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用于储能应用的孔隙率可调金属有机框架(MOF)基复合材料:最新进展

Porosity Tunable Metal-Organic Framework (MOF)-Based Composites for Energy Storage Applications: Recent Progress.

作者信息

Laeim Huddad, Molahalli Vandana, Prajongthat Pongthep, Pattanaporkratana Apichart, Pathak Govind, Phettong Busayamas, Hongkarnjanakul Natthawat, Chattham Nattaporn

机构信息

Department of Physics, Faculty of Science, Kasetsart University, Bangkok 10900, Thailand.

Department of Physics, B.M.S. College of Engineering, Bull Temple Road, Bengaluru 560019, India.

出版信息

Polymers (Basel). 2025 Jan 8;17(2):130. doi: 10.3390/polym17020130.

DOI:10.3390/polym17020130
PMID:39861203
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11768229/
Abstract

To solve the energy crisis and environmental issues, it is essential to create effective and sustainable energy conversion and storage technologies. Traditional materials for energy conversion and storage however have several drawbacks, such as poor energy density and inadequate efficiency. The advantages of MOF-based materials, such as pristine MOFs, also known as porous coordination polymers, MOF composites, and their derivatives, over traditional materials, have been thoroughly investigated. These advantages stem from their high specific surface area, highly adjustable structure, and multifunctional nature. MOFs are promising porous materials for energy storage and conversion technologies, according to research on their many applications. Moreover, MOFs have served as sacrificial materials for the synthesis of different nanostructures for energy applications and as support substrates for metals, metal oxides, semiconductors, and complexes. One of the most intriguing characteristics of MOFs is their porosity, which permits space on the micro- and meso-scales, revealing and limiting their functions. The main goals of MOF research are to create high-porosity MOFs and develop more efficient activation techniques to preserve and access their pore space. This paper examines the porosity tunable mixed and hybrid MOF, pore architecture, physical and chemical properties of tunable MOF, pore conditions, market size of MOF, and the latest development of MOFs as precursors for the synthesis of different nanostructures and their potential uses.

摘要

为了解决能源危机和环境问题,创建有效且可持续的能量转换和存储技术至关重要。然而,传统的能量转换和存储材料存在若干缺点,例如能量密度低和效率不足。基于金属有机框架(MOF)的材料,如原始MOF(也称为多孔配位聚合物)、MOF复合材料及其衍生物,相对于传统材料的优势已得到充分研究。这些优势源于其高比表面积、高度可调节的结构以及多功能性质。根据对其众多应用的研究,MOF是用于能量存储和转换技术的有前景的多孔材料。此外,MOF已用作合成用于能源应用的不同纳米结构的牺牲材料,以及用作金属、金属氧化物、半导体和配合物的支撑基底。MOF最引人入胜的特性之一是其孔隙率,这在微观和介观尺度上允许有空间,揭示并限制了它们的功能。MOF研究的主要目标是创建高孔隙率的MOF,并开发更有效的活化技术以保留和利用其孔隙空间。本文研究了孔隙率可调的混合和杂化MOF、孔隙结构、可调MOF的物理和化学性质、孔隙条件、MOF的市场规模,以及MOF作为合成不同纳米结构的前驱体的最新进展及其潜在用途。

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