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Main Authors: van Dongen, N., van Hoof, A. J. F., Calero, S., Vicent-Luna, J. M.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.06400
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author van Dongen, N.
van Hoof, A. J. F.
Calero, S.
Vicent-Luna, J. M.
author_facet van Dongen, N.
van Hoof, A. J. F.
Calero, S.
Vicent-Luna, J. M.
contents Direct air capture of carbon dioxide (CO$_2$) is one of the most promising strategies to mitigate rising atmospheric CO$_2$ levels. Among various techniques, adsorption using porous materials is a viable method for extracting CO$_2$ from air, even under humid conditions. However, identifying optimal adsorbent materials remains a significant challenge. Moreover, the performance of existing materials can be improved by doping with active species that boost gas capture, a relatively unexplored field. In this study, we perform atomistic simulations to investigate the adsorption, structural, and energetic properties of CO$_2$ and water in realistic models of activated carbons. We first analyze the impact of explicitly considering surfaces containing functional groups, which aims to imitate the chemical environment of experimental samples. Additionally, we introduce potassium carbonate within the pores of the adsorbent to evaluate its effect on CO$_2$ and water adsorption. Our results demonstrate that both functional groups and potassium carbonate enhance adsorption, primarily by shifting the adsorption onset pressures to lower values. Specifically, potassium carbonate clusters act as extra adsorption sites for CO$_2$ and water, facilitating the nucleation of water molecules and promoting the formation of a hydrogen bond network within the activated carbon pores.
format Preprint
id arxiv_https___arxiv_org_abs_2510_06400
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Enhancing Direct Air Capture through Potassium Carbonate Doping of Activated Carbons
van Dongen, N.
van Hoof, A. J. F.
Calero, S.
Vicent-Luna, J. M.
Materials Science
Direct air capture of carbon dioxide (CO$_2$) is one of the most promising strategies to mitigate rising atmospheric CO$_2$ levels. Among various techniques, adsorption using porous materials is a viable method for extracting CO$_2$ from air, even under humid conditions. However, identifying optimal adsorbent materials remains a significant challenge. Moreover, the performance of existing materials can be improved by doping with active species that boost gas capture, a relatively unexplored field. In this study, we perform atomistic simulations to investigate the adsorption, structural, and energetic properties of CO$_2$ and water in realistic models of activated carbons. We first analyze the impact of explicitly considering surfaces containing functional groups, which aims to imitate the chemical environment of experimental samples. Additionally, we introduce potassium carbonate within the pores of the adsorbent to evaluate its effect on CO$_2$ and water adsorption. Our results demonstrate that both functional groups and potassium carbonate enhance adsorption, primarily by shifting the adsorption onset pressures to lower values. Specifically, potassium carbonate clusters act as extra adsorption sites for CO$_2$ and water, facilitating the nucleation of water molecules and promoting the formation of a hydrogen bond network within the activated carbon pores.
title Enhancing Direct Air Capture through Potassium Carbonate Doping of Activated Carbons
topic Materials Science
url https://arxiv.org/abs/2510.06400