Alkylamine-Functionalized Carbon Supports to Enhance the Silver Nanoparticles Electrocatalytic Reduction of CO2 to CO

Francesco Mattarozzi; Karen van den Akker; Matt L.J. Peerlings; Maaike E.T. Vink-Van Ittersum; Nienke L. Visser; Rim C.J. van de Poll; Emiel J.M. Hensen; Peter Ngene; Petra E. de Jongh

doi:10.1002/celc.202300295

Alkylamine-Functionalized Carbon Supports to Enhance the Silver Nanoparticles Electrocatalytic Reduction of CO₂ to CO

Francesco Mattarozzi
, Karen van den Akker
, Matt L.J. Peerlings
, Maaike E.T. Vink-Van Ittersum
, Nienke L. Visser
, Rim C.J. van de Poll
, Emiel J.M. Hensen
, Peter Ngene
, Petra E. de Jongh (Corresponding author)

Onderzoeksoutput: Bijdrage aan tijdschrift › Tijdschriftartikel › Academic › peer review

4 Citaten (Scopus)

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Samenvatting

Silver electrocatalysts enable the conversion of CO₂ to CO, thereby facilitating the transition to a carbon neutral society. To lower the cost of the expensive metal, silver nanostructures are often supported on carbon. This substrate offers great electrical conductivity, but it enhances the selectivity towards the competing hydrogen evolution reaction. In this work, carbon supports were functionalized with linear alkylamines of different chain lengths, to understand its effect on electrochemical performance. Alkylamines interact with the carbon surface and confer hydrophobic properties to the carbon support as well as making the local environment less acidic. These properties led not only to a suppression of the hydrogen evolution, but also to a remarkable enhancement in CO production. Despite the low silver weight loading (0.0016 mg_Ag cm⁻²), hexylamine-functionalized carbon-based catalysts achieved a CO to H₂ ratio of 2.0, while the same material without the alkylamine functionalization only reached a ratio of 0.3, at −1.3 V vs RHE. This demonstrates the potential of hydrophobic functionalization for enhancing the CO selectivity of carbon-supported catalysts.

Originele taal-2	Engels
Artikelnummer	e202300295
Aantal pagina's	8
Tijdschrift	ChemElectroChem
Volume	10
Nummer van het tijdschrift	19
DOI's	https://doi.org/10.1002/celc.202300295
Status	Gepubliceerd - 2 okt. 2023

Bibliografische nota

Funding Information:
Francesco Mattarozzi and Rim van de Poll were funded by the Dutch Research Council (NWO), via the Advanced Research Center Chemical Building Blocks Consortium (ARC‐CBBC) in collaboration with Shell Global Solutions International B.V. Matt Peerlings and Maaike Vink‐van Ittersum acknowledge funding from the NWO and RELEASE consortium. Nienke Visser was funded by TotalEnergies OneTech Belgium. Stephan Jonker is acknowledged for the precious help with atomic absorption spectroscopy measurements. Alex van Silfhout is acknowledged for his help during the contact angle measurements. Jan Willem de Rijk is acknowledged for the technical support, helping both with the cell design and the preparation of the catalytic set‐up during this project. Valerio Gulino is acknowledged for the useful discussions related to the project results.

Financiering

Francesco Mattarozzi and Rim van de Poll were funded by the Dutch Research Council (NWO), via the Advanced Research Center Chemical Building Blocks Consortium (ARC‐CBBC) in collaboration with Shell Global Solutions International B.V. Matt Peerlings and Maaike Vink‐van Ittersum acknowledge funding from the NWO and RELEASE consortium. Nienke Visser was funded by TotalEnergies OneTech Belgium. Stephan Jonker is acknowledged for the precious help with atomic absorption spectroscopy measurements. Alex van Silfhout is acknowledged for his help during the contact angle measurements. Jan Willem de Rijk is acknowledged for the technical support, helping both with the cell design and the preparation of the catalytic set‐up during this project. Valerio Gulino is acknowledged for the useful discussions related to the project results.

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Mattarozzi, F., van den Akker, K., Peerlings, M. L. J., Vink-Van Ittersum, M. E. T., Visser, N. L., van de Poll, R. C. J., Hensen, E. J. M., Ngene, P., & de Jongh, P. E. (2023). Alkylamine-Functionalized Carbon Supports to Enhance the Silver Nanoparticles Electrocatalytic Reduction of CO₂ to CO. ChemElectroChem, 10(19), Artikel e202300295. https://doi.org/10.1002/celc.202300295

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title = "Alkylamine-Functionalized Carbon Supports to Enhance the Silver Nanoparticles Electrocatalytic Reduction of CO2 to CO",

abstract = "Silver electrocatalysts enable the conversion of CO2 to CO, thereby facilitating the transition to a carbon neutral society. To lower the cost of the expensive metal, silver nanostructures are often supported on carbon. This substrate offers great electrical conductivity, but it enhances the selectivity towards the competing hydrogen evolution reaction. In this work, carbon supports were functionalized with linear alkylamines of different chain lengths, to understand its effect on electrochemical performance. Alkylamines interact with the carbon surface and confer hydrophobic properties to the carbon support as well as making the local environment less acidic. These properties led not only to a suppression of the hydrogen evolution, but also to a remarkable enhancement in CO production. Despite the low silver weight loading (0.0016 mgAg cm−2), hexylamine-functionalized carbon-based catalysts achieved a CO to H2 ratio of 2.0, while the same material without the alkylamine functionalization only reached a ratio of 0.3, at −1.3 V vs RHE. This demonstrates the potential of hydrophobic functionalization for enhancing the CO selectivity of carbon-supported catalysts.",

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author = "Francesco Mattarozzi and \{van den Akker\}, Karen and Peerlings, \{Matt L.J.\} and \{Vink-Van Ittersum\}, \{Maaike E.T.\} and Visser, \{Nienke L.\} and \{van de Poll\}, \{Rim C.J.\} and Hensen, \{Emiel J.M.\} and Peter Ngene and \{de Jongh\}, \{Petra E.\}",

note = "Funding Information: Francesco Mattarozzi and Rim van de Poll were funded by the Dutch Research Council (NWO), via the Advanced Research Center Chemical Building Blocks Consortium (ARC‐CBBC) in collaboration with Shell Global Solutions International B.V. Matt Peerlings and Maaike Vink‐van Ittersum acknowledge funding from the NWO and RELEASE consortium. Nienke Visser was funded by TotalEnergies OneTech Belgium. Stephan Jonker is acknowledged for the precious help with atomic absorption spectroscopy measurements. Alex van Silfhout is acknowledged for his help during the contact angle measurements. Jan Willem de Rijk is acknowledged for the technical support, helping both with the cell design and the preparation of the catalytic set‐up during this project. Valerio Gulino is acknowledged for the useful discussions related to the project results. ",

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AU - Vink-Van Ittersum, Maaike E.T.

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AU - Hensen, Emiel J.M.

AU - Ngene, Peter

AU - de Jongh, Petra E.

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N2 - Silver electrocatalysts enable the conversion of CO2 to CO, thereby facilitating the transition to a carbon neutral society. To lower the cost of the expensive metal, silver nanostructures are often supported on carbon. This substrate offers great electrical conductivity, but it enhances the selectivity towards the competing hydrogen evolution reaction. In this work, carbon supports were functionalized with linear alkylamines of different chain lengths, to understand its effect on electrochemical performance. Alkylamines interact with the carbon surface and confer hydrophobic properties to the carbon support as well as making the local environment less acidic. These properties led not only to a suppression of the hydrogen evolution, but also to a remarkable enhancement in CO production. Despite the low silver weight loading (0.0016 mgAg cm−2), hexylamine-functionalized carbon-based catalysts achieved a CO to H2 ratio of 2.0, while the same material without the alkylamine functionalization only reached a ratio of 0.3, at −1.3 V vs RHE. This demonstrates the potential of hydrophobic functionalization for enhancing the CO selectivity of carbon-supported catalysts.

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KW - alkylamine.

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