A perspective on data-driven screening and discovery of polymer membranes for gas separation, from the molecular structure to the industrial performance

IF 4.9 3区 工程技术 Q1 ENGINEERING, CHEMICAL Reviews in Chemical Engineering Pub Date : 2023-11-20 DOI:10.1515/revce-2023-0021
Eleonora Ricci, Maria Grazia De Angelis
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引用次数: 0

Abstract

In the portfolio of technologies available for net zero-enabling solutions, such as carbon capture and low-carbon production of hydrogen, membrane-based gas separation is a sustainable alternative to energy-intensive processes, such as solvent-based absorption or cryogenic distillation. Detailed knowledge of membrane materials performance in wide operative ranges is a necessary prerequisite for the design of efficient membrane processes. With the increasing popularization of data-driven methods in natural sciences and engineering, the investigation of their potential to support materials and process design for gas separation with membranes has received increasing attention, as it can help compact the lab-to-market cycle. In this work we review several machine learning (ML) strategies for the estimation of the gas separation performance of polymer membranes. New hybrid modelling strategies, in which ML complements physics-based models and simulation methods, are also discussed. Such strategies can enable the fast screening of large databases of existing materials for a specific separation, as well as assist in de-novo materials design. We conclude by highlighting the challenges and future directions envisioned for the ML-assisted design and optimization of membrane materials and processes for traditional, as well as new, membrane separations.
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从分子结构到工业性能,数据驱动的气体分离聚合物膜筛选和发现的观点
在可用于实现净零排放解决方案的技术组合中,如碳捕获和低碳制氢,膜基气体分离是一种可持续的替代能源密集型工艺,如溶剂基吸收或低温蒸馏。在广泛的操作范围内,对膜材料性能的详细了解是设计高效膜工艺的必要前提。随着数据驱动方法在自然科学和工程领域的日益普及,研究它们支持膜气体分离材料和工艺设计的潜力受到越来越多的关注,因为它可以帮助缩短从实验室到市场的周期。在这项工作中,我们回顾了几种用于估计聚合物膜气体分离性能的机器学习(ML)策略。还讨论了新的混合建模策略,其中ML补充了基于物理的模型和仿真方法。这种策略可以快速筛选现有材料的大型数据库,以便进行特定的分离,并有助于重新设计材料。最后,我们强调了传统和新型膜分离中膜材料和工艺的ml辅助设计和优化的挑战和未来方向。
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来源期刊
Reviews in Chemical Engineering
Reviews in Chemical Engineering 工程技术-工程:化工
CiteScore
12.30
自引率
0.00%
发文量
37
审稿时长
6 months
期刊介绍: Reviews in Chemical Engineering publishes authoritative review articles on all aspects of the broad field of chemical engineering and applied chemistry. Its aim is to develop new insights and understanding and to promote interest and research activity in chemical engineering, as well as the application of new developments in these areas. The bimonthly journal publishes peer-reviewed articles by leading chemical engineers, applied scientists and mathematicians. The broad interest today in solutions through chemistry to some of the world’s most challenging problems ensures that Reviews in Chemical Engineering will play a significant role in the growth of the field as a whole.
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