H2O2 Production at Low Overpotentials for Electroenzymatic Halogenation Reactions

Sebastian Bormann; Morten M.C.H. van Schie; Tiago Pedroso De Almeida; Wuyuan Zhang; Markus Stöckl; Roland Ulber; Frank Hollmann; Dirk Holtmann

doi:10.1002/cssc.201902326

H₂O₂ Production at Low Overpotentials for Electroenzymatic Halogenation Reactions

Sebastian Bormann, Morten M.C.H. van Schie, Tiago Pedroso De Almeida, Wuyuan Zhang, Markus Stöckl, Roland Ulber, Frank Hollmann^*, Dirk Holtmann

^*Corresponding author for this work

BT/Biocatalysis

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

28 Citations (Scopus)

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Abstract

Various enzymes utilize hydrogen peroxide as an oxidant. Such “peroxizymes” are potentially very attractive catalysts for a broad range of oxidation reactions. Most peroxizymes, however, are inactivated by an excess of H₂O₂. The electrochemical reduction of oxygen can be used as an in situ generation method for hydrogen peroxide to drive the peroxizymes at high operational stabilities. Using conventional electrode materials, however, also necessitates significant overpotentials, thereby reducing the energy efficiency of these systems. This study concerns a method to coat a gas-diffusion electrode with oxidized carbon nanotubes (oCNTs), thereby greatly reducing the overpotential needed to perform an electroenzymatic halogenation reaction. In comparison to the unmodified electrode, with the oCNTs-modified electrode the overpotential can be reduced by approximately 100 mV at comparable product formation rates.

Original language	English
Pages (from-to)	4759-4763
Number of pages	5
Journal	ChemSusChem
Volume	12
Issue number	21
DOIs	https://doi.org/10.1002/cssc.201902326
Publication status	Published - 2019

Keywords

biocatalysis
carbon nanotubes
electrochemistry
enzymes
hydrogen peroxide

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10.1002/cssc.201902326

Bormann_et_al-2019-ChemSusChemFinal published version, 568 KBLicence: CC BY

Cite this

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title = "H2O2 Production at Low Overpotentials for Electroenzymatic Halogenation Reactions",

abstract = "Various enzymes utilize hydrogen peroxide as an oxidant. Such “peroxizymes” are potentially very attractive catalysts for a broad range of oxidation reactions. Most peroxizymes, however, are inactivated by an excess of H2O2. The electrochemical reduction of oxygen can be used as an in situ generation method for hydrogen peroxide to drive the peroxizymes at high operational stabilities. Using conventional electrode materials, however, also necessitates significant overpotentials, thereby reducing the energy efficiency of these systems. This study concerns a method to coat a gas-diffusion electrode with oxidized carbon nanotubes (oCNTs), thereby greatly reducing the overpotential needed to perform an electroenzymatic halogenation reaction. In comparison to the unmodified electrode, with the oCNTs-modified electrode the overpotential can be reduced by approximately 100 mV at comparable product formation rates.",

keywords = "biocatalysis, carbon nanotubes, electrochemistry, enzymes, hydrogen peroxide",

author = "Sebastian Bormann and {van Schie}, {Morten M.C.H.} and {De Almeida}, {Tiago Pedroso} and Wuyuan Zhang and Markus St{\"o}ckl and Roland Ulber and Frank Hollmann and Dirk Holtmann",

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AU - Bormann, Sebastian

AU - van Schie, Morten M.C.H.

AU - De Almeida, Tiago Pedroso

AU - Zhang, Wuyuan

AU - Stöckl, Markus

AU - Ulber, Roland

AU - Hollmann, Frank

AU - Holtmann, Dirk

PY - 2019

Y1 - 2019

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AB - Various enzymes utilize hydrogen peroxide as an oxidant. Such “peroxizymes” are potentially very attractive catalysts for a broad range of oxidation reactions. Most peroxizymes, however, are inactivated by an excess of H2O2. The electrochemical reduction of oxygen can be used as an in situ generation method for hydrogen peroxide to drive the peroxizymes at high operational stabilities. Using conventional electrode materials, however, also necessitates significant overpotentials, thereby reducing the energy efficiency of these systems. This study concerns a method to coat a gas-diffusion electrode with oxidized carbon nanotubes (oCNTs), thereby greatly reducing the overpotential needed to perform an electroenzymatic halogenation reaction. In comparison to the unmodified electrode, with the oCNTs-modified electrode the overpotential can be reduced by approximately 100 mV at comparable product formation rates.

KW - biocatalysis

KW - carbon nanotubes

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