Pore space partition of metal-organic frameworks for gas storage and separation

IF 22.2 Q1 CHEMISTRY, MULTIDISCIPLINARY
Anh N. Hong , Huajun Yang , Xianhui Bu , Pingyun Feng
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引用次数: 24

Abstract

Pore space partition (PSP) concept is a synthetic design concept and can also serve as a structure analysis method useful for next-step synthetic planning and execution. PSP provides an integrated chemistry-topology-focused tool to design new materials platforms. While PSP is no less effective for making large-pore materials, the growing importance of small-molecule gas storage and separation for green-energy applications provides impetus for developing small-pore materials for which the PSP strategy is uniquely suited. Currently, the best embodiment of the PSP concept is the partitioned-acs (pacs) platform in which both fine or coarse adjustments to the building blocks have sparked a transformation of a prototype framework into a huge and continuously expanding family of chemically robust materials with controllable pore metrics and functionalities suitable for tailored applications. The pacs compositional diversity results from the platform's intrinsic multi-module nature, geometric flexibility and tolerance towards individual module variations, and mutual structure-directing effects among various modules, all of which combine to enable the molecular-level uniform co-assemblies of chemical components rarely seen together elsewhere. In this contribution, we present an overview of different pore space engineering methods and how different MOF materials have contributed to important advances in chemical stability, industrial gas storage and gas separation. In particular, we will focus on synthetic assembly of the pacs system, highlighting the differences of pacs materials from other MOF platforms and advantages of pacs materials in enhancing various MOF properties.

Abstract Image

储气分离用金属-有机骨架的孔隙空间划分
孔隙空间划分(PSP)概念是一种综合设计概念,也可以作为一种结构分析方法,对下一步的综合规划和执行有用。PSP提供了一个集成的化学拓扑工具来设计新的材料平台。虽然PSP在制造大孔材料方面同样有效,但小分子气体储存和分离在绿色能源应用中的重要性日益增加,这为开发小孔材料提供了动力,而PSP策略是唯一适合的。目前,PSP概念的最佳体现是分区acs (pacs)平台,在该平台中,对构建块进行精细或粗略的调整,引发了原型框架向巨大且不断扩展的化学坚固材料家族的转变,这些材料具有可控制的孔隙指标和适合定制应用的功能。pacs的成分多样性源于平台固有的多模块特性、几何灵活性和对单个模块变化的容忍度,以及各个模块之间的相互结构导向效应,所有这些因素结合在一起,使化学成分在分子水平上均匀地协同组装在一起,在其他地方很少见到。在这篇文章中,我们概述了不同的孔隙空间工程方法,以及不同的MOF材料如何在化学稳定性、工业气体储存和气体分离方面取得重要进展。我们将特别关注pacs系统的合成组装,突出pacs材料与其他MOF平台的区别,以及pacs材料在提高各种MOF性能方面的优势。
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来源期刊
EnergyChem
EnergyChem Multiple-
CiteScore
40.80
自引率
2.80%
发文量
23
审稿时长
40 days
期刊介绍: EnergyChem, a reputable journal, focuses on publishing high-quality research and review articles within the realm of chemistry, chemical engineering, and materials science with a specific emphasis on energy applications. The priority areas covered by the journal include:Solar energy,Energy harvesting devices,Fuel cells,Hydrogen energy,Bioenergy and biofuels,Batteries,Supercapacitors,Electrocatalysis and photocatalysis,Energy storage and energy conversion,Carbon capture and storage
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