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High-productivity single-pass electrochemical birch reduction of Naphthalenes in a continuous flow electrochemical Taylor Vortex Reactor

High-productivity single-pass electrochemical birch reduction of Naphthalenes in a continuous flow electrochemical Taylor Vortex Reactor
High-productivity single-pass electrochemical birch reduction of Naphthalenes in a continuous flow electrochemical Taylor Vortex Reactor
We report the development of a single-pass electrochemical Birch reduction carried out in a small footprint electrochemical Taylor vortex reactor with projected productivities of >80 g day-1 (based on 32.2 mmol h-1), using a modified version of our previously reported reactor [Org. Process Res. Dev. 2021, 25, 7, 1619-1627], consisting of a static outer electrode and a rapidly rotating cylindrical inner electrode. In this study, we used an aluminum tube as the sacrificial outer electrode and stainless steel as the rotating inner electrode. We have established the viability of using a sacrificial aluminum anode for the electrochemical reduction of naphthalene, and by varying the current, we can switch between high selectivity (>90%) for either the single ring reduction or double ring reduction with >80 g day-1 projected productivity for either product. The concentration of LiBr in solution changes the fluid dynamics of the reaction mixture investigated by computational fluid dynamics, and this affects equilibration time, monitored using Fourier transform infrared spectroscopy. We show that the concentrations of electrolyte (LiBr) and proton source (dimethylurea) can be reduced while maintaining high reaction efficiency. We also report the reduction of 1-aminonaphthalene, which has been used as a precursor to the API Ropinirole. We find that our methodology produces the corresponding dihydronaphthalene with excellent selectivity and 88% isolated yield in an uninterrupted run of >8 h with a projected productivity of >100 g day-1.
Birch reduction, continuous flow, dearomatization, electrochemistry, electroreduction, Taylor vortex reactor
1083-6160
2674-2684
Lee, Darren S.
37a299e0-81c6-4630-90bc-92a9921fbb9c
Love, Ashley
b082e4f2-fbbc-4c8c-97ec-37711f4767fd
Mansouri, Zakaria
7943d1a9-9655-4246-b038-2ba13c1ded2b
Waldron Clarke, Toby H.
962d29af-3ea0-4c70-b784-a2d47853451c
Harrowven, David C.
bddcfab6-dbde-49df-aec2-42abbcf5d10b
Jefferson-Loveday, Richard
35061b92-7b46-4970-acf6-92163a64f48d
Pickering, Stephen J.
73719011-f28d-40fb-b74b-0ac0ef89232d
Poliakoff, Martyn
32e8faf7-3736-4052-8b7e-cf381dc76210
George, Michael W.
152757cb-31f4-4fba-82ac-b0d3c9926a36
Lee, Darren S.
37a299e0-81c6-4630-90bc-92a9921fbb9c
Love, Ashley
b082e4f2-fbbc-4c8c-97ec-37711f4767fd
Mansouri, Zakaria
7943d1a9-9655-4246-b038-2ba13c1ded2b
Waldron Clarke, Toby H.
962d29af-3ea0-4c70-b784-a2d47853451c
Harrowven, David C.
bddcfab6-dbde-49df-aec2-42abbcf5d10b
Jefferson-Loveday, Richard
35061b92-7b46-4970-acf6-92163a64f48d
Pickering, Stephen J.
73719011-f28d-40fb-b74b-0ac0ef89232d
Poliakoff, Martyn
32e8faf7-3736-4052-8b7e-cf381dc76210
George, Michael W.
152757cb-31f4-4fba-82ac-b0d3c9926a36

Lee, Darren S., Love, Ashley, Mansouri, Zakaria, Waldron Clarke, Toby H., Harrowven, David C., Jefferson-Loveday, Richard, Pickering, Stephen J., Poliakoff, Martyn and George, Michael W. (2022) High-productivity single-pass electrochemical birch reduction of Naphthalenes in a continuous flow electrochemical Taylor Vortex Reactor. Organic Process Research and Development, 26 (9), 2674-2684. (doi:10.1021/acs.oprd.2c00108).

Record type: Article

Abstract

We report the development of a single-pass electrochemical Birch reduction carried out in a small footprint electrochemical Taylor vortex reactor with projected productivities of >80 g day-1 (based on 32.2 mmol h-1), using a modified version of our previously reported reactor [Org. Process Res. Dev. 2021, 25, 7, 1619-1627], consisting of a static outer electrode and a rapidly rotating cylindrical inner electrode. In this study, we used an aluminum tube as the sacrificial outer electrode and stainless steel as the rotating inner electrode. We have established the viability of using a sacrificial aluminum anode for the electrochemical reduction of naphthalene, and by varying the current, we can switch between high selectivity (>90%) for either the single ring reduction or double ring reduction with >80 g day-1 projected productivity for either product. The concentration of LiBr in solution changes the fluid dynamics of the reaction mixture investigated by computational fluid dynamics, and this affects equilibration time, monitored using Fourier transform infrared spectroscopy. We show that the concentrations of electrolyte (LiBr) and proton source (dimethylurea) can be reduced while maintaining high reaction efficiency. We also report the reduction of 1-aminonaphthalene, which has been used as a precursor to the API Ropinirole. We find that our methodology produces the corresponding dihydronaphthalene with excellent selectivity and 88% isolated yield in an uninterrupted run of >8 h with a projected productivity of >100 g day-1.

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All accepted Birch Paper_July 1st_DL - Accepted Manuscript
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More information

Accepted/In Press date: 24 August 2022
e-pub ahead of print date: 24 August 2022
Published date: 16 September 2022
Additional Information: © 2022 The Authors. Published by American Chemical Society.
Keywords: Birch reduction, continuous flow, dearomatization, electrochemistry, electroreduction, Taylor vortex reactor

Identifiers

Local EPrints ID: 471880
URI: http://eprints.soton.ac.uk/id/eprint/471880
ISSN: 1083-6160
PURE UUID: 221fe596-e217-4edb-9126-a53b8951e5ba
ORCID for David C. Harrowven: ORCID iD orcid.org/0000-0001-6730-3573

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Date deposited: 22 Nov 2022 17:33
Last modified: 18 Mar 2024 02:40

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Contributors

Author: Darren S. Lee
Author: Ashley Love
Author: Zakaria Mansouri
Author: Toby H. Waldron Clarke
Author: Richard Jefferson-Loveday
Author: Stephen J. Pickering
Author: Martyn Poliakoff
Author: Michael W. George

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