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Proceedings of ESCAPE 35ISSN: 2818-4734
Volume: 4 (2025)
Table of Contents
LAPSE:2025.0322
Published Article
LAPSE:2025.0322
Physics-based and data-driven hybrid modelling and dynamic adaptive multi-objective optimization of chemical reactors for CO2 capture via enhanced weathering
Yalun Zhao, Jin Xuan, Lei Xing
June 27, 2025
Abstract
Enhanced weathering (EW) of alkaline minerals in chemical reactors with a controlled environment is recognized as a promising approach for gigaton-level carbon dioxide removal. However, reactor configuration and operating conditions must be optimized to balance the interfacial areas between gas, liquid and solid phases prior to industrial application. We developed a physics-based and data-driven hybrid modelling approach, coupled with multi-objective optimization, to study and compare three typical chemical reactors, i.e., trickle bed, packed bubbling columns, and stirred slurry reactors, and the optimal design to improve CO2 capture rate and reduce energy and water consumptions. Then an adaptive optimization is proposed to dynamically adjust the operating of the reactors in response to intermittent CO2 emission and renewable energy supply. Results indicated that forced stirring enhances CO2 capture rates by accelerating mass transport but increases energy consumption. Trickle bed reactor achieves the highest capture rate and lowest energy and water consumption. The AI-enabled, multi-objective, and adaptive optimization developed in response to intermittent CO2 and energy supplies shows considerable potential for industrial applications, advancing progress towards achieving SDG #13.
Record ID
LAPSE:2025.0322
Keywords
Carbon Dioxide Capture, Chemical reactors, Data-driven, Enhanced weathering, Optimization
Subject
Numerical Methods and Statistics
Suggested Citation
Zhao Y, Xuan J, Xing L. Physics-based and data-driven hybrid modelling and dynamic adaptive multi-objective optimization of chemical reactors for CO2 capture via enhanced weathering. Systems and Control Transactions 4:1059-1064 (2025) https://doi.org/10.69997/sct.186688
Author Affiliations
Zhao Y: University of Surrey, School of Chemistry and Chemical Engineering, Guildford, UK
Xuan J: University of Surrey, School of Chemistry and Chemical Engineering, Guildford, UK
Xing L: University of Surrey, School of Chemistry and Chemical Engineering, Guildford, UK
Journal Name
Systems and Control Transactions
Volume
4
First Page
1059
Last Page
1064
Year
2025
Publication Date
2025-07-01
DOI:
https://doi.org/10.69997/sct.186688
Version Comments
Original Submission
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PII: 1059-1064-1299-SCT-4-2025, Publication Type: Journal Article
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References Cited
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