Side-chain tuning in conjugated polymer photocatalysts for improved hydrogen production from water

Woods, Duncan J.; Hillman, Sam A. J.; Pearce, Drew; Wilbraham, Liam; Flagg, Lucas Q.; Duffy, Warren; McCulloch, Iain; Durrant, James R.; Guilbert, Anne A. Y.; Zwijnenburg, Martijn A.; Sprick, Reiner Sebastian; Nelson, Jenny; Cooper, Andrew I.

doi:10.1039/d0ee01213k

Cited by 104 publications

(158 citation statements)

References 56 publications

(80 reference statements)

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“…This is in line with previous observations by Cooper et al. for hydrophilic sulfone containing polymer photocatalysts, [ 67–69 ] where wettability was identified as crucial parameter for electron transfer during proton reduction. Our study demonstrates that interfacial effects in general are a bottleneck reaction, i.e., hole extraction, which is also important to enable efficient charge carrier separation and with it, high HER rates.…”

Section: Resultssupporting

confidence: 93%

Interfacial Engineering for Improved Photocatalysis in a Charge Storing 2D Carbon Nitride: Melamine Functionalized Poly(heptazine imide)

Kröger

Jiménez‐Solano

Savaşçı

et al. 2020

Advanced Energy Materials

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Carbon nitrides constitute a class of earth‐abundant polymeric semiconductors, which have high potential for tunability on a molecular level, despite their high chemical and thermal inertness. Here the first postsynthetic modification of the 2D carbon nitride poly(heptazine imide) (PHI) is reported, which is decorated with terminal melamine (Mel) moieties by a functional group interconversion. The covalent attachment of this group is verified based with a suite of spectroscopic and microscopic techniques supported by quantum–chemical calculations. Using triethanolamine as a sacrificial electron donor, Mel‐PHI outperforms most other carbon nitrides in terms of hydrogen evolution rate (5570 µmol h−1 g−1), while maintaining the intrinsic light storing properties of PHI. The origin of the observed superior photocatalytic performance is traced back to a modified surface electronic structure and enhanced interfacial interactions with the amphiphile triethanolamine, which imparts improved colloidal stability to the catalyst particles especially in contrast to methanol used as donor. However, this high activity can be limited by oxidation products of donor reversibly building up at the surface, thus blocking active centers. The findings lay out the importance of surface functionalization to engineer the catalyst–solution interface, an underappreciated tuning parameter in photocatalytic reaction design.

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Section: Resultssupporting

confidence: 93%

Interfacial Engineering for Improved Photocatalysis in a Charge Storing 2D Carbon Nitride: Melamine Functionalized Poly(heptazine imide)

Kröger

Jiménez‐Solano

Savaşçı

et al. 2020

Advanced Energy Materials

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“…Previously, we showed that this approach yields results comparable to those measured using photoelectron spectroscopy, at least for amorphous polymers. 54,60 The results of these calculations (Fig. 3d), suggest for MeF1-MeF3 and S1-S3 that with increasing oligomer length the IP becomes less positive and EA less negative, and hence the driving force for triethylamine/Na 2 SO 3 /Na 2 S oxidation and proton reduction decreases with oligomer length.…”

Section: Driving Force Calculationsmentioning

confidence: 92%

Structure–activity relationships in well-defined conjugated oligomer photocatalysts for hydrogen production from water

et al. 2020

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“…18,22,23 The dispersability of a polymer probably depends both on the size (distribution) of the polymer particles in suspension and the inherent wettability of the polymer or the sidegroups present. 24,25 Our empirical observations are in line with a classical semiconductor microscopic model where the exciton formed through the absorption of light either (i) spontaneously falls apart and the free electron and hole formed in the process reduce protons/SEA and oxidise water/SED, respectively, or, more likely due to the large exciton binding energy relative to k B T in polymers, (ii) drives one of the two solution half-reactions and the remaining free-electron/hole the other. 26,27 Transient spectroscopy of polymers under hydrogen evolution conditions 25,28 indeed suggest the presence of electron polarons, i.e.…”

Section: Introductionmentioning

confidence: 99%

Hydrogen evolution by polymer photocatalysts; a possible photocatalytic cycle

Prentice

Zwijnenburg

2021

Sustainable Energy Fuels

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Side-chain tuning in conjugated polymer photocatalysts for improved hydrogen production from water

Abstract: Structure–property–activity relationships in solution processable polymer photocatalysts for hydrogen production from water were probed by varying the chemical structure of both the polymer side-chains and the polymer backbone.

Cited by 104 publications

References 56 publications

Interfacial Engineering for Improved Photocatalysis in a Charge Storing 2D Carbon Nitride: Melamine Functionalized Poly(heptazine imide)

Interfacial Engineering for Improved Photocatalysis in a Charge Storing 2D Carbon Nitride: Melamine Functionalized Poly(heptazine imide)

Structure–activity relationships in well-defined conjugated oligomer photocatalysts for hydrogen production from water

Hydrogen evolution by polymer photocatalysts; a possible photocatalytic cycle

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