MOFs耦合木材复合材料在环境修复方面应用研究进展OA北大核心CSTPCD
Research Progress in the Application of MOFs Coupled Wood Composites in Environmental Remediation
在中国积极倡导"绿水青山就是金山银山"的绿色发展理念下,开发高效、低成本、零污染的先进可循环污染物去除技术,对于实现"绿水青山"目标至关重要.然而,当前主流的污染物去除技术,如活性炭吸附、高级氧化、膜分离等,虽具备成本优势,却常伴随去除效率低、能耗高及二次污染等问题.在此背景下,以纳米材料为核心的环境纳米技术(涵盖吸附、催化、膜分离等领域)凭借其高效性和功能多样性,在环境修复领域引发了广泛关注.金属有机骨架材料(MOFs)作为一类由金属离子与有机配体构筑的、具有1~3维结构的多功能晶态材料,因其有序的孔道结构、丰富的化学组成及高比表面积,在环境修复领域展现出良好的应用前景.然而,MOFs的粉末形态及其固有的易碎性、不宜加工性及低相容性,限制了其在回收、成型等方面的应用,从而阻碍了其在实际场景中的广泛推广.生物质材料,特别是木材,因其种类丰富、成本低廉及天然的高孔隙率等特性,在环境修复领域备受青睐.木材的多维孔道结构、丰富的羟基/羧基官能团以及良好的加工性能,使其成为固定粉末状MOFs的理想载体.近年来,国内外学者利用木材的这些本征特性,将MOFs作为新型载体,引入功能化纳米粒子或非均相催化剂等活性组分,构建了一系列新型复合结构体系,这些体系在木材、纤维素、凝胶等生物质及其衍生物基复合材料的制备和生物质催化转化中展现出巨大潜力.本文系统阐述了 MOFs与木材的耦合策略,包括混合浸泡法、真空浸渍法、溶剂热法及原位生长法等,并深入解析了 MOFs负载于木材表面形成MOFs/木材复合材料的机理,如物理吸附、润湿作用、毛细现象及构造成核位点等.同时,梳理并总结了当前MOFs材料在生物质及其衍生化学品领域的研究进展,重点讨论了 MOFs/木材复合材料在气相污染物吸附、重金属离子去除、有害颗粒物过滤及高级氧化等环境修复领域的应用现状,并阐明了 MOFs微观结构设计与复合材料宏观性能之间的内在联系.最后,展望了 MOFs/木材复合材料未来发展所面临的机遇与挑战,为构建面向环境实际应用的MOFs基复合材料提供了新视角,有望进一步推动其在环境修复领域的广泛应用.
In light of the national advocacy that"green waters and green mountains are golden mountains and silver mountains,"developing ad-vanced,recyclable pollutant removal technologies that are efficient,cost-effective,and pollution-free has become crucial.Traditional technolo-gies such as activated carbon adsorption,advanced oxidation,and membrane separation remain prevalent due to their low cost.However,these methods often suffer from low efficiency,high energy consumption,and secondary pollution issues.Environmental nanotechnology,centered on nanomaterials(including adsorption,catalysis,and membrane separation),has attracted significant attention for its high efficiency and functional diversity.Metal-organic frameworks(MOFs),multifunctional crystalline materials composed of metal ions and organic ligands,exhibit structures ranging from one-dimensional to three-dimensional.As an emerging class of porous materials,MOFs offer promising applications in environ-mental remediation due to their ordered pores,rich structures,and extensive surface area.However,the crystal structure of MOFs typically results in a powdered form that is inherently fragile,unsuitable for processing,and low compatibility.These limitations hinder their recycling,pro-cessing,and molding,severely restricting their practical application.Biomass materials have attracted great interest globally due to their diversity,low cost,and inherent high porosity.Wood,one of the most common and abundant biomass materials,features a natural multidimensional pore structure,abundant hydroxyl/carboxyl groups,and good processability,making it an ideal substrate for immobilizing powdered MOFs.In recent years,scholars have used its intrinsic structure and characteristics to introduce functional nanoparticles or heterogeneous catalysts and other act-ive components to build a new structural system with MOFs as a novel carrier,which has emerged as a current research focus and is progress-ively being applied in the development of biomass and its derivatives-based composites such as wood,cellulose,gel,and in the catalytic conver-sion of biomass.The expanding foundational research demonstrates considerable potential for application.Accordingly,this study comprehens-ively introduces the coupling strategies between MOFs and wood,such as mixed immersion,vacuum immersion,solvothermal,and in situ growth methods.In addition,the mechanisms of MOFs loading onto wood to a couple of MOF/wood composite materials,such as physical adsorption,the wetting mechanism,capillary phenomenon,self-growth pressure,and nucleation sites,are revealed.The study also summarizes the represent-ative achievements in the application research of MOF materials in biomass and its derived chemicals.Based on this,the current application status of these MOF/wood composites in environmental remediation fields such as gas phase adsorption,heavy metal ion removal,harmful particle fil-tration,and advanced oxidation is discussed,and the correlation between the microstructure design of MOFs and the macroscopic performance of the composite materials is clarified.Finally,the opportunities and challenges faced in developing MOF/wood composite materials are explored.This review provides a new perspective on the design and construction of MOF-based composite materials for practical environmental applica-tions,which is anticipated to enhance their application in environmental remediation.
彭荣富;朱新锋;王军宁;张金辉;王超海;翟尚儒
大连工业大学轻工与化学工程学院,辽宁大连 116034||河南城建学院市政与环境工程学院,河南平顶山 467041河南城建学院市政与环境工程学院,河南平顶山 467041大连工业大学轻工与化学工程学院,辽宁大连 116034||浙江科技大学环境与资源学院,浙江杭州 310023
环境科学
金属有机骨架材料(MOFs)木材环境修复水处理
Metal-organic frameworks(MOFs)woodenvironmental remediationwater treatment
《工程科学与技术》 2024 (004)
11-23 / 13
国家自然科学基金项目(22206080;22178037);河南省科技攻关项目(232102321050;232102521009)
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