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Search for "photocatalytic hydrogen evolution" in Full Text gives 3 result(s) in Beilstein Journal of Organic Chemistry.
Catalysing (organo-)catalysis: Trends in the application of machine learning to enantioselective organocatalysis
- Stefan P. Schmid,
- Leon Schlosser,
- Frank Glorius and
- Kjell Jorner
Beilstein J. Org. Chem. 2024, 20, 2280–2304, doi:10.3762/bjoc.20.196
Graphical Abstract
Figure 1: Schematic depiction of available data sources for predictive modelling, each with its advantages an...
Figure 2: Schematic depiction of different kinds of molecular representations for fluoronitroethane. Among th...
Figure 3: Depiction of the energy diagram of a generic enantioselective reaction. In the centre, catalyst and...
Figure 4: Hammett parameters are derived from the equilibrium constant of substituted benzoic acids (example ...
Figure 5: Selected examples of popular descriptors applied to model organocatalytic reactions. Descriptors en...
Figure 6: Example bromocyclization reaction from Toste and co-workers using a DABCOnium catalyst system and C...
Figure 7: Example from Neel et al. using a chiral ion pair catalyst for the selective fluorination of allylic...
Figure 8: Data set created by Denmark and co-workers for the CPA-catalysed thiol addition to N-acylimines [67]. T...
Figure 9: Selected examples of ML developments that used the dataset from Denmark and co-workers [67]. (A) Varnek...
Figure 10: Study from Reid and Sigman developing statistical models for CPA-catalysed nucleophilic addition re...
Figure 11: Selected examples of studies where mechanistic transferability was exploited to model multiple reac...
Figure 12: Generality approach by Denmark and co-workers [132] for the iodination of arylpyridines. From the releva...
Figure 13: Betinol et al. [133] clustered the relevant chemical space and then evaluated the average ee for every c...
Figure 14: Corminboeuf and co-workers [134] chose a representative subset of the reaction space (indicated by dark ...
Figure 15: Example for data-driven modelling to improve substrate and catalyst design. (A) C–N coupling cataly...
Figure 16: Example for utilising a genetic algorithm for catalyst design. (A) Morita–Baylis–Hillman reaction s...
Figure 17: Organocatalysed synthesis of spirooxindole analogues by Kondo et al. [171] (A) Reaction scheme of dienon...
Figure 18: Schematic depiction of required developments in order to overcome current limitations of ML for org...
Optimizing reaction conditions for the light-driven hydrogen evolution in a loop photoreactor
- Pengcheng Li,
- Daniel Kowalczyk,
- Johannes Liessem,
- Mohamed M. Elnagar,
- Dariusz Mitoraj,
- Radim Beranek and
- Dirk Ziegenbalg
Beilstein J. Org. Chem. 2024, 20, 74–91, doi:10.3762/bjoc.20.9
- be applied. Notably, the loop photoreactor demonstrated an external photon efficiency up to 17 times higher than reported in literature studies, while scaling the reactor size by a factor of 10. Keywords: loop photoreactor; parametric study; photocatalytic hydrogen evolution; polymeric carbon
- hydrogen generation is designed and equipped with 365 nm LEDs. Fluid dynamics in the loop photoreactor are characterized using a color tracer mixing experiment and image analysis. Photonic characterization is performed with the ferrioxalate actinometer. Finally, the photocatalytic hydrogen evolution with
- paths, where consequently the requirements for the application of the Beer–Lambert law are not fulfilled anymore. Considering the inner diameter of the loop reactor of 5 cm, a catalyst loading of 0.11 g L−1 is sufficient to absorb more than 95% of the photons. Photocatalytic hydrogen evolution Long-term
Graphical Abstract
Scheme 1: Photocatalytic hydrogen evolution with Pt-loaded polymeric carbon nitride.
Figure 1: SEM images of the Pt-PCN photocatalyst at different magnifications.
Figure 2: SEM-EDX elemental mapping images of C, N, and Pt on a particle.
Figure 3: Exemplary results of the mixing experiments using methylene blue to visualize and quantify fluid fl...
Figure 4: Red channel values of ROIs with different stirring speeds: (a) left space between reactor and draft...
Figure 5: Quantified mixing time using different stirring speeds.
Figure 6: Chemical actinometry results: (a) actinometer conversion at different irradiation time, (b) photon ...
Figure 7: Photon flux in the loop reactor with respect to the LED electrical current.
Figure 8: Absorbance as function of photocatalyst loading for different optical path lengths.
Figure 9: Long-term operation of the loop photoreactor.
Figure 10: Visualization of the response surfaces of the modified DOE model for the four parameters: (a) photo...
Figure 11: Parity plot of the measured photocatalytic hydrogen generation rate versus the values predicted by ...
Figure 12: Effect of photon flux on hydrogen generation rate: (a) hydrogen generation rate as function of the ...
Figure 13: Effect of inert gas flow rate on hydrogen generation rate: (a) hydrogen generation rate as a functi...
Figure 14: Effect of photocatalyst loading on the hydrogen generation rate: (a) hydrogen generation rate as fu...
Figure 15: Effect of stirring speed on hydrogen generation rate: (a) hydrogen generation rate as function of i...
Figure 16: 3D plot of AQE for different studied parameters: (a) AQE for different photon fluxes and inert gas ...
Figure 17: Reactor design: (a) CAD drawing of the loop reactor, (b) picture of the manufactured loop reactor.
Figure 18: Assembled reactor and 3D printed parts: (a) the whole reactor setup, (b) 3D printed propellers.
Figure 19: Photocatalytic reaction setup: (a) reaction setup flow diagram, (b) reaction setup in lab. 1 argon ...
Heterogeneous photocatalysis in flow chemical reactors
- Christopher G. Thomson,
- Ai-Lan Lee and
- Filipe Vilela
Beilstein J. Org. Chem. 2020, 16, 1495–1549, doi:10.3762/bjoc.16.125
- temperature to yield alkyl, halo, and trifluoromethyl products, such as the examples 5 and 6 (Scheme 2). Chen, Wang and co-workers recently studied methods to reduce the exciton binding energy in linear conjugated polymers to enhance the charge separation and subsequent photocatalytic hydrogen evolution
- (Figure 11) [129]. Four conjugated polymers containing dibenzothiophene sulfone (FSO) monomers, linked by either biphenyl (FSO-BP), fluorene (FSO-F), 2,8-dibenzothiophene (FSO-FSz), or 3,7-dibenzothiophene (FSO-FS) monomers were synthesised and applied in the photocatalytic hydrogen evolution reaction
Graphical Abstract
Figure 1: A) Bar chart of the publications per year for the topics “Photocatalysis” (49,662 instances) and “P...
Figure 2: A) Professor Giacomo Ciamician and Dr. Paolo Silber on their roof laboratory at the University of B...
Scheme 1: PRC trifluoromethylation of N-methylpyrrole (1) using hazardous gaseous CF3I safely in a flow react...
Figure 3: A) Unit cells of the three most common crystal structures of TiO2: rutile, brookite, and anatase. R...
Figure 4: Illustration of the key semiconductor photocatalysis events: 1) A photon with a frequency exceeding...
Figure 5: Photocatalytic splitting of water by oxygen vacancies on a TiO2(110) surface. Reprinted with permis...
Figure 6: Proposed adsorption modes of A) benzene, B) chlorobenzene, C) toluene, D) phenol, E) anisole, and F...
Figure 7: Structures of the sulfonate-containing organic dyes RB5 (3) and MX-5B (4) and the adsorption isothe...
Figure 8: Idealised triclinic unit cell of a g-C3N4 type polymer, displaying possible hopping transport scena...
Figure 9: Idealised structure of a perfect g-C3N4 sheet. The central unit highlighted in red represents one t...
Figure 10: Timeline of the key processes of charge transport following the photoexcitation of g-C3N4, leading ...
Scheme 2: Photocatalytic bifunctionalisation of heteroarenes using mpg-C3N4, with the selected examples 5 and ...
Figure 11: A) Structure of four linear conjugated polymer photocatalysts for hydrogen evolution, displaying th...
Figure 12: Graphical representation of the common methods used to immobilise molecular photocatalysts (PC) ont...
Figure 13: Wireless light emitter-supported TiO2 (TiO2@WLE) HPCat spheres powered by resonant inductive coupli...
Figure 14: Graphical representation of zinc–perylene diimide (Zn-PDI) supramolecular assembly photocatalysis v...
Scheme 3: Upconversion of NIR photons to the UV frequency by NaYF4:Yb,Tm nanocrystals sequentially coated wit...
Figure 15: Types of reactors employed in heterogeneous photocatalysis in flow. A) Fixed bed reactors and the s...
Figure 16: Electrochemical potential of common semiconductor, transition metal, and organic dye-based photocat...
Scheme 4: Possible mechanisms of an immobilised molecular photoredox catalyst by oxidative or reductive quenc...
Scheme 5: Scheme of the CMB-C3N4 photocatalytic decarboxylative fluorination of aryloxyacetic acids, with the...
Scheme 6: Scheme of the g-C3N4 photocatalytic desilylative coupling reaction in flow and proposed mechanism [208].
Scheme 7: Proposed mechanism of the radical cyclisation of unsaturated alkyl 2-bromo-1,3-dicarbonyl compounds...
Scheme 8: N-alkylation of benzylamine and schematic of the TiO2-coated microfluidic device [213].
Scheme 9: Proposed mechanism of the Pt@TiO2 photocatalytic deaminitive cyclisation of ʟ-lysine (23) to ʟ-pipe...
Scheme 10: A) Proposed mechanism for the photocatalytic oxidation of phenylboronic acid (24). B) Photos and SE...
Scheme 11: Proposed mechanism for the DA-CMP3 photocatalytic aza-Henry reaction performed in a continuous flow...
Scheme 12: Proposed mechanism for the formation of the cyclic product 32 by TiO2-NC HPCats in a slurry flow re...
Scheme 13: Reaction scheme for the photocatalytic synthesis of homo and hetero disulfides in flow and scope of...
Scheme 14: Reaction scheme for the MoOx/TiO2 HPCat oxidation of cyclohexane (34) to benzene. The graph shows t...
Scheme 15: Proposed mechanism of the TiO2 HPC heteroarene C–H functionalisation via aryl radicals generated fr...
Scheme 16: Scheme of the oxidative coupling of benzylamines with the HOTT-HATN HPCat and selected examples of ...
Scheme 17: Photocatalysis oxidation of benzyl alcohol (40) to benzaldehyde (41) in a microflow reactor coated ...
Figure 17: Mechanisms of Dexter and Forster energy transfer.
Scheme 18: Continuous flow process for the isomerisation of alkenes with an ionic liquid-immobilised photocata...
Scheme 19: Singlet oxygen synthetic step in the total synthesis of canataxpropellane [265].
Scheme 20: Scheme and proposed mechanism of the singlet oxygen photosensitisation by CMP_X HPCats, with the st...
Scheme 21: Structures of CMP HPCat materials applied by Vilela and co-workers for the singlet oxygen photosens...
Scheme 22: Polyvinylchloride resin-supported TDCPP photosensitisers applied for singlet oxygen photosensitisat...
Scheme 23: Structure of the ionically immobilised TPP photosensitiser on amberlyst-15 ion exchange resins (TPP...
Scheme 24: Photosensitised singlet oxygen oxidation of citronellol (46) in scCO2, with automatic phase separat...
Scheme 25: Schematic of PS-Est-BDP-Cl2 being applied for singlet oxygen photosensitisation in flow. A) Pseudo-...
Scheme 26: Reaction scheme of the singlet oxygen oxidation of furoic acid (54) using a 3D-printed microfluidic...
Figure 18: A) Photocatalytic bactericidal mechanism by ROS oxidative cleavage of membrane lipids (R = H, amino...
Figure 19: A) Suggested mechanisms for the aqueous pollutant degradation by TiO2 in a slurry flow reactor [284-287]. B)...
Figure 20: Schematic of the flow system used for the degradation of aqueous oxytetracycline (56) solutions [215]. M...
Scheme 27: Degradation of a salicylic acid (57) solution by a coupled solar photoelectro-Fenton (SPEF) process...
Figure 21: A) Schematic flow diagram using the TiO2-coated NETmix microfluidic device for an efficient mass tr...
