Machine learning for CO2 capture and conversion: A review

IF 9.6 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Energy and AI Pub Date : 2024-03-30 DOI:10.1016/j.egyai.2024.100361

Sung Eun Jerng , Yang Jeong Park , Ju Li

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Abstract

Coupled electrochemical systems for the direct capture and conversion of CO $_{2}$ have garnered significant attention owing to their potential to enhance energy- and cost-efficiency by circumventing the amine regeneration step. However, optimizing the coupled system is more challenging than handling separated systems because of its complexity, caused by the incorporation of solvent and heterogeneous catalysts. Nevertheless, the deployment of machine learning can be immensely beneficial, reducing both time and cost owing to its ability to simulate and describe complex systems with numerous parameters involved. In this review, we summarized the machine learning techniques employed in the development of CO $_{2}$ capture solvents such as amine and ionic liquids, as well as electrochemical CO $_{2}$ conversion catalysts. To optimize a coupled electrochemical system, these two separately developed systems will need to be combined via machine learning techniques in the future.

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二氧化碳捕获和转化的机器学习：综述

用于直接捕获和转化二氧化碳的耦合电化学系统因其通过规避胺再生步骤来提高能源和成本效率的潜力而备受关注。然而，由于溶剂和异相催化剂的加入，耦合系统的优化比处理分离系统更具挑战性。然而，由于机器学习能够模拟和描述涉及众多参数的复杂系统，因此它可以减少时间和成本，对机器学习的应用大有裨益。在本综述中，我们总结了在开发二氧化碳捕集溶剂（如胺和离子液体）以及二氧化碳电化学转化催化剂时所采用的机器学习技术。为了优化耦合电化学系统，未来需要通过机器学习技术将这两个单独开发的系统结合起来。

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