Structure Sensitivity of CO2Conversion over Nickel Metal Nanoparticles Explained by Micro-Kinetics Simulations

Ellen B. Sterk; Anne Eva Nieuwelink; Matteo Monai; Jaap N. Louwen; Eelco T.C. Vogt; Ivo A.W. Filot; Bert M. Weckhuysen

doi:10.1021/jacsau.2c00430

Structure Sensitivity of CO₂Conversion over Nickel Metal Nanoparticles Explained by Micro-Kinetics Simulations

Ellen B. Sterk
, Anne Eva Nieuwelink
, Matteo Monai
, Jaap N. Louwen
, Eelco T.C. Vogt
, Ivo A.W. Filot
, Bert M. Weckhuysen^*

^*Corresponding author for this work

Faculty of Science

Eindhoven University of Technology

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

Abstract

Nickel metal nanoparticles are intensively researched for the catalytic conversion of carbon dioxide. They are commercially explored in the so-called power-to-methane application in which renewably resourced H2 reacts with CO2 to produce CH4, which is better known as the Sabatier reaction. Previous work has shown that this reaction is structure-sensitive. For instance, Ni/SiO2 catalysts reveal a maximum performance when nickel metal nanoparticles of ∼2-3 nm are used. Particularly important to a better understanding of the structure sensitivity of the Sabatier reaction over nickel-based catalysts is to understand all relevant elementary reaction steps over various nickel metal facets because this will tell as to which type of nickel facets and which elementary reaction steps are crucial for designing an efficient nickel-based methanation catalyst. In this work, we have determined by density functional theory (DFT) calculations and micro-kinetics modeling (MKM) simulations that the two terrace facets Ni(111) and Ni(100) and the stepped facet Ni(211) barely show any activity in CO2 methanation. The stepped facet Ni(110) turned out to be the most effective in CO2 methanation. Herein, it was found that the dominant kinetic route corresponds to a combination of the carbide and formate reaction pathways. It was found that the dissociation of H2CO∗ toward CH2∗ and O∗ is the most critical elementary reaction step on this Ni(110) facet. The calculated activity of a range of Wulff-constructed nickel metal nanoparticles, accounting for varying ratios of the different facets and undercoordinated atoms exposed, reveals the same trend of activity-versus-nanoparticle size, as was observed in previous experimental work from our research group, thereby providing an explanation for the structure-sensitive nature of the Sabatier reaction.

Original language	English
Pages (from-to)	2714-2730
Number of pages	17
Journal	Journal of the American Chemical Society
Volume	2
Issue number	12
Early online date	14 Oct 2022
DOIs	https://doi.org/10.1021/jacsau.2c00430
Publication status	Published - 26 Dec 2022

Bibliographical note

Funding Information:
The research presented in this work was calculated on the Cartesius cluster and the authors gratefully acknowledge NWO for the computation time and also SurfSARA for maintenance. This work was supported by the Netherlands Center for Multiscale Catalytic Energy Conversion (MCEC), an NWO Gravitation program funded by the Ministry of Education, Culture and Science (OC&W), of the government of the Netherlands. Thomas Hartman (Utrecht University, UU) is thanked for making animations of the predominant reaction mechanisms. Bram Kappé (UU) is acknowledged for help with catalytic measurements and useful discussions. Renzo Leeflang (UU) is acknowledged for helping to assemble the Wulff-constructed nickel metal nanoparticles. Michel van Etten (Eindhoven University of Technology, TU/e) is thanked for sharing the pattern library used by the pattern recognition software for the enumeration of the active sites in Wulff constructions.

Publisher Copyright:
© 2022 The Authors. Published by American Chemical Society.

Funding

The research presented in this work was calculated on the Cartesius cluster and the authors gratefully acknowledge NWO for the computation time and also SurfSARA for maintenance. This work was supported by the Netherlands Center for Multiscale Catalytic Energy Conversion (MCEC), an NWO Gravitation program funded by the Ministry of Education, Culture and Science (OC&W), of the government of the Netherlands. Thomas Hartman (Utrecht University, UU) is thanked for making animations of the predominant reaction mechanisms. Bram Kappé (UU) is acknowledged for help with catalytic measurements and useful discussions. Renzo Leeflang (UU) is acknowledged for helping to assemble the Wulff-constructed nickel metal nanoparticles. Michel van Etten (Eindhoven University of Technology, TU/e) is thanked for sharing the pattern library used by the pattern recognition software for the enumeration of the active sites in Wulff constructions.

Keywords

carbon dioxide
density functional theory
micro-kinetics simulations
nickel
Sabatier reaction

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Cite this

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title = "Structure Sensitivity of CO2Conversion over Nickel Metal Nanoparticles Explained by Micro-Kinetics Simulations",

abstract = "Nickel metal nanoparticles are intensively researched for the catalytic conversion of carbon dioxide. They are commercially explored in the so-called power-to-methane application in which renewably resourced H2 reacts with CO2 to produce CH4, which is better known as the Sabatier reaction. Previous work has shown that this reaction is structure-sensitive. For instance, Ni/SiO2 catalysts reveal a maximum performance when nickel metal nanoparticles of ∼2-3 nm are used. Particularly important to a better understanding of the structure sensitivity of the Sabatier reaction over nickel-based catalysts is to understand all relevant elementary reaction steps over various nickel metal facets because this will tell as to which type of nickel facets and which elementary reaction steps are crucial for designing an efficient nickel-based methanation catalyst. In this work, we have determined by density functional theory (DFT) calculations and micro-kinetics modeling (MKM) simulations that the two terrace facets Ni(111) and Ni(100) and the stepped facet Ni(211) barely show any activity in CO2 methanation. The stepped facet Ni(110) turned out to be the most effective in CO2 methanation. Herein, it was found that the dominant kinetic route corresponds to a combination of the carbide and formate reaction pathways. It was found that the dissociation of H2CO∗ toward CH2∗ and O∗ is the most critical elementary reaction step on this Ni(110) facet. The calculated activity of a range of Wulff-constructed nickel metal nanoparticles, accounting for varying ratios of the different facets and undercoordinated atoms exposed, reveals the same trend of activity-versus-nanoparticle size, as was observed in previous experimental work from our research group, thereby providing an explanation for the structure-sensitive nature of the Sabatier reaction.",

keywords = "carbon dioxide, density functional theory, micro-kinetics simulations, nickel, Sabatier reaction",

author = "Sterk, \{Ellen B.\} and Nieuwelink, \{Anne Eva\} and Matteo Monai and Louwen, \{Jaap N.\} and Vogt, \{Eelco T.C.\} and Filot, \{Ivo A.W.\} and Weckhuysen, \{Bert M.\}",

note = "Funding Information: The research presented in this work was calculated on the Cartesius cluster and the authors gratefully acknowledge NWO for the computation time and also SurfSARA for maintenance. This work was supported by the Netherlands Center for Multiscale Catalytic Energy Conversion (MCEC), an NWO Gravitation program funded by the Ministry of Education, Culture and Science (OC\&W), of the government of the Netherlands. Thomas Hartman (Utrecht University, UU) is thanked for making animations of the predominant reaction mechanisms. Bram Kapp{\'e} (UU) is acknowledged for help with catalytic measurements and useful discussions. Renzo Leeflang (UU) is acknowledged for helping to assemble the Wulff-constructed nickel metal nanoparticles. Michel van Etten (Eindhoven University of Technology, TU/e) is thanked for sharing the pattern library used by the pattern recognition software for the enumeration of the active sites in Wulff constructions. Publisher Copyright: {\textcopyright} 2022 The Authors. Published by American Chemical Society.",

year = "2022",

month = dec,

day = "26",

doi = "10.1021/jacsau.2c00430",

language = "English",

volume = "2",

pages = "2714--2730",

journal = "Journal of the American Chemical Society",

issn = "0002-7863",

publisher = "American Chemical Society",

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TY - JOUR

T1 - Structure Sensitivity of CO2Conversion over Nickel Metal Nanoparticles Explained by Micro-Kinetics Simulations

AU - Sterk, Ellen B.

AU - Nieuwelink, Anne Eva

AU - Monai, Matteo

AU - Louwen, Jaap N.

AU - Vogt, Eelco T.C.

AU - Filot, Ivo A.W.

AU - Weckhuysen, Bert M.

N1 - Funding Information: The research presented in this work was calculated on the Cartesius cluster and the authors gratefully acknowledge NWO for the computation time and also SurfSARA for maintenance. This work was supported by the Netherlands Center for Multiscale Catalytic Energy Conversion (MCEC), an NWO Gravitation program funded by the Ministry of Education, Culture and Science (OC&W), of the government of the Netherlands. Thomas Hartman (Utrecht University, UU) is thanked for making animations of the predominant reaction mechanisms. Bram Kappé (UU) is acknowledged for help with catalytic measurements and useful discussions. Renzo Leeflang (UU) is acknowledged for helping to assemble the Wulff-constructed nickel metal nanoparticles. Michel van Etten (Eindhoven University of Technology, TU/e) is thanked for sharing the pattern library used by the pattern recognition software for the enumeration of the active sites in Wulff constructions. Publisher Copyright: © 2022 The Authors. Published by American Chemical Society.

PY - 2022/12/26

Y1 - 2022/12/26

N2 - Nickel metal nanoparticles are intensively researched for the catalytic conversion of carbon dioxide. They are commercially explored in the so-called power-to-methane application in which renewably resourced H2 reacts with CO2 to produce CH4, which is better known as the Sabatier reaction. Previous work has shown that this reaction is structure-sensitive. For instance, Ni/SiO2 catalysts reveal a maximum performance when nickel metal nanoparticles of ∼2-3 nm are used. Particularly important to a better understanding of the structure sensitivity of the Sabatier reaction over nickel-based catalysts is to understand all relevant elementary reaction steps over various nickel metal facets because this will tell as to which type of nickel facets and which elementary reaction steps are crucial for designing an efficient nickel-based methanation catalyst. In this work, we have determined by density functional theory (DFT) calculations and micro-kinetics modeling (MKM) simulations that the two terrace facets Ni(111) and Ni(100) and the stepped facet Ni(211) barely show any activity in CO2 methanation. The stepped facet Ni(110) turned out to be the most effective in CO2 methanation. Herein, it was found that the dominant kinetic route corresponds to a combination of the carbide and formate reaction pathways. It was found that the dissociation of H2CO∗ toward CH2∗ and O∗ is the most critical elementary reaction step on this Ni(110) facet. The calculated activity of a range of Wulff-constructed nickel metal nanoparticles, accounting for varying ratios of the different facets and undercoordinated atoms exposed, reveals the same trend of activity-versus-nanoparticle size, as was observed in previous experimental work from our research group, thereby providing an explanation for the structure-sensitive nature of the Sabatier reaction.

AB - Nickel metal nanoparticles are intensively researched for the catalytic conversion of carbon dioxide. They are commercially explored in the so-called power-to-methane application in which renewably resourced H2 reacts with CO2 to produce CH4, which is better known as the Sabatier reaction. Previous work has shown that this reaction is structure-sensitive. For instance, Ni/SiO2 catalysts reveal a maximum performance when nickel metal nanoparticles of ∼2-3 nm are used. Particularly important to a better understanding of the structure sensitivity of the Sabatier reaction over nickel-based catalysts is to understand all relevant elementary reaction steps over various nickel metal facets because this will tell as to which type of nickel facets and which elementary reaction steps are crucial for designing an efficient nickel-based methanation catalyst. In this work, we have determined by density functional theory (DFT) calculations and micro-kinetics modeling (MKM) simulations that the two terrace facets Ni(111) and Ni(100) and the stepped facet Ni(211) barely show any activity in CO2 methanation. The stepped facet Ni(110) turned out to be the most effective in CO2 methanation. Herein, it was found that the dominant kinetic route corresponds to a combination of the carbide and formate reaction pathways. It was found that the dissociation of H2CO∗ toward CH2∗ and O∗ is the most critical elementary reaction step on this Ni(110) facet. The calculated activity of a range of Wulff-constructed nickel metal nanoparticles, accounting for varying ratios of the different facets and undercoordinated atoms exposed, reveals the same trend of activity-versus-nanoparticle size, as was observed in previous experimental work from our research group, thereby providing an explanation for the structure-sensitive nature of the Sabatier reaction.

KW - carbon dioxide

KW - density functional theory

KW - micro-kinetics simulations

KW - nickel

KW - Sabatier reaction

UR - https://www.scopus.com/pages/publications/85140325513

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DO - 10.1021/jacsau.2c00430

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