用于可持续阻燃聚合物材料的金属有机框架及其衍生物

Geng Huang , Ye-Tang Pan , Lubin Liu , Pingan Song , Rongjie Yang
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摘要

生物质资源是天然聚合材料,资源丰富、价格低廉、无毒且可再生。虽然它们在日常生活和高科技材料中有着广泛的应用,但其使用往往受到相关火灾危险的限制。为解决这一问题,人们对开发阻燃生物质聚合物材料的兴趣与日俱增。金属有机框架(MOFs)由过渡金属物种、阻燃元素和潜在碳源组成,可轻松调整其结构和特性。这种多功能性使 MOFs 及其衍生物和混合物在阻燃研究中极具吸引力。尽管 MOFs 具有独特的性能,但仅靠它们可能无法完全满足商业阻燃应用的需求。MOFs 与生物质材料的结合已被认为是开发高效阻燃生物质纳米复合材料的一种有前途的策略。这种创新方法旨在利用协同效应来解决 MOFs 的局限性。本综述重点介绍了结合生物质材料的 MOF 基阻燃剂的最新进展和策略,阐明了 MOF/生物质纳米复合材料的阻燃机理,为该领域未来的设计工作提供参考。此外,该综述还讨论了该领域当前面临的挑战和前景,旨在为研究人员提供简明而全面的概述,以便他们快速掌握最新进展。
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Metal-organic frameworks and their derivatives for sustainable flame-retardant polymeric materials
Biomass resources are natural polymeric materials that are abundant, affordable, non-toxic and renewable. Although they find diverse applications in both everyday life and high-tech materials, their use is often constrained by the associated fire hazards. To address this issue, there is a growing interest in the development of flame-retardant biomass polymeric materials. Metal-organic frameworks (MOFs) consist of transition metal species, flame-retardant elements and potential carbon sources, allowing for easy adjustment of their structure and properties. This versatility makes MOFs and their derivatives and hybrids highly attractive for flame retardancy studies. Despite their distinctive properties, MOFs alone may not fully satisfy the demands of commercial flame-retardant applications. The combination of MOFs with biomass materials has been identified as a promising strategy for developing efficient flame-retardant biomass nanocomposites. This innovative approach aims to address the limitations of MOFs by capitalizing on synergistic effects. This review highlights recent advancements and strategies in MOF-based flame retardants incorporating biomass materials, and it elucidates the flame-retardant mechanisms of MOF/biomass nanocomposites to inform future design efforts in the field. Furthermore, the review discusses the current challenges and prospects in this field, aiming to provide a succinct yet comprehensive overview for researchers to quickly grasp the latest developments.
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