Scaling Up Gas-Liquid Photo-Oxidations in Flow Using Rotor-Stator Spinning Disc Reactors and a High-Intensity Light Source

Arnab Chaudhuri; Wouter F.C. de Groot; Jasper H.A. Schuurmans; Stefan D.A. Zondag; Alessia Bianchi; Koen P.L. Kuijpers; Rémy Broersma; Amin Delparish; Matthieu Dorbec; John van der Schaaf; Timothy Noël

doi:10.1021/acs.oprd.4c00458

Scaling Up Gas-Liquid Photo-Oxidations in Flow Using Rotor-Stator Spinning Disc Reactors and a High-Intensity Light Source

Arnab Chaudhuri, Wouter F.C. de Groot, Jasper H.A. Schuurmans, Stefan D.A. Zondag, Alessia Bianchi, Koen P.L. Kuijpers, Rémy Broersma, Amin Delparish, Matthieu Dorbec, John van der Schaaf (Corresponding author), Timothy Noël (Corresponding author-nrf)

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Abstract

Photochemical transformations have garnered renewed interest over the past decade for their ability to enable unique reactions under mild conditions. However, scaling up such processes, particularly in multiphase systems (e.g., gas-liquid), remains challenging. Previously, we demonstrated the potential of the photochemical rotor-stator spinning disc reactor (pRS-SDR) for scaling the photooxidation of α-terpinene to ascaridole, though the system was limited by the light source, resulting in suboptimal operation in a photon-limited regime. In this work, we unlock the full potential of the pRS-SDR by integrating a high-powered light source (up to 652 W optical output) specifically designed for the reactor. The results show that the high gas-liquid mass transfer rates achievable in the pRS-SDR allow for significant productivity improvements under high irradiance (16.3 kg day^-1 at 92% α-terpinene conversion and 2.52 W cm^-2 in a 27 mL irradiated volume), representing an order of magnitude increase compared to our previous study. However, the photooxidation of β-citronellol exhibited notable limitations, highlighting the importance of selecting appropriate model reactions when evaluating intensified photochemical reactors.

Original language	English
Pages (from-to)	460-471
Number of pages	12
Journal	Organic Process Research and Development
Volume	29
Issue number	2
Early online date	14 Jan 2025
DOIs	https://doi.org/10.1021/acs.oprd.4c00458
Publication status	Published - 21 Feb 2025

Funding

We express our sincere gratitude to the research group at Signify for extending their support for the custom development of the light source used in this work. A.C and J.vdS. would like to thank J&J Innovative Medicine for providing funding for the project. All authors would like to thank NWO for financial support (19887, PhotoScale, Open Technology Program). S.D.A.Z., J.H.A.S., and T.N. would like to thank the European Union\u2019s Horizon research and innovation program FlowPhotoChem (S.D.A.Z. and T.N.; 862453) and CATART (J.H.A.S. and T.N.; 101046836).

Keywords

photocatalysis
photochemistry
process intensification
reactor development
scale-up

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Chaudhuri, A., de Groot, W. F. C., Schuurmans, J. H. A., Zondag, S. D. A., Bianchi, A., Kuijpers, K. P. L., Broersma, R., Delparish, A., Dorbec, M., van der Schaaf, J., & Noël, T. (2025). Scaling Up Gas-Liquid Photo-Oxidations in Flow Using Rotor-Stator Spinning Disc Reactors and a High-Intensity Light Source. Organic Process Research and Development, 29(2), 460-471. https://doi.org/10.1021/acs.oprd.4c00458

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title = "Scaling Up Gas-Liquid Photo-Oxidations in Flow Using Rotor-Stator Spinning Disc Reactors and a High-Intensity Light Source",

abstract = "Photochemical transformations have garnered renewed interest over the past decade for their ability to enable unique reactions under mild conditions. However, scaling up such processes, particularly in multiphase systems (e.g., gas-liquid), remains challenging. Previously, we demonstrated the potential of the photochemical rotor-stator spinning disc reactor (pRS-SDR) for scaling the photooxidation of α-terpinene to ascaridole, though the system was limited by the light source, resulting in suboptimal operation in a photon-limited regime. In this work, we unlock the full potential of the pRS-SDR by integrating a high-powered light source (up to 652 W optical output) specifically designed for the reactor. The results show that the high gas-liquid mass transfer rates achievable in the pRS-SDR allow for significant productivity improvements under high irradiance (16.3 kg day-1 at 92% α-terpinene conversion and 2.52 W cm-2 in a 27 mL irradiated volume), representing an order of magnitude increase compared to our previous study. However, the photooxidation of β-citronellol exhibited notable limitations, highlighting the importance of selecting appropriate model reactions when evaluating intensified photochemical reactors.",

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author = "Arnab Chaudhuri and {de Groot}, {Wouter F.C.} and Schuurmans, {Jasper H.A.} and Zondag, {Stefan D.A.} and Alessia Bianchi and Kuijpers, {Koen P.L.} and R{\'e}my Broersma and Amin Delparish and Matthieu Dorbec and {van der Schaaf}, John and Timothy No{\"e}l",

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Chaudhuri, A, de Groot, WFC, Schuurmans, JHA, Zondag, SDA , Bianchi, A , Kuijpers, KPL, Broersma, R, Delparish, A, Dorbec, M, van der Schaaf, J & Noël, T 2025, 'Scaling Up Gas-Liquid Photo-Oxidations in Flow Using Rotor-Stator Spinning Disc Reactors and a High-Intensity Light Source', Organic Process Research and Development, vol. 29, no. 2, pp. 460-471. https://doi.org/10.1021/acs.oprd.4c00458

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T1 - Scaling Up Gas-Liquid Photo-Oxidations in Flow Using Rotor-Stator Spinning Disc Reactors and a High-Intensity Light Source

AU - Chaudhuri, Arnab

AU - de Groot, Wouter F.C.

AU - Schuurmans, Jasper H.A.

AU - Zondag, Stefan D.A.

AU - Bianchi, Alessia

AU - Kuijpers, Koen P.L.

AU - Broersma, Rémy

AU - Delparish, Amin

AU - Dorbec, Matthieu

AU - van der Schaaf, John

A2 - Noël, Timothy

PY - 2025/2/21

Y1 - 2025/2/21

N2 - Photochemical transformations have garnered renewed interest over the past decade for their ability to enable unique reactions under mild conditions. However, scaling up such processes, particularly in multiphase systems (e.g., gas-liquid), remains challenging. Previously, we demonstrated the potential of the photochemical rotor-stator spinning disc reactor (pRS-SDR) for scaling the photooxidation of α-terpinene to ascaridole, though the system was limited by the light source, resulting in suboptimal operation in a photon-limited regime. In this work, we unlock the full potential of the pRS-SDR by integrating a high-powered light source (up to 652 W optical output) specifically designed for the reactor. The results show that the high gas-liquid mass transfer rates achievable in the pRS-SDR allow for significant productivity improvements under high irradiance (16.3 kg day-1 at 92% α-terpinene conversion and 2.52 W cm-2 in a 27 mL irradiated volume), representing an order of magnitude increase compared to our previous study. However, the photooxidation of β-citronellol exhibited notable limitations, highlighting the importance of selecting appropriate model reactions when evaluating intensified photochemical reactors.

AB - Photochemical transformations have garnered renewed interest over the past decade for their ability to enable unique reactions under mild conditions. However, scaling up such processes, particularly in multiphase systems (e.g., gas-liquid), remains challenging. Previously, we demonstrated the potential of the photochemical rotor-stator spinning disc reactor (pRS-SDR) for scaling the photooxidation of α-terpinene to ascaridole, though the system was limited by the light source, resulting in suboptimal operation in a photon-limited regime. In this work, we unlock the full potential of the pRS-SDR by integrating a high-powered light source (up to 652 W optical output) specifically designed for the reactor. The results show that the high gas-liquid mass transfer rates achievable in the pRS-SDR allow for significant productivity improvements under high irradiance (16.3 kg day-1 at 92% α-terpinene conversion and 2.52 W cm-2 in a 27 mL irradiated volume), representing an order of magnitude increase compared to our previous study. However, the photooxidation of β-citronellol exhibited notable limitations, highlighting the importance of selecting appropriate model reactions when evaluating intensified photochemical reactors.

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KW - photochemistry

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Scaling Up Gas-Liquid Photo-Oxidations in Flow Using Rotor-Stator Spinning Disc Reactors and a High-Intensity Light Source

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