocatalytic CO₂ Reduction

Liu,

Hu,

Liu

et al. 2024

Advanced Energy Materials

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Photocatalytic carbon dioxide reduction reaction (CO2RR) is widely recognized as an attractive technology for simultaneously addressing environmental issues and energy crises. CO2RR encompasses three primary processes: electron‐hole generation, electron‐hole separation, and surface catalysis. Consequently, the light absorption capacity, charge separation ability, and selectivity of the surface catalytic site of the photocatalyst significantly influence the rate of CO2RR. The significant role of strain engineering in the photocatalytic reduction of carbon dioxide to solar fuel using semiconductor catalysts is reviewed in this paper. Specifically, the design strategies of strain catalysts and the crucial role of strain on CO2RR are examined. In this paper, the mechanisms of strain‐enhanced light absorption, photoelectron‐hole separation, and product selectivity are reviewed, along with the most recent advancements in this field. This review offers valuable information for the design of strain engineering photocatalysts and supplements the review of various semiconductor photocatalysts.

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Highly‐Active Chiral Organic Photovoltaic Catalysts with Suppressed Charge Recombination

Cited by 13 publications

References 69 publications

From light to hydrogen: the complete life cycle of free charges in photocatalytic nanoparticles

From light to hydrogen: the complete life cycle of free charges in photocatalytic nanoparticles

Emerging Light‐Harvesting Materials Based on Organic Photovoltaic D/A Heterojunctions for Efficient Photocatalytic Water Splitting

Review on Fundamental and Recent Advances of Strain Engineering for Enhancing Photocatalytic CO₂ Reduction

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Highly‐Active Chiral Organic Photovoltaic Catalysts with Suppressed Charge Recombination

Cited by 13 publications

References 69 publications

From light to hydrogen: the complete life cycle of free charges in photocatalytic nanoparticles

From light to hydrogen: the complete life cycle of free charges in photocatalytic nanoparticles

Emerging Light‐Harvesting Materials Based on Organic Photovoltaic D/A Heterojunctions for Efficient Photocatalytic Water Splitting

Review on Fundamental and Recent Advances of Strain Engineering for Enhancing Photocatalytic CO2 Reduction

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Review on Fundamental and Recent Advances of Strain Engineering for Enhancing Photocatalytic CO₂ Reduction