Enhancement of formic acid production from carbon dioxide hydrogenation using metal-organic frameworks: Monte Carlo simulation study

Dominika O. Wasik; Ana Martín-Calvo; Juan José Gutiérrez-Sevillano; David Dubbeldam; Thijs J.H. Vlugt; Sofía Calero

doi:10.1016/j.cej.2023.143432

Enhancement of formic acid production from carbon dioxide hydrogenation using metal-organic frameworks: Monte Carlo simulation study

Dominika O. Wasik, Ana Martín-Calvo, Juan José Gutiérrez-Sevillano, David Dubbeldam, Thijs J.H. Vlugt, Sofía Calero (Corresponding author)

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Formic acid production from CO₂ allows the reduction of carbon dioxide emissions while synthesizing a product with a wide range of applications. CO₂ hydrogenation is challenging due to the cost of transition metal catalysts and the toxicity of the transition elements. In this work, the thermodynamic confinement effects of the metal–organic framework UiO-66 on the CO₂ hydrogenation to formic acid were studied by force field-based molecular simulations. The confinement effects of UiO-66 and the metal–organic frameworks Cu-BTC, and IRMOF-1 were compared, to assess the impact of different pore size and metal centers on the production of HCOOH. Monte Carlo simulations in the grand-canonical ensemble were performed in the frameworks, using gas phase mole fractions of CO₂, H₂, and HCOOH at chemical equilibrium, obtained from Continuous Fractional Component Monte Carlo simulations in the Reaction Ensemble. The adsorption isobars of the components in metal–organic frameworks were computed at 298.15 – 800 K, 1 – 60 bar. The enhancement of HCOOH production due to preferential adsorption of HCOOH in metal–organic frameworks was calculated for all studied conditions. UiO-66, Cu-BTC, and IRMOF-1 affect CO₂ hydrogenation reaction, shifting the thermodynamical equilibrium toward HCOOH formation. The prevailing factor is the type of metal center in the metal–organic framework. The confinement effect of Cu-BTC turns out to exceed the enhancement caused by UiO-66, and IRMOF-1. The resulting mole fraction of HCOOH increased by ca. 2000 times compared to the gas phase at 298.15 K, 60 bar. Cu-BTC can be considered as an alternative to improve the production of HCOOH due to elimination of the high-cost temperature elevation, cost reduction of downstream processing methods, and comparable final concentration of HCOOH to the reported concentrations of formate obtained using transition metal catalysts.

Originele taal-2	Engels
Artikelnummer	143432
Aantal pagina's	13
Tijdschrift	Chemical Engineering Journal
Volume	467
DOI's	https://doi.org/10.1016/j.cej.2023.143432
Status	Gepubliceerd - 1 jul. 2023

Bibliografische nota

Funding Information:
This research has been supported by the Eindhoven Institute for Renewable Energy Systems (EIRES). A. M-C and J. J. G-S, thank the Spanish Ministerio de Ciencia, Innovación y Universidades (IJC2018-038162-I and IJC2019-042207-I).

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This research has been supported by the Eindhoven Institute for Renewable Energy Systems (EIRES). A. M-C and J. J. G-S, thank the Spanish Ministerio de Ciencia, Innovación y Universidades (IJC2018-038162-I and IJC2019-042207-I). This research has been supported by the Eindhoven Institute for Renewable Energy Systems (EIRES) . A. M-C and J. J. G-S, thank the Spanish Ministerio de Ciencia, Innovación y Universidades ( IJC2018-038162-I and IJC2019-042207-I ).

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@article{a8e4e60d01a046fe92b4966f1282a1c5,

title = "Enhancement of formic acid production from carbon dioxide hydrogenation using metal-organic frameworks: Monte Carlo simulation study",

abstract = "Formic acid production from CO2 allows the reduction of carbon dioxide emissions while synthesizing a product with a wide range of applications. CO2 hydrogenation is challenging due to the cost of transition metal catalysts and the toxicity of the transition elements. In this work, the thermodynamic confinement effects of the metal–organic framework UiO-66 on the CO2 hydrogenation to formic acid were studied by force field-based molecular simulations. The confinement effects of UiO-66 and the metal–organic frameworks Cu-BTC, and IRMOF-1 were compared, to assess the impact of different pore size and metal centers on the production of HCOOH. Monte Carlo simulations in the grand-canonical ensemble were performed in the frameworks, using gas phase mole fractions of CO2, H2, and HCOOH at chemical equilibrium, obtained from Continuous Fractional Component Monte Carlo simulations in the Reaction Ensemble. The adsorption isobars of the components in metal–organic frameworks were computed at 298.15 – 800 K, 1 – 60 bar. The enhancement of HCOOH production due to preferential adsorption of HCOOH in metal–organic frameworks was calculated for all studied conditions. UiO-66, Cu-BTC, and IRMOF-1 affect CO2 hydrogenation reaction, shifting the thermodynamical equilibrium toward HCOOH formation. The prevailing factor is the type of metal center in the metal–organic framework. The confinement effect of Cu-BTC turns out to exceed the enhancement caused by UiO-66, and IRMOF-1. The resulting mole fraction of HCOOH increased by ca. 2000 times compared to the gas phase at 298.15 K, 60 bar. Cu-BTC can be considered as an alternative to improve the production of HCOOH due to elimination of the high-cost temperature elevation, cost reduction of downstream processing methods, and comparable final concentration of HCOOH to the reported concentrations of formate obtained using transition metal catalysts.",

keywords = "Confinement effect, Le Chatelier's principle, Molecular simulations, Porous crystals, Thermodynamic equilibrium",

author = "Wasik, {Dominika O.} and Ana Mart{\'i}n-Calvo and Guti{\'e}rrez-Sevillano, {Juan Jos{\'e}} and David Dubbeldam and Vlugt, {Thijs J.H.} and Sof{\'i}a Calero",

note = "Funding Information: This research has been supported by the Eindhoven Institute for Renewable Energy Systems (EIRES). A. M-C and J. J. G-S, thank the Spanish Ministerio de Ciencia, Innovaci{\'o}n y Universidades (IJC2018-038162-I and IJC2019-042207-I). ",

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doi = "10.1016/j.cej.2023.143432",

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Enhancement of formic acid production from carbon dioxide hydrogenation using metal-organic frameworks: Monte Carlo simulation study. / Wasik, Dominika O.; Martín-Calvo, Ana; Gutiérrez-Sevillano, Juan José et al.
In: Chemical Engineering Journal, Vol. 467, 143432, 01.07.2023.

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

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T1 - Enhancement of formic acid production from carbon dioxide hydrogenation using metal-organic frameworks

T2 - Monte Carlo simulation study

AU - Wasik, Dominika O.

AU - Martín-Calvo, Ana

AU - Gutiérrez-Sevillano, Juan José

AU - Dubbeldam, David

AU - Vlugt, Thijs J.H.

AU - Calero, Sofía

N1 - Funding Information: This research has been supported by the Eindhoven Institute for Renewable Energy Systems (EIRES). A. M-C and J. J. G-S, thank the Spanish Ministerio de Ciencia, Innovación y Universidades (IJC2018-038162-I and IJC2019-042207-I).

PY - 2023/7/1

Y1 - 2023/7/1

N2 - Formic acid production from CO2 allows the reduction of carbon dioxide emissions while synthesizing a product with a wide range of applications. CO2 hydrogenation is challenging due to the cost of transition metal catalysts and the toxicity of the transition elements. In this work, the thermodynamic confinement effects of the metal–organic framework UiO-66 on the CO2 hydrogenation to formic acid were studied by force field-based molecular simulations. The confinement effects of UiO-66 and the metal–organic frameworks Cu-BTC, and IRMOF-1 were compared, to assess the impact of different pore size and metal centers on the production of HCOOH. Monte Carlo simulations in the grand-canonical ensemble were performed in the frameworks, using gas phase mole fractions of CO2, H2, and HCOOH at chemical equilibrium, obtained from Continuous Fractional Component Monte Carlo simulations in the Reaction Ensemble. The adsorption isobars of the components in metal–organic frameworks were computed at 298.15 – 800 K, 1 – 60 bar. The enhancement of HCOOH production due to preferential adsorption of HCOOH in metal–organic frameworks was calculated for all studied conditions. UiO-66, Cu-BTC, and IRMOF-1 affect CO2 hydrogenation reaction, shifting the thermodynamical equilibrium toward HCOOH formation. The prevailing factor is the type of metal center in the metal–organic framework. The confinement effect of Cu-BTC turns out to exceed the enhancement caused by UiO-66, and IRMOF-1. The resulting mole fraction of HCOOH increased by ca. 2000 times compared to the gas phase at 298.15 K, 60 bar. Cu-BTC can be considered as an alternative to improve the production of HCOOH due to elimination of the high-cost temperature elevation, cost reduction of downstream processing methods, and comparable final concentration of HCOOH to the reported concentrations of formate obtained using transition metal catalysts.

AB - Formic acid production from CO2 allows the reduction of carbon dioxide emissions while synthesizing a product with a wide range of applications. CO2 hydrogenation is challenging due to the cost of transition metal catalysts and the toxicity of the transition elements. In this work, the thermodynamic confinement effects of the metal–organic framework UiO-66 on the CO2 hydrogenation to formic acid were studied by force field-based molecular simulations. The confinement effects of UiO-66 and the metal–organic frameworks Cu-BTC, and IRMOF-1 were compared, to assess the impact of different pore size and metal centers on the production of HCOOH. Monte Carlo simulations in the grand-canonical ensemble were performed in the frameworks, using gas phase mole fractions of CO2, H2, and HCOOH at chemical equilibrium, obtained from Continuous Fractional Component Monte Carlo simulations in the Reaction Ensemble. The adsorption isobars of the components in metal–organic frameworks were computed at 298.15 – 800 K, 1 – 60 bar. The enhancement of HCOOH production due to preferential adsorption of HCOOH in metal–organic frameworks was calculated for all studied conditions. UiO-66, Cu-BTC, and IRMOF-1 affect CO2 hydrogenation reaction, shifting the thermodynamical equilibrium toward HCOOH formation. The prevailing factor is the type of metal center in the metal–organic framework. The confinement effect of Cu-BTC turns out to exceed the enhancement caused by UiO-66, and IRMOF-1. The resulting mole fraction of HCOOH increased by ca. 2000 times compared to the gas phase at 298.15 K, 60 bar. Cu-BTC can be considered as an alternative to improve the production of HCOOH due to elimination of the high-cost temperature elevation, cost reduction of downstream processing methods, and comparable final concentration of HCOOH to the reported concentrations of formate obtained using transition metal catalysts.

KW - Confinement effect

KW - Le Chatelier's principle

KW - Molecular simulations

KW - Porous crystals

KW - Thermodynamic equilibrium

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DO - 10.1016/j.cej.2023.143432

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SN - 1385-8947

VL - 467

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Enhancement of formic acid production from carbon dioxide hydrogenation using metal-organic frameworks: Monte Carlo simulation study

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