TEMPO‐Mediated Paired Electrosynthesis of Ethylene Glycol from Formaldehyde and Methanol at High Current Densities

Valtteri Oksanen; Kiia Malinen; Tao Hu; Alexander Reznichenko; Tom Wirtanen

doi:10.1002/cssc.202500123

TEMPO‐Mediated Paired Electrosynthesis of Ethylene Glycol from Formaldehyde and Methanol at High Current Densities

Valtteri Oksanen, Kiia Malinen, Tao Hu, Alexander Reznichenko, Tom Wirtanen^*

^*Corresponding author for this work

BA5205 Chemical and polymer synthesis

Research output: Contribution to journal › Article › Scientific › peer-review

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Abstract

Herein, a paired electrosynthesis of ethylene glycol from formaldehyde and methanol facilitated by TEMPO is reported. The use of TEMPO accentuates formaldehyde production at the anode, providing additional formaldehyde into the cathodic coupling process. The reaction is performed in water/methanol solution in a simple undivided cell using sulfuric acid-treated graphite electrodes with industrially feasible current densities between 300 and 350 mA cm−2. Other components of the reaction are sodium chloride which is used as a supporting electrolyte and tributylmethylammonium chloride which raises the current efficiency. With a slight modification in the reaction temperature and current density, the outcome can be tuned from high current efficiency toward higher chemical yields. The conditions of the batch reaction are successfully transferred to a continuous flow-cell arrangement. Mechanistic studies indicate the involvement of hydroxymethyl radicals in the electrolysis, and deuterium-labeling experiments show the partial conversion of methanol into formaldehyde and ethylene glycol.

Original language	English
Article number	2500123
Journal	ChemSusChem
DOIs	https://doi.org/10.1002/cssc.202500123
Publication status	E-pub ahead of print - 11 Apr 2025
MoE publication type	A1 Journal article-refereed

Funding

T.W. is grateful for financial support from the Research Council of Finland (grant no. 348889). V.O. acknowledges European Union NextGenerationEU for funding, which is part of the strategic research opening “Electric Storage” of VTT, launched with the support of the additional chapter of the RePowerEU investment and reform program for sustainable growth in Finland.

Keywords

aldehydes
c1 building blocks
electrochemistry
dimerization
alcohols

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cssc.202500123Final published version, 640 KBLicence: CC BY

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title = "TEMPO‐Mediated Paired Electrosynthesis of Ethylene Glycol from Formaldehyde and Methanol at High Current Densities",

abstract = "Herein, a paired electrosynthesis of ethylene glycol from formaldehyde and methanol facilitated by TEMPO is reported. The use of TEMPO accentuates formaldehyde production at the anode, providing additional formaldehyde into the cathodic coupling process. The reaction is performed in water/methanol solution in a simple undivided cell using sulfuric acid-treated graphite electrodes with industrially feasible current densities between 300 and 350 mA cm−2. Other components of the reaction are sodium chloride which is used as a supporting electrolyte and tributylmethylammonium chloride which raises the current efficiency. With a slight modification in the reaction temperature and current density, the outcome can be tuned from high current efficiency toward higher chemical yields. The conditions of the batch reaction are successfully transferred to a continuous flow-cell arrangement. Mechanistic studies indicate the involvement of hydroxymethyl radicals in the electrolysis, and deuterium-labeling experiments show the partial conversion of methanol into formaldehyde and ethylene glycol.",

keywords = "aldehydes, c1 building blocks, electrochemistry, dimerization, alcohols",

author = "Valtteri Oksanen and Kiia Malinen and Tao Hu and Alexander Reznichenko and Tom Wirtanen",

year = "2025",

month = apr,

day = "11",

doi = "10.1002/cssc.202500123",

language = "English",

journal = "ChemSusChem",

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T1 - TEMPO‐Mediated Paired Electrosynthesis of Ethylene Glycol from Formaldehyde and Methanol at High Current Densities

AU - Oksanen, Valtteri

AU - Malinen, Kiia

AU - Hu, Tao

AU - Reznichenko, Alexander

AU - Wirtanen, Tom

PY - 2025/4/11

Y1 - 2025/4/11

N2 - Herein, a paired electrosynthesis of ethylene glycol from formaldehyde and methanol facilitated by TEMPO is reported. The use of TEMPO accentuates formaldehyde production at the anode, providing additional formaldehyde into the cathodic coupling process. The reaction is performed in water/methanol solution in a simple undivided cell using sulfuric acid-treated graphite electrodes with industrially feasible current densities between 300 and 350 mA cm−2. Other components of the reaction are sodium chloride which is used as a supporting electrolyte and tributylmethylammonium chloride which raises the current efficiency. With a slight modification in the reaction temperature and current density, the outcome can be tuned from high current efficiency toward higher chemical yields. The conditions of the batch reaction are successfully transferred to a continuous flow-cell arrangement. Mechanistic studies indicate the involvement of hydroxymethyl radicals in the electrolysis, and deuterium-labeling experiments show the partial conversion of methanol into formaldehyde and ethylene glycol.

AB - Herein, a paired electrosynthesis of ethylene glycol from formaldehyde and methanol facilitated by TEMPO is reported. The use of TEMPO accentuates formaldehyde production at the anode, providing additional formaldehyde into the cathodic coupling process. The reaction is performed in water/methanol solution in a simple undivided cell using sulfuric acid-treated graphite electrodes with industrially feasible current densities between 300 and 350 mA cm−2. Other components of the reaction are sodium chloride which is used as a supporting electrolyte and tributylmethylammonium chloride which raises the current efficiency. With a slight modification in the reaction temperature and current density, the outcome can be tuned from high current efficiency toward higher chemical yields. The conditions of the batch reaction are successfully transferred to a continuous flow-cell arrangement. Mechanistic studies indicate the involvement of hydroxymethyl radicals in the electrolysis, and deuterium-labeling experiments show the partial conversion of methanol into formaldehyde and ethylene glycol.

KW - aldehydes

KW - c1 building blocks

KW - electrochemistry

KW - dimerization

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TEMPO‐Mediated Paired Electrosynthesis of Ethylene Glycol from Formaldehyde and Methanol at High Current Densities

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Paired Electrosynthetic Upgrading of Organic Molecules

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TEMPO‐Mediated Paired Electrosynthesis of Ethylene Glycol from Formaldehyde and Methanol at High Current Densities

Abstract

Funding

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Paired Electrosynthetic Upgrading of Organic Molecules

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