Your search keyword '"Sprick, Reiner Sebastian"' showing total 16 results

1. Conjugated Polymer/Recombinant Escherichia coliBiohybrid Systems for Photobiocatalytic Hydrogen Production

Author

Yang, Ying, Zwijnenburg, Martijn A., Gardner, Adrian M., Adamczyk, Sylwia, Yang, Jing, Sun, Yaqi, Jiang, Qiuyao, Cowan, Alexander J., Sprick, Reiner Sebastian, Liu, Lu-Ning, and Cooper, Andrew I.

Abstract

Biohybrid photocatalysts are composite materials that combine the efficient light-absorbing properties of synthetic materials with the highly evolved metabolic pathways and self-repair mechanisms of biological systems. Here, we show the potential of conjugated polymers as photosensitizers in biohybrid systems by combining a series of polymer nanoparticles with engineered Escherichia colicells. Under simulated solar light irradiation, the biohybrid system consisting of fluorene/dibenzo [b,d]thiophene sulfone copolymer (LP41) and recombinant E. coli(i.e., a LP41/HydA BL21 biohybrid) shows a sacrificial hydrogen evolution rate of 3.442 mmol g–1h–1(normalized to polymer amount). It is over 30 times higher than the polymer photocatalyst alone (0.105 mmol g–1h–1), while no detectable hydrogen was generated from the E. colicells alone, demonstrating the strong synergy between the polymer nanoparticles and bacterial cells. The differences in the physical interactions between synthetic materials and microorganisms, as well as redox energy level alignment, elucidate the trends in photochemical activity. Our results suggest that organic semiconductors may offer advantages, such as solution processability, low toxicity, and more tunable surface interactions with the biological components over inorganic materials.

Published

2024

2. Processing polymer photocatalysts for photocatalytic hydrogen evolution

Author

Lyons, Richard Jack and Sprick, Reiner Sebastian

Abstract

Conjugated materials have emerged as competitive photocatalysts for the production of sustainable hydrogen from water over the last decade. Interest in these polymer photocatalysts stems from the relative ease to tune their electronic properties through molecular engineering, and their potentially low cost. However, most polymer photocatalysts have only been utilised in rudimentary suspension-based photocatalytic reactors, which are not scalable as these systems can suffer from significant optical losses and often require constant agitation to maintain the suspension. Here, we will explore research performed to utilise polymeric photocatalysts in more sophisticated systems, such as films or as nanoparticulate suspensions, which can enhance photocatalytic performance or act as a demonstration of how the polymer can be scaled for real-world applications. We will also discuss how the systems were prepared and consider both the benefits and drawbacks of each system before concluding with an outlook on the field of processable polymer photocatalysts.

Published

2024

3. Reconstructed covalent organic frameworks

Author

Zhang, Weiwei, Chen, Linjiang, Dai, Sheng, Zhao, Chengxi, Ma, Cheng, Wei, Lei, Zhu, Minghui, Chong, Samantha Y., Yang, Haofan, Liu, Lunjie, Bai, Yang, Yu, Miaojie, Xu, Yongjie, Zhu, Xiao-Wei, Zhu, Qiang, An, Shuhao, Sprick, Reiner Sebastian, Little, Marc A., Wu, Xiaofeng, Jiang, Shan, Wu, Yongzhen, Zhang, Yue-Biao, Tian, He, Zhu, Wei-Hong, and Cooper, Andrew I.

Abstract

Covalent organic frameworks (COFs) are distinguished from other organic polymers by their crystallinity1–3, but it remains challenging to obtain robust, highly crystalline COFs because the framework-forming reactions are poorly reversible4,5. More reversible chemistry can improve crystallinity6–9, but this typically yields COFs with poor physicochemical stability and limited application scope5. Here we report a general and scalable protocol to prepare robust, highly crystalline imine COFs, based on an unexpected framework reconstruction. In contrast to standard approaches in which monomers are initially randomly aligned, our method involves the pre-organization of monomers using a reversible and removable covalent tether, followed by confined polymerization. This reconstruction route produces reconstructed COFs with greatly enhanced crystallinity and much higher porosity by means of a simple vacuum-free synthetic procedure. The increased crystallinity in the reconstructed COFs improves charge carrier transport, leading to sacrificial photocatalytic hydrogen evolution rates of up to 27.98 mmol h−1g−1. This nanoconfinement-assisted reconstruction strategy is a step towards programming function in organic materials through atomistic structural control.

Published

2022

4. Covalent triazine-based frameworks with cobalt-loading for visible light-driven photocatalytic water oxidationElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d2cy00773h

Author

Chen, Hongmei, Gardner, Adrian M., Lin, Guoan, Zhao, Wei, Bahri, Mounib, Browning, Nigel D., Sprick, Reiner Sebastian, Li, Xiaobo, Xu, Xiaoxiang, and Cooper, Andrew I.

Abstract

Conjugated polymers have received significant attention as photocatalysts. However, photocatalytic oxygen evolution has only been reported for a few polymers so far. Here, we present a bipyridine based covalent triazine-based framework containing metal coordination sites (Bpy-CTF). The material is highly active for sacrificial photocatalytic oxygen evolution with a rate of 322 μmol g−1h−1under visible light illumination (≥420 nm) after post-synthetic cobalt coordination. An analogous photocatalyst containing biphenyl was found to be less active as it is not able to coordinate cobalt. Transient absorption spectroscopy studies showed that the cobalt coordinated in the bipyridine units of Bpy-CTF promotes charge separation and transfer, thus increasing water oxidation activity. The study demonstrates the growing potential of polymer photocatalysts for oxygen evolution by structural engineering and post-synthetic metalation.

Published

2022

5. Rational design of covalent organic frameworks for efficient photocatalytic hydrogen peroxide productionElectronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d2en00135g

Author

Chai, Shuming, Chen, Xiaowen, Zhang, Xirui, Fang, Yuanxing, Sprick, Reiner Sebastian, and Chen, Xiong

Abstract

Hydrogen peroxide (H2O2) is an important chemical for environmental applications and also used in large-scale industrial processes. Recent studies have demonstrated photocatalytic production of H2O2, but the observed production rates are low, making the materials unpractical for applications at scale. Herein, covalent organic frameworks (COFs) have been studied as photocatalysts for H2O2production. Two related COFs show markedly different performances, which can be explained by the presence of donor–acceptor configurations in the backbone. N0-COF has increased charge-separation efficiencies and a better band alignment compared to its nitrogen containing analogue N3-COF. The result is that N0-COF has a H2O2production rate of 15.7 μmol h−1for 10 mg, which is ten times higher compared to N3-COF. In this study, both experimental and theoretical studies have been used to understand the improved performance. This study reveals the importance of the backbone design of metal-free materials for advanced photocatalytic applications.

Published

2022

6. Probing Dynamics of Water Mass Transfer in Organic Porous Photocatalyst Water-Splitting Materials by Neutron Spectroscopy

Author

Zbiri, Mohamed, Aitchison, Catherine M., Sprick, Reiner Sebastian, Cooper, Andrew I., and Guilbert, Anne A. Y.

Abstract

The quest for efficient and economically accessible cleaner methods to develop sustainable carbon-free energy sources induced a keen interest in the production of hydrogen fuel. This can be achieved via the water-splitting process and by exploiting solar energy. However, the use of adequate photocatalysts is required to reach this goal. Covalent triazine-based frameworks (CTFs) are potential target photocatalysts for water splitting. Both electronic and structural characteristics of CTFs, particularly energy levels, optical band gaps, and porosities are directly relevant to water splitting and can be engineered through chemical design. Porosity can, in principle, be beneficial to water splitting by providing a larger surface area for the catalytic reactions to take place. However, porosity can also affect both charge transport within the photocatalyst and mass transfer of both reactants and products, thus impacting the overall kinetics of the reaction. Here, we focus on the link between chemical design and water (reactant) mass transfer, which plays a key role in the water uptake process and the subsequent hydrogen generation in practice. We use neutron spectroscopy to study the mass transfer of water in two porous CTFs, CTF-CN and CTF-2, that differ in the polarity of their struts. Quasi-elastic neutron scattering is used to quantify the amount of bound water and the translational diffusion of water. Inelastic neutron scattering measurements complement the quasi-elastic neutron scattering study and provide insights into the softness of the CTF structures and the changes in librational degrees of freedom of water in the porous CTFs. We show that two different types of interaction between water and CTFs take place in CTF-CN and CTF-2. CTF-CN exhibits a smaller surface area and lower water uptake due to its softer structure than CTF-2. However, the polar cyano group interacts locally with water leading to a large amount of bound water and a strong rearrangement of the water hydration monolayer, while water diffusion in CTF-2 is principally impacted by microporosity. The current study leads to new insights into the structure-dynamics–property relationship of CTF photocatalysts that pave the road for a better understanding of the guest–host interaction on the basis of water-splitting applications.

Published

2021

7. Covalent Organic Framework Nanosheets Embedding Single Cobalt Sites for Photocatalytic Reduction of Carbon Dioxide

Author

Wang, Xiaoyan, Fu, Zhiwei, Zheng, Lirong, Zhao, Chengxi, Wang, Xue, Chong, Samantha Y., McBride, Fiona, Raval, Rasmita, Bilton, Matthew, Liu, Lunjie, Wu, Xiaofeng, Chen, Linjiang, Sprick, Reiner Sebastian, and Cooper, Andrew I.

Abstract

Covalent organic framework nanosheets (CONs), fabricated from two-dimensional covalent organic frameworks (COFs), present a promising strategy for incorporating atomically distributed catalytic metal centers into well-defined pore structures with desirable chemical environments. Here, a series of CONs was synthesized by embedding single cobalt sites that were then evaluated for photocatalytic carbon dioxide reduction. A partially fluorinated, cobalt-loaded CON produced 10.1 μmol carbon monoxide with a selectivity of 76%, over 6 hours irradiation under visible light (TON = 28.1), and a high external quantum efficiency (EQE) of 6.6% under 420 nm irradiation in the presence of an iridium dye. The CONs appear to act as a semiconducting support, facilitating charge carrier transfer between the dye and the cobalt centers, and this results in a performance comparable with that of the state-of-the-art heterogeneous catalysts in the literature under similar conditions. The ultrathin CONs outperformed their bulk counterparts in all cases, suggesting a general strategy to enhance the photocatalytic activities of COF materials.

Published

2020

8. Tracking Charge Transfer to Residual Metal Clusters in Conjugated Polymers for Photocatalytic Hydrogen Evolution

Author

Sachs, Michael, Cha, Hyojung, Kosco, Jan, Aitchison, Catherine M., Francàs, Laia, Corby, Sacha, Chiang, Chao-Lung, Wilson, Anna A., Godin, Robert, Fahey-Williams, Alexander, Cooper, Andrew I., Sprick, Reiner Sebastian, McCulloch, Iain, and Durrant, James R.

Abstract

Semiconducting polymers are versatile materials for solar energy conversion and have gained popularity as photocatalysts for sunlight-driven hydrogen production. Organic polymers often contain residual metal impurities such as palladium (Pd) clusters that are formed during the polymerization reaction, and there is increasing evidence for a catalytic role of such metal clusters in polymer photocatalysts. Using transient and operando optical spectroscopy on nanoparticles of F8BT, P3HT, and the dibenzo[b,d]thiophene sulfone homopolymer P10, we demonstrate how differences in the time scale of electron transfer to Pd clusters translate into hydrogen evolution activity optima at different residual Pd concentrations. For F8BT nanoparticles with common Pd concentrations of >1000 ppm (>0.1 wt %), we find that residual Pd clusters quench photogenerated excitons via energy and electron transfer on the femto-nanosecond time scale, thus outcompeting reductive quenching. We spectroscopically identify reduced Pd clusters in our F8BT nanoparticles from the microsecond time scale onward and show that the predominant location of long-lived electrons gradually shifts to the F8BT polymer when the Pd content is lowered. While a low yield of long-lived electrons limits the hydrogen evolution activity of F8BT, P10 exhibits a substantially higher hydrogen evolution activity, which we demonstrate results from higher yields of long-lived electrons due to more efficient reductive quenching. Surprisingly, and despite the higher performance of P10, long-lived electrons reside on the P10 polymer rather than on the Pd clusters in P10 particles, even at very high Pd concentrations of 27000 ppm (2.7 wt %). In contrast, long-lived electrons in F8BT already reside on Pd clusters before the typical time scale of hydrogen evolution. This comparison shows that P10 exhibits efficient reductive quenching but slow electron transfer to residual Pd clusters, whereas the opposite is the case for F8BT. These findings suggest that the development of even more efficient polymer photocatalysts must target materials that combine both rapid reductive quenching and rapid charge transfer to a metal-based cocatalyst.

Published

2020

9. A mobile robotic chemist

Author

Burger, Benjamin, Maffettone, Phillip M., Gusev, Vladimir V., Aitchison, Catherine M., Bai, Yang, Wang, Xiaoyan, Li, Xiaobo, Alston, Ben M., Li, Buyi, Clowes, Rob, Rankin, Nicola, Harris, Brandon, Sprick, Reiner Sebastian, and Cooper, Andrew I.

Abstract

Technologies such as batteries, biomaterials and heterogeneous catalysts have functions that are defined by mixtures of molecular and mesoscale components. As yet, this multi-length-scale complexity cannot be fully captured by atomistic simulations, and the design of such materials from first principles is still rare1–5. Likewise, experimental complexity scales exponentially with the number of variables, restricting most searches to narrow areas of materials space. Robots can assist in experimental searches6–14but their widespread adoption in materials research is challenging because of the diversity of sample types, operations, instruments and measurements required. Here we use a mobile robot to search for improved photocatalysts for hydrogen production from water15. The robot operated autonomously over eight days, performing 688 experiments within a ten-variable experimental space, driven by a batched Bayesian search algorithm16–18. This autonomous search identified photocatalyst mixtures that were six times more active than the initial formulations, selecting beneficial components and deselecting negative ones. Our strategy uses a dexterous19,20free-roaming robot21–24, automating the researcher rather than the instruments. This modular approach could be deployed in conventional laboratories for a range of research problems beyond photocatalysis.

Published

2020

10. Structurally Diverse Covalent Triazine-Based Framework Materials for Photocatalytic Hydrogen Evolution from Water

Author

Meier, Christian B., Clowes, Rob, Berardo, Enrico, Jelfs, Kim E., Zwijnenburg, Martijn A., Sprick, Reiner Sebastian, and Cooper, Andrew I.

Abstract

A structurally diverse family of 39 covalent triazine-based framework materials (CTFs) are synthesized by Suzuki–Miyaura polycondensation and tested as hydrogen evolution photocatalysts using a high-throughput workflow. The two best-performing CTFs are based on benzonitrile and dibenzo[b,d]thiophene sulfone linkers, respectively, with catalytic activities that are among the highest for this material class. The activities of the different CTFs are rationalized in terms of four variables: the predicted electron affinity, the predicted ionization potential, the optical gap, and the dispersibility of the CTFs particles in solution, as measured by optical transmittance. The electron affinity and dispersibility in solution are found to be the best predictors of photocatalytic hydrogen evolution activity.

Published

2019

11. Accelerated Discovery of Organic Polymer Photocatalysts for Hydrogen Evolution from Water through the Integration of Experiment and Theory

Author

Bai, Yang, Wilbraham, Liam, Slater, Benjamin J., Zwijnenburg, Martijn A., Sprick, Reiner Sebastian, and Cooper, Andrew I.

Abstract

Conjugated polymers are an emerging class of photocatalysts for hydrogen production where the large breadth of potential synthetic diversity presents both an opportunity and a challenge. Here, we integrate robotic experimentation with high-throughput computation to navigate the available structure–property space. A total of 6354 co-polymers was considered computationally, followed by the synthesis and photocatalytic characterization of a sub-library of more than 170 co-polymers. This led to the discovery of new polymers with sacrificial hydrogen evolution rates (HERs) of more than 6 mmol g–1h–1. The variation in HER across the library does not correlate strongly with any single physical property, but a machine-learning model involving four separate properties can successfully describe up to 68% of the variation in the HER data between the different polymers. The four variables used in the model were the predicted electron affinity, the predicted ionization potential, the optical gap, and the dispersibility of the polymer particles in solution, as measured by optical transmittance.

Published

2019

12. Photocatalytic Hydrogen Evolution from Water Using Fluorene and Dibenzothiophene Sulfone-Conjugated Microporous and Linear Polymers

Author

Sprick, Reiner Sebastian, Bai, Yang, Guilbert, Anne A. Y., Zbiri, Mohamed, Aitchison, Catherine M., Wilbraham, Liam, Yan, Yong, Woods, Duncan J., Zwijnenburg, Martijn A., and Cooper, Andrew I.

Abstract

Three series of conjugated microporous polymers (CMPs) were studied as photocatalysts for hydrogen production from water using a sacrificial hole scavenger. In all cases, dibenzo[b,d]thiophene sulfone polymers outperformed their fluorene analogues. A porous network, S-CMP3, showed the highest hydrogen evolution rates of 6076 μmol h–1g–1(λ > 295 nm) and 3106 μmol h–1g–1(λ > 420 nm), with an external quantum efficiency of 13.2% at 420 nm. S-CMP3 outperforms its linear structural analogue, P35, whereas in other cases, nonporous linear polymers are superior to equivalent porous networks. This suggests that microporosity might be beneficial for sacrificial photocatalytic hydrogen evolution, if suitable linkers are used that do not limit charge transport and the material can be wetted by water as studied here by water sorption and quasi-elastic neutron scattering.

Published

2019

13. Sulfone-containing covalent organic frameworks for photocatalytic hydrogen evolution from water

Author

Wang, Xiaoyan, Chen, Linjiang, Chong, Samantha Y., Little, Marc A., Wu, Yongzhen, Zhu, Wei-Hong, Clowes, Rob, Yan, Yong, Zwijnenburg, Martijn A., Sprick, Reiner Sebastian, and Cooper, Andrew I.

Abstract

Nature uses organic molecules for light harvesting and photosynthesis, but most man-made water splitting catalysts are inorganic semiconductors. Organic photocatalysts, while attractive because of their synthetic tunability, tend to have low quantum efficiencies for water splitting. Here we present a crystalline covalent organic framework (COF) based on a benzo-bis(benzothiophene sulfone) moiety that shows a much higher activity for photochemical hydrogen evolution than its amorphous or semicrystalline counterparts. The COF is stable under long-term visible irradiation and shows steady photochemical hydrogen evolution with a sacrificial electron donor for at least 50?hours. We attribute the high quantum efficiency of fused-sulfone-COF to its crystallinity, its strong visible light absorption, and its wettable, hydrophilic 3.2?nm mesopores. These pores allow the framework to be dye-sensitized, leading to a further 61% enhancement in the hydrogen evolution rate up to 16.3?mmol?g-1?h-1. The COF also retained its photocatalytic activity when cast as a thin film onto a support.

Published

2018

14. Nitrogen Containing Linear Poly(phenylene) Derivatives for Photo-catalytic Hydrogen Evolution from Water

Author

Sprick, Reiner Sebastian, Wilbraham, Liam, Bai, Yang, Guiglion, Pierre, Monti, Adriano, Clowes, Rob, Cooper, Andrew I., and Zwijnenburg, Martijn A.

Abstract

Here we study how the introduction of nitrogen into poly(p-phenylene) type materials affects their ability to act as hydrogen evolution photocatalysts. Direct photocatalytic water splitting is an attractive strategy for clean energy production, but understanding which material properties are important, how they interplay, and how they can be influenced through doping remains a significant challenge, especially for polymers. Using a combined experimental and computational approach, we demonstrate that introducing nitrogen in conjugated polymers results in either materials that absorb significantly  more visible  light but worse predicted driving force for water/sacrificial electron donor oxidation, or materials with an improved driving force that absorb  relatively less visible light. The latter materials are found to be much more active and the former much less. The trade-off between properties highlights that the optimization of a single property in isolation is a poor strategy for improving the overall activity of materials.

Published

2018

15. Why Do Sulfone-Containing Polymer Photocatalysts Work So Well for Sacrificial Hydrogen Evolution from Water?

Author

Hillman, Sam A. J., Sprick, Reiner Sebastian, Pearce, Drew, Woods, Duncan J., Sit, Wai-Yu, Shi, Xingyuan, Cooper, Andrew I., Durrant, James R., and Nelson, Jenny

Abstract

Many of the highest-performing polymer photocatalysts for sacrificial hydrogen evolution from water have contained dibenzo[b,d]thiophene sulfone units in their polymer backbones. However, the reasons behind the dominance of this building block are not well understood. We study films, dispersions, and solutions of a new set of solution-processable materials, where the sulfone content is systematically controlled, to understand how the sulfone unit affects the three key processes involved in photocatalytic hydrogen generation in this system: light absorption; transfer of the photogenerated hole to the hole scavenger triethylamine (TEA); and transfer of the photogenerated electron to the palladium metal co-catalyst that remains in the polymer from synthesis. Transient absorption spectroscopy and electrochemical measurements, combined with molecular dynamics and density functional theory simulations, show that the sulfone unit has two primary effects. On the picosecond timescale, it dictates the thermodynamics of hole transfer out of the polymer. The sulfone unit attracts water molecules such that the average permittivity experienced by the solvated polymer is increased. We show that TEA oxidation is only thermodynamically favorable above a certain permittivity threshold. On the microsecond timescale, we present experimental evidence that the sulfone unit acts as the electron transfer site out of the polymer, with the kinetics of electron extraction to palladium dictated by the ratio of photogenerated electrons to the number of sulfone units. For the highest-performing, sulfone-rich material, hydrogen evolution seems to be limited by the photogeneration rate of electrons rather than their extraction from the polymer.

Published

2022

16. Correction to “Tracking Charge Transfer to Residual Metal Clusters in Conjugated Polymers for Photocatalytic Hydrogen Evolution”

Author

Sachs, Michael, Cha, Hyojung, Kosco, Jan, Aitchison, Catherine M., Francàs, Laia, Corby, Sacha, Chiang, Chao-Lung, Wilson, Anna A., Godin, Robert, Fahey-Williams, Alexander, Cooper, Andrew I., Sprick, Reiner Sebastian, McCulloch, Iain, and Durrant, James R.

Published

2021