Extraction of the intrinsic rate constant for a photocyclization reaction in capillary microreactors using a simplified reactor model
Li, Jun
1; Šimek Tosino, Helena 2; Ladewig, Bradley P.; Jung, Nicole 2,3; Bräse, Stefan 2,3; Dittmeyer, Roland 1
1 Institut für Mikroverfahrenstechnik (IMVT), Karlsruher Institut für Technologie (KIT)
2 Institut für Biologische und Chemische Systeme (IBCS), Karlsruher Institut für Technologie (KIT)
3 Institut für Organische Chemie (IOC), Karlsruher Institut für Technologie (KIT)
1; Šimek Tosino, Helena 2; Ladewig, Bradley P.; Jung, Nicole 2,3; Bräse, Stefan 2,3; Dittmeyer, Roland 11 Institut für Mikroverfahrenstechnik (IMVT), Karlsruher Institut für Technologie (KIT)
2 Institut für Biologische und Chemische Systeme (IBCS), Karlsruher Institut für Technologie (KIT)
3 Institut für Organische Chemie (IOC), Karlsruher Institut für Technologie (KIT)
Abstract:
In this work, a simple reactor model for evaluating the intrinsic rate constant of a photocyclization reaction
is presented. The photoreaction was performed in a standardized capillary microreactor that ensures
isothermal and uniform irradiation conditions. The effects of residence time and incident light intensity on
the reaction performance were studied, and a reaction kinetic model was established based on a plug flow
assumption. The reaction order with respect to the F-tagged amide precursor was found to be 2 in the
photochemical transformation, and apparent rate constants under various light intensities were obtained.
Comprehensive mass transport diagnostics were performed by using dimensionless numbers based on the
established effective reaction kinetics. The intrinsic rate constant of the photoreaction was extracted from
the experimental data using a simplified reactor model, in which a parameter representing the photon
absorption fraction of the photocatalyst was introduced. Moreover, the proposed reactor model gives a
general overview for improving the space–time yield of photochemical processes in microreactors.
is presented. The photoreaction was performed in a standardized capillary microreactor that ensures
isothermal and uniform irradiation conditions. The effects of residence time and incident light intensity on
the reaction performance were studied, and a reaction kinetic model was established based on a plug flow
assumption. The reaction order with respect to the F-tagged amide precursor was found to be 2 in the
photochemical transformation, and apparent rate constants under various light intensities were obtained.
Comprehensive mass transport diagnostics were performed by using dimensionless numbers based on the
established effective reaction kinetics. The intrinsic rate constant of the photoreaction was extracted from
the experimental data using a simplified reactor model, in which a parameter representing the photon
absorption fraction of the photocatalyst was introduced. Moreover, the proposed reactor model gives a
general overview for improving the space–time yield of photochemical processes in microreactors.
| Zugehörige Institution(en) am KIT | Institut für Biologische und Chemische Systeme (IBCS) Institut für Mikroverfahrenstechnik (IMVT) Institut für Organische Chemie (IOC) |
| Publikationstyp | Zeitschriftenaufsatz |
| Publikationsdatum | 23.07.2024 |
| Sprache | Englisch |
| Identifikator | ISSN: 2058-9883 KITopen-ID: 1000171528 |
| HGF-Programm | 38.03.02 (POF IV, LK 01) Power-based Fuels and Chemicals |
| Erschienen in | Reaction Chemistry & Engineering |
| Verlag | Royal Society of Chemistry (RSC) |
| Band | 9 |
| Heft | 8 |
| Seiten | 2149–2159 |
| Vorab online veröffentlicht am | 09.05.2024 |
| Nachgewiesen in | Web of Science Scopus Dimensions |