Entropy-Driven Carbon Dioxide Capture: The Role of High Salinity and Hydrophobic Monoethanolamine

Aleksa Petrović; Rodrigo Lima; Peter Westh; Ji Woong Lee

doi:10.1002/aesr.202400204

Entropy-Driven Carbon Dioxide Capture: The Role of High Salinity and Hydrophobic Monoethanolamine

Aleksa Petrović, Rodrigo Lima, Peter Westh, Ji Woong Lee^*

^*Corresponding author for this work

Department of Chemistry

Research output: Contribution to journal › Journal article › Research › peer-review

1 Citation (Scopus)

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Abstract

Addressing atmospheric CO₂ levels during the transition to carbon neutrality requires efficient CO₂ capture methods. Aqueous amine scrubbing dominates large-scale flue gas capture but is hampered by the energy-intensive regeneration step, sorbent loss, and consequent environmental concerns with volatile amines. Herein, hydrophobic non-volatile alkylated monoethanolamine (MEA) is introduced as a water-lean CO₂ absorbent in brine. The effects of alkylation of MEA, salinity, and aggregation of absorbents on the improved CO₂ capture process are systematically investigated. The CO₂ absorption facilitates spontaneous self-aggregation of hydrophobic absorbents, which increases the entropy of water in high-ion strength solutions. This effect is controlled by the salinity of aqueous solutions, affording comparative gravimetric CO₂ uptake performance to benchmark MEA. It is experimentally verified that the hydrophobicity of alkylated MEAs in saline water is responsible for facile absorption, and also for mild regeneration conditions. Therefore, the entropy-driven approach minimizes absorbent evaporation, corrosion, and decomposition, thus paving the way to realize energy-efficient carbon capture.

Original language	English
Article number	2400204
Journal	Advanced Energy and Sustainability Research
Volume	5
Issue number	12
Number of pages	6
DOIs	https://doi.org/10.1002/aesr.202400204
Publication status	Published - 2024

Bibliographical note

Funding Information:
The generous support of the Department of Chemistry, University of Copenhagen, Independent Research Fond Denmark (DFF\u2010Research Project1 Thematic Research, 0217\u201000192B), The NNF\u2010CO Research Center (CORC), and the Carlsberg Fonden (CF21\u20100308) is gratefully acknowledged. We thank S.H. and G.H. for helping with the synthesis of absorbents. We also thank our friends and collaborators, who brought various seawater samples from all around the world. 2

Publisher Copyright:
© 2024 The Author(s). Advanced Energy and Sustainability Research published by Wiley-VCH GmbH.

Keywords

carbon capture
CO
entropy
hydrophobicity
sea water

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Cite this

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title = "Entropy-Driven Carbon Dioxide Capture: The Role of High Salinity and Hydrophobic Monoethanolamine",

abstract = "Addressing atmospheric CO2 levels during the transition to carbon neutrality requires efficient CO2 capture methods. Aqueous amine scrubbing dominates large-scale flue gas capture but is hampered by the energy-intensive regeneration step, sorbent loss, and consequent environmental concerns with volatile amines. Herein, hydrophobic non-volatile alkylated monoethanolamine (MEA) is introduced as a water-lean CO2 absorbent in brine. The effects of alkylation of MEA, salinity, and aggregation of absorbents on the improved CO2 capture process are systematically investigated. The CO2 absorption facilitates spontaneous self-aggregation of hydrophobic absorbents, which increases the entropy of water in high-ion strength solutions. This effect is controlled by the salinity of aqueous solutions, affording comparative gravimetric CO2 uptake performance to benchmark MEA. It is experimentally verified that the hydrophobicity of alkylated MEAs in saline water is responsible for facile absorption, and also for mild regeneration conditions. Therefore, the entropy-driven approach minimizes absorbent evaporation, corrosion, and decomposition, thus paving the way to realize energy-efficient carbon capture.",

keywords = "carbon capture, CO, entropy, hydrophobicity, sea water",

author = "Aleksa Petrovi{\'c} and Rodrigo Lima and Peter Westh and Lee, {Ji Woong}",

note = "Funding Information: The generous support of the Department of Chemistry, University of Copenhagen, Independent Research Fond Denmark (DFF\u2010Research Project1 Thematic Research, 0217\u201000192B), The NNF\u2010CO Research Center (CORC), and the Carlsberg Fonden (CF21\u20100308) is gratefully acknowledged. We thank S.H. and G.H. for helping with the synthesis of absorbents. We also thank our friends and collaborators, who brought various seawater samples from all around the world. 2 Publisher Copyright: {\textcopyright} 2024 The Author(s). Advanced Energy and Sustainability Research published by Wiley-VCH GmbH.",

year = "2024",

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volume = "5",

journal = "Advanced Energy and Sustainability Research",

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AU - Petrović, Aleksa

AU - Lima, Rodrigo

AU - Westh, Peter

AU - Lee, Ji Woong

N1 - Funding Information: The generous support of the Department of Chemistry, University of Copenhagen, Independent Research Fond Denmark (DFF\u2010Research Project1 Thematic Research, 0217\u201000192B), The NNF\u2010CO Research Center (CORC), and the Carlsberg Fonden (CF21\u20100308) is gratefully acknowledged. We thank S.H. and G.H. for helping with the synthesis of absorbents. We also thank our friends and collaborators, who brought various seawater samples from all around the world. 2 Publisher Copyright: © 2024 The Author(s). Advanced Energy and Sustainability Research published by Wiley-VCH GmbH.

PY - 2024

Y1 - 2024

N2 - Addressing atmospheric CO2 levels during the transition to carbon neutrality requires efficient CO2 capture methods. Aqueous amine scrubbing dominates large-scale flue gas capture but is hampered by the energy-intensive regeneration step, sorbent loss, and consequent environmental concerns with volatile amines. Herein, hydrophobic non-volatile alkylated monoethanolamine (MEA) is introduced as a water-lean CO2 absorbent in brine. The effects of alkylation of MEA, salinity, and aggregation of absorbents on the improved CO2 capture process are systematically investigated. The CO2 absorption facilitates spontaneous self-aggregation of hydrophobic absorbents, which increases the entropy of water in high-ion strength solutions. This effect is controlled by the salinity of aqueous solutions, affording comparative gravimetric CO2 uptake performance to benchmark MEA. It is experimentally verified that the hydrophobicity of alkylated MEAs in saline water is responsible for facile absorption, and also for mild regeneration conditions. Therefore, the entropy-driven approach minimizes absorbent evaporation, corrosion, and decomposition, thus paving the way to realize energy-efficient carbon capture.

AB - Addressing atmospheric CO2 levels during the transition to carbon neutrality requires efficient CO2 capture methods. Aqueous amine scrubbing dominates large-scale flue gas capture but is hampered by the energy-intensive regeneration step, sorbent loss, and consequent environmental concerns with volatile amines. Herein, hydrophobic non-volatile alkylated monoethanolamine (MEA) is introduced as a water-lean CO2 absorbent in brine. The effects of alkylation of MEA, salinity, and aggregation of absorbents on the improved CO2 capture process are systematically investigated. The CO2 absorption facilitates spontaneous self-aggregation of hydrophobic absorbents, which increases the entropy of water in high-ion strength solutions. This effect is controlled by the salinity of aqueous solutions, affording comparative gravimetric CO2 uptake performance to benchmark MEA. It is experimentally verified that the hydrophobicity of alkylated MEAs in saline water is responsible for facile absorption, and also for mild regeneration conditions. Therefore, the entropy-driven approach minimizes absorbent evaporation, corrosion, and decomposition, thus paving the way to realize energy-efficient carbon capture.

KW - carbon capture

KW - CO

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KW - hydrophobicity

KW - sea water

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DO - 10.1002/aesr.202400204

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