沼气转化为甲醇作为可再生能源的改进:基于纳米材料和金属有机框架的新型催化剂的展望

IF 4.1 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Frontiers in Nanotechnology Pub Date : 2022-10-11 DOI:10.3389/fnano.2022.1012384
Antoni Sánchez
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引用次数: 0

摘要

近年来,能源的高成本和可获得性推动了获取不同类型可再生能源的战略的实施。其中,厌氧消化产生的沼气中所含的甲烷具有特殊的意义,因为它还允许管理大量有机废物,并捕获和长期储存碳。然而,沼气作为能源存在一些问题:1)沼气是一种气体,因此储存成本高且复杂;2)沼气不纯,是二氧化碳厌氧消化的主要副产物(30%-50%);3)在某些条件下与氧气发生爆炸;4)沼气具有很高的全球变暖潜能值(是二氧化碳的27-30倍)。因此,将沼气转化为甲醇是克服这些问题的一种有吸引力的方法。这个过程意味着甲烷和二氧化碳分别在一次氧化和一次还原反应中转化为甲醇。在这种双系统中,对两种反应使用有效和选择性的催化剂是一个关键问题。在这方面,嵌入金属有机框架的纳米材料最近已经对这两种反应进行了测试,与传统材料相比,结果非常令人满意。本文综述了近年来催化剂的结构,包括纳米颗粒作为活性催化剂和金属有机骨架作为支撑材料。还强调了这项技术未来发展的主要挑战,即在商业规模上发展的环境和经济成本。
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Biogas improvement as renewable energy through conversion into methanol: A perspective of new catalysts based on nanomaterials and metal organic frameworks
In recent years, the high cost and availability of energy sources have boosted the implementation of strategies to obtain different types of renewable energy. Among them, methane contained in biogas from anaerobic digestion has gained special relevance, since it also permits the management of a big amount of organic waste and the capture and long-term storage of carbon. However, methane from biogas presents some problems as energy source: 1) it is a gas, so its storage is costly and complex, 2) it is not pure, being carbon dioxide the main by-product of anaerobic digestion (30%–50%), 3) it is explosive with oxygen under some conditions and 4) it has a high global warming potential (27–30 times that of carbon dioxide). Consequently, the conversion of biogas to methanol is as an attractive way to overcome these problems. This process implies the conversion of both methane and carbon dioxide into methanol in one oxidation and one reduction reaction, respectively. In this dual system, the use of effective and selective catalysts for both reactions is a critical issue. In this regard, nanomaterials embedded in metal organic frameworks have been recently tested for both reactions, with very satisfactory results when compared to traditional materials. In this review paper, the recent configurations of catalysts including nanoparticles as active catalysts and metal organic frameworks as support materials are reviewed and discussed. The main challenges for the future development of this technology are also highlighted, that is, its cost in environmental and economic terms for its development at commercial scale.
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来源期刊
Frontiers in Nanotechnology
Frontiers in Nanotechnology Engineering-Electrical and Electronic Engineering
CiteScore
7.10
自引率
0.00%
发文量
96
审稿时长
13 weeks
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