利用吸附剂和机器学习提高储氢效率:综述

IF 15 2区 环境科学与生态学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Ahmed I. Osman, Walaa Abd-Elaziem, Mahmoud Nasr, Mohamed Farghali, Ahmed K. Rashwan, Atef Hamada, Y. Morris Wang, Moustafa A. Darwish, Tamer A. Sebaey, A. Khatab, Ammar H. Elsheikh
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引用次数: 0

摘要

氢被视为未来的碳中性燃料,然而氢的储存是发展氢经济的一个关键问题,因为目前的储存技术成本高昂,并且由于压力高达 700 巴而具有潜在的不安全性。因此,最近的研究设计了先进的氢吸附剂,如金属有机框架、共价有机框架、多孔碳基吸附剂、沸石和先进复合材料,以实现更安全的氢存储。在此,我们将以氢源与生产、先进吸附剂和机器学习为重点,对氢存储进行回顾。碳基吸附剂包括石墨烯、富勒烯、碳纳米管和活性炭。我们观察到,金属有机框架的储存能力可达 10 wt.%,共价有机框架可达 6 wt.%,多孔碳基吸附剂可达 3-5 wt.%。高熵合金和先进的复合材料表现出更高的稳定性和吸氢能力。机器学习可以预测高效的储氢材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Enhanced hydrogen storage efficiency with sorbents and machine learning: a review

Enhanced hydrogen storage efficiency with sorbents and machine learning: a review

Hydrogen is viewed as the future carbon–neutral fuel, yet hydrogen storage is a key issue for developing the hydrogen economy because current storage techniques are expensive and potentially unsafe due to pressures reaching up to 700 bar. As a consequence, research has recently designed advanced hydrogen sorbents, such as metal–organic frameworks, covalent organic frameworks, porous carbon-based adsorbents, zeolite, and advanced composites, for safer hydrogen storage. Here, we review hydrogen storage with a focus on hydrogen sources and production, advanced sorbents, and machine learning. Carbon-based sorbents include graphene, fullerene, carbon nanotubes and activated carbon. We observed that storage capacities reach up to 10 wt.% for metal–organic frameworks, 6 wt.% for covalent organic frameworks, and 3–5 wt.% for porous carbon-based adsorbents. High-entropy alloys and advanced composites exhibit improved stability and hydrogen uptake. Machine learning has allowed predicting efficient storage materials.

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来源期刊
Environmental Chemistry Letters
Environmental Chemistry Letters 环境科学-工程:环境
CiteScore
32.00
自引率
7.00%
发文量
175
审稿时长
2 months
期刊介绍: Environmental Chemistry Letters explores the intersections of geology, chemistry, physics, and biology. Published articles are of paramount importance to the examination of both natural and engineered environments. The journal features original and review articles of exceptional significance, encompassing topics such as the characterization of natural and impacted environments, the behavior, prevention, treatment, and control of mineral, organic, and radioactive pollutants. It also delves into interfacial studies involving diverse media like soil, sediment, water, air, organisms, and food. Additionally, the journal covers green chemistry, environmentally friendly synthetic pathways, alternative fuels, ecotoxicology, risk assessment, environmental processes and modeling, environmental technologies, remediation and control, and environmental analytical chemistry using biomolecular tools and tracers.
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