Boronation of Biomass-Derived Materials for Hydrogen Storage

Compounds Pub Date : 2023-03-14 DOI:10.3390/compounds3010020
A. Lazzarini, Alessia Marino, R. Colaiezzi, O. De Luca, G. Conte, A. Policicchio, A. Aloise, M. Crucianelli
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引用次数: 2

Abstract

In spite of the widespread range of hydrogen applications as one of the greenest energy vectors, its transportation and storage still remain among the main concerns to be solved in order to definitively kickstart a rapid takeoff of a sustainable H2 economy. The quest for a simple, efficient, and highly reversible release storage technique is a very compelling target. Many studies have been undertaken to increase H2 storage efficiency by exploiting either chemisorption or physisorption processes, or through entrapment on different porous solid materials as sorbent systems. Among these, biomass-derived carbons represent a category of robust, efficient, and low-cost materials. One question that is still open-ended concerns the correlation of H2 uptake with the kind and number of heteroatoms as dopant of the carbonaceous sorbent matrix, such as boron, aiming to increase whenever possible bonding interactions with H2. Furthermore, the preferred choice is a function of the type of hydrogen use, which may involve a short- or long-term storage option. In this article, after a brief overview of the main hydrogen storage methods currently in use, all the currently available techniques for the boronation of activated carbonaceous matrices derived from recycled biomass or agricultural waste are discussed, highlighting the advantages and drawbacks of each of them.
生物质衍生储氢材料的硼化研究
尽管氢作为最环保的能源载体之一得到了广泛的应用,但为了明确启动可持续氢经济的快速起飞,氢的运输和储存仍然是需要解决的主要问题之一。寻求一种简单、有效和高度可逆的释放存储技术是一个非常引人注目的目标。许多研究都是通过化学吸附或物理吸附过程,或通过不同的多孔固体材料作为吸附系统来提高H2的储存效率。其中,生物质衍生的碳代表了一类坚固、高效和低成本的材料。一个悬而未决的问题是H2的摄取与杂原子的种类和数量的关系,杂原子作为碳质吸附剂基体的掺杂剂,如硼,旨在增加与H2的键相互作用。此外,首选是氢气使用类型的函数,可能涉及短期或长期存储选项。在本文中,在简要概述了目前使用的主要储氢方法之后,讨论了所有目前可用的用于再生生物质或农业废弃物衍生的活性炭基的硼化技术,并突出了每种技术的优点和缺点。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
2.30
自引率
0.00%
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