三维共价有机框架的后合成修饰

三维共价有机框架(3D COFs)是一种由有机构筑基元通过共价键连接而成的三维网状晶态有机多孔材料,具有高比表面积、复杂孔道结构和大量开放功能位点,在气体吸附与分离及催化等领域展现出了独特的应用前景.由功能基团构筑3D COFs可赋予其特征的性质及功能,然而普遍采用的直接构筑法可能存在合成困难、功能基团不兼容及结构解析...     

共价有机框架新应用: 选择性水解二维共价有机框架制备有机纳米管

共价有机框架(covalent organic frameworks,COFs)是一类晶态有机多孔聚合物,它们通过多官能团有机单体分子缩聚形成共价键连接的二维或三维拓展网格结构[1].遵循“框架化学”构筑原理[2],COFs的结构可被预先设计并精确构筑.这类新颖材料的显著特点是其内部分布高度有序的纳米孔道且孔道形状和大小可通过改变聚合单体的对称性和尺寸进行精确调节.此外,从构效关系的角度考虑,多孔和共轭结构特征[3]使其在物质吸附、储存与分离、催化、光电和传感检测等领域均得到了引人注目的应用[4].尽管如此,开辟COFs新应用的需求仍然十分迫切.     

碳碳键链接的二维共价有机框架研究进展

二维共价有机框架(Two-dimensional Covalent-Organic Frameworks, 2D COFs)是指一类由π-共轭构筑单元通过共价键连接形成的具有二维拓扑结构的晶态多孔材料.由于其独特的周期性多孔结构、高比表面积、优异的稳定性等特点在离子传输、光电材料、催化等领域展现出了巨大的应用潜力.其中,碳碳键链接的共价有机框架因兼具优异的稳定性和良好的结晶性,被认为是最具有前景的二维聚合物材料之一.近年来,基于不同的设计原则和合成策略涌现出了许多具有不同结构和优异性能的碳碳键链接共价有机框架.在这篇综述中,按照构筑单元的拓扑结构对碳碳键链接共价有机框架进行分类,并归纳总结了迄今为止C=C和C—C键链接的二维共价有机框架在合成方法、结构创新、性能提升以及实际应用领域的研究进展.该综述旨在为相关领域的研究人员更好地设计和合成具有多种功能的多孔结晶材料提供参考,从而促进碳碳键链接共价有机框架材料在光电领域的进一步发展和应用.     

有机模板协助构建的动态共价大环

本文详细综述了有机模板协助而形成的动态共价大环。有机模板具有比金属离子更大的尺寸,因此可以诱导形成具有较大尺寸的大环结构。同时,有机模板结构具有多样性,可以通过化学反应进行按需修饰。可逆共价键有很多种,在模板诱导下形成大环结构的主要有三类:硫硫键、硼酸酯和希夫碱。硫硫键和硼酸酯的动态可逆性可以通过改变外界条件来开关。而希夫碱则可以通过还原转化为动力学稳定的共价键。因此,这类模板诱导而形成的热力学稳定大环可以转化为相应的动力学稳定大环,为大环主体的合成提供了一个新的途径。此外,动态共价大环的主客体键合模块还可以被用来构建更加复杂的超分子结构,例如轮烷和锁烃等。     

共价有机框架COF66/COF366的电子结构:从单体到二维平面聚合物

二维共价有机骨架(COFs)是由有机小分子结构单元通过共价键连接形成的一类新型的、具有周期性多孔网络框架结构的结晶性聚合物,在未来的光电功能材料领域有着优异的应用前景.因此,研究COFs结构与性质之间的内在关系,并以此反馈分子设计,将对此类光电功能材料的发展有着至关重要的意义.以共价有机框架66(COF66)和共价有机框架366(COF366)为例,分析了有机构建单元、COFs片段分子和周期性二维平面聚合物前线轨道能级/分布以及电子性质,阐述了有机构建单元与COFs电子结构之间的内在关系.计算结果表明,有机构建单元小分子的几何构型会影响其二维周期性平面聚合物的结构.另外,有机构建单元自身的前线轨道能级的相对位置会直接影响到COFs片段分子前线轨道的能级和分布,也决定了片段分子的电离势和电子亲和能.COFs周期性结构的电子性质与片段分子相似.因此,有机构建单元的前线轨道能级以及匹配情况决定了COFs周期性结构的电子性质.除此之外,中心分子和连接分子之间的共轭相互作用越大,电子耦合作用也相应较大,价带顶和导带底则会相对比较分散,会更有助于载流子在二维平面结构内的迁移.     

共价有机框架材料研究进展

共价有机框架材料是一类具有周期性和结晶性的有机多孔聚合物。共价有机框架材料由轻质元素通过共价键连接,拥有较低的密度、高的热稳定性以及固有的多孔性,在气体吸附、非均相催化、能量存储等研究领域有着广泛的应用潜力,引起了科学界强烈的研究兴趣。本文主要综述了近年来共价有机框架材料的最新研究进展,包括其结构设计、合成、纯化、表征以及在气体吸附,催化及光电等方面的应用,并对共价有机框架材料未来的发展趋势进行了展望。     

共价有机框架材料在多相催化领域的研究进展（英文）

共价有机框架(COFs)材料是近年来在拓扑学基础上发展起来的一类新型有机多孔聚合物,是有机单体通过可逆共价键连接而形成的晶型多孔材料,具有拓扑结构"可设计"、比表面积大、结构规整、孔道均一、孔径可调节以及易于修饰和功能化等优点.与金属有机框架材料(MOFs)相比,由于COFs是以共价键连接形成空间网络结构,具有较好的热稳定性和化学稳定性,又被称为"有机分子筛".COFs的构筑单体为有机小分子,有机小分子来源广泛而且种类繁多,使得构筑单体多样化,便于通过构筑单体来调控目标材料的结构和功能.自2005年首次报道以来,COFs以其独特的结构和优越的性能,吸引了广大科研工作者的极大兴趣,对其结构设计、可控合成、结构解析以及功能探索成为了研究热点,在气体吸附与分离、光电材料等领域展现出了广阔的应用前景.特别是在催化领域,由于COFs材料的多孔性、敞开的孔道结构、良好的稳定性以及易于修饰的特点,采用COFs作为催化剂以及催化剂载体受到了人们普遍的关注.作为催化剂,COFs可分为本征型催化剂和负载型催化剂.本征型催化剂的设计方法是基于"自下而上"策略将催化活性中心嵌入材料骨架之中;负载型催化剂的设计方法是以COFs为载体,通过后修饰方式负载金属颗粒或离子来构建多相催化剂.本征型COFs催化剂是在分子水平上引入催化活性中心,具有活性位点均匀分散、数量可控的特点,而且COFs规整均一的孔道结构有利于底物的传质,也为择形催化提供了可能;负载型催化剂通过后修饰方式引入催化活性中心,由于COFs以共价键连接,催化剂稳定性较高.COFs载体具有较大的比表面积,使得催化活性位点分散性好,也有利于底物与催化活性位点的结合.本文综述了COFs作为多相催化剂在催化领域的发展状况,按照COFs引入催化活性位点的类别,如单催化位点、双催化位点以及负载的金属纳米粒子进行了细致的阐述,重点讨论了COFs催化剂的设计理念、制备方式、功能化策略、材料的稳定性、催化活性以及选择性等内容.此外,对COFs作为光催化剂以及电催化剂方面的研究也进行了详细的介绍.最后,我们讨论了COFs在未来催化领域所面临的问题及挑战,并展望了COFs在超分子催化以及酶催化等方面的应用前景.     

二维有机组装体的可控制备

二维有机组装体是一类具有特殊形貌和性质的有序结构, 有可能带来新功能和光电子领域的潜在应用, 但如何实现二维有机组装体的可控制备是尚待解决的问题. 针对这一问题, 我们通过对构筑基元的理性设计, 调控分子间的相互作用, 发展了三种可控制备二维有机组装体的新方法: (1)利用疏水有机阴离子作为Bola型两亲分子的抗衡离子, 能够削弱亲水头基间的静电排斥作用, 从而诱导两亲分子的组装结构从一维向二维转变; (2)基于非共价键形成超两亲分子, 通过设计和控制超两亲分子的拓扑结构, 简便有效地实现二维组装体的制备; (3)通过共价修饰或引入新的非共价键, 以限制三维结构在某一方向上的生长, 从而降低三维结构的维度, 也能实现二维组装体的可控制备. 未来, 上述研究有望进一步拓展, 并实现功能二维有机组装体的构筑.     

共价有机框架材料在光催化领域中的应用

共价有机框架(COFs)材料是有机构筑基元通过共价键连接而形成的晶态有机多孔材料. COFs具有孔道结构规整、及比表面积高等特点,被广泛地应用于气体储存与分离、催化、传感、储能及光电转化等领域.将具有可调吸光能力的有机构筑基元引入到COFs中,可使其展现出强大的光催化潜力.近年来, COFs在光催化领域中发展迅猛.本文总结了COFs在光催化产氢、光催化二氧化碳还原、光催化有机反应以及光催化污染物降解等方面的研究进展,并展望了其在光催化领域的应用前景.     

共价有机框架材料在吸附领域的研究进展

共价有机框架材料(Covalent Organic Frameworks,COFs)是由有机结构单元通过共价键连接的具有期性结构的多孔化合物。共价有机框架材料具有永久的孔隙、高的比表面积、可调的孔径、易于功能化和高的水热稳定性等优点,广泛应用于许多领域。本文总结了COFs目前主要的合成方法,介绍了COFs在吸附领域的应用和发展。最后,文章指出未来的研究重点是发展更多有机反应和键连方式,合成具有高度稳定性和结晶度、成本低廉的功能性材料。     

多孔有机骨架材料对顺式二醇化合物富集分离的研究进展

基于在碱性环境下硼酸能与顺式二醇化合物可逆共价结合形成稳定的五元或六元环酯,而在酸性环境下环酯开环释放顺式二醇化合物这一特性,设计合成高效、高选择性、高富集性能的硼亲和材料的研究备受关注。近年来,许多研究工作者合成了各种类型的硼亲和材料,应用于高选择性富集顺式二醇化合物。金属有机骨架(MOFs)和共价有机骨架(COFs)由于具有孔径可调、高孔隙率、高比表面积、骨架结构可调和化学及热稳定性良好等特点,被广泛应用于色谱分离和样品前处理领域。为赋予MOFs和COFs材料对顺式二醇化合物的富集选择性,各种不同结构和不同种类的硼酸修饰的MOFs和COFs被合成出来。该综述主要是对近几年来80余篇源于科学引文索引关于硼酸功能化MOFs和COFs的种类、合成方法及其应用文章的总结,包括“金属配体-片段共组装”“合成后修饰”和“自下而上”的硼酸功能化多孔材料的修饰策略,以及硼酸功能化MOFs和COFs的种类,介绍了其在化学分析和生物分析领域的发展概况和应用前景,客观评价了硼酸功能化MOFs和COFs的区别和优缺点。该文旨在让研究人员能够充分了解近几年硼酸功能化多孔有机骨架材料的研究现状、掌握合成思路和方法,为其应用提供一定的理论指导和技术支撑,为加快硼酸功能化多孔有机骨架材料的商业化脚步贡献绵薄之力。     

Tailoring Covalent Organic Frameworks To Capture Water Contaminants

Covalent organic frameworks (COFs) are attractive materials receiving increasing interest in the literature due to their crystallinity, large surface area, and pore uniformity. Their properties can be tailored towards specific applications by judicious design of COF building blocks, giving access to tailor-made pore sizes and surfaces. In this Concept article, developments in the field of COFs that have allowed these materials to be explored for contaminant adsorption are discussed. Strategies to obtain water-stable materials with highly ordered structures and large surface areas are reviewed. Post-synthetic modification approaches, by which pore surfaces can be tuned to target specific contaminants, are described. Recent advances in COF formulations, crucial for future implementation in adsorption devices, are highlighted. At the end, future challenges which need to be addressed to allow for the deployment of COFs for the capture of water contaminants will be discussed.     

Adsorption Properties of Hydrated Cr3+ Ions on Schiff‐base Covalent Organic Frameworks: A DFT Study

Considering the superior physiochemical property, increasing efforts have been devoted to exploiting the covalent organic frameworks (COFs) materials on the environmental remediation of heavy metal ions. Water pollution caused by Cr³⁺ metal ions is of special concern for scientists and engineers. Notwithstanding all the former efforts made, it is surprising that very little is known about the interaction mechanisms between the hydrated Cr³⁺ metal ions and COF materials. In present context, density functional theory (DFT) method is used to elucidate geometric and electronic properties with the purpose of putting into theoretical perspective the application values and interaction mechanisms for COF materials on Cr³⁺ capture. The results showed that all the five selected Schiff‐base COFs materials displayed good adsorption performance on Cr³⁺ removal while the phenazine‐linked and imine‐COFs possessed the most favorable adsorption capacity due to the optimal chemical units and frameworks. The hydration effect was found to play a two‐side role in the adsorption process and interaction mechanisms, involving coordination, hydrogen bonds, as well as weak non‐covalent interactions, have been illuminated to explain the observed different adsorption behaviors. This study provides a general guidance for the design and selection of efficient COF materials as high‐capacity Cr³⁺ adsorbents.     

Thiophene-Based Covalent Organic Frameworks: Synthesis,Photophysics and Light-Driven Applications

Porous crystalline materials, such as covalent organic frameworks (COFs), have emerged as some of the most important materials over the last two decades due to their excellent physicochemical properties such as their large surface area and permanent, accessible porosity. On the other hand, thiophene derivatives are common versatile scaffolds in organic chemistry. Their outstanding electrical properties have boosted their use in different light-driven applications (photocatalysis, organic thin film transistors, photoelectrodes, organic photovoltaics, etc.), attracting much attention in the research community. Despite the great potential of both systems, porous COF materials based on thiophene monomers are scarce due to the inappropriate angle provided by the latter, which hinders its use as the building block of the former. To circumvent this drawback, researchers have engineered a number of thiophene derivatives that can form part of the COFs structure, while keeping their intrinsic properties. Hence, in the present minireview, we will disclose some of the most relevant thiophene-based COFs, highlighting their basic components (building units), spectroscopic properties and potential light-driven applications.     

共价有机框架材料固定化酶的研究进展

共价有机框架（Covalent Organic Frameworks, COFs）是一种新型的多孔材料,具有结构规整、骨架稳定、孔径结构可调等特点,被视为固定化酶的理想载体。我们主要总结了近10年来COFs材料作为载体,通过物理吸附、共价连接、包埋的固定化策略制备固定化酶的研究进展与应用,并讨论了COFs材料在酶固定化领域所面临的机遇和挑战。     

A Photoresponsive Smart Covalent Organic Framework

Ordered π‐columnar structures found in covalent organic frameworks (COFs) render them attractive as smart materials. However, external‐stimuli‐responsive COFs have not been explored. Here we report the design and synthesis of a photoresponsive COF with anthracene units as the photoresponsive π‐building blocks. The COF is switchable upon photoirradiation to yield a concavo‐convex polygon skeleton through the interlayer [4π+4π] cycloaddition of anthracene units stacked in the π‐columns. This cycloaddition reaction is thermally reversible; heating resets the anthracene layers and regenerates the COF. These external‐stimuli‐induced structural transformations are accompanied by profound changes in properties, including gas adsorption, π‐electronic function, and luminescence. The results suggest that COFs are useful for designing smart porous materials with properties that are controllable by external stimuli.     

Room‐Temperature Synthesis of Covalent Organic Frameworks with a Boronic Ester Linkage at the Liquid/Solid Interface

With various prospected applications in the field of nanoelectronics and catalysis, on‐surface synthesis of single‐layer covalent organic frameworks (surface COFs) with designable structures and properties have attracted enormous interest. Herein, we report on a scanning tunneling microscopic investigation of the surface‐confined synthesis of a covalently bonded boronic ester network directly at the octanoic acid/ highly oriented pyrolytic graphite(HOPG) interface under room temperature. The dynamic reaction process was investigated in detail. STM results indicate that the surface networks undergo structural evolution from a hybrid covalent/noncovalent multiwall porous network to single‐wall hexagonal COF with the decrease of monomer concentration. Further experimental observation disclosed that the boronic ester‐linked system is sensitive to instantaneous voltage pulses and the stimulation of the STM tip. In addition, the ¹H NMR spectra has further confirmed that the surface and octanoic acid may play important roles in promoting the reaction between 4,4′‐phenylazobenzoyl diboronic acid (ABBA) and 2,3,6,7,10,11‐hexahydroxytriphenylene (HHTP) building units.     

Covalent Organic Framework Materials for Photo/ Electrocatalytic Carbon Dioxide Reduction北大核心CSCD

Covalent organic frameworks （COFs）are a class of emerging materials connected by covalent bonds,which have high thermal/chemical stability （except boric acid COFs）,permanent porosity,large specific surface area and good crystallinity. In addition,the structure of the monomer unit in COFs is adjustable and can coordinate with many transition metal ions to provide catalytic active sites. These advantages make COFs helpful to catalyze various reactions. Among them,COFs have an excellent catalytic effect on the CO2 reduction reaction（CO2 RR）. This is mainly because the adjustable pore structure of COFs allows them to adsorb a large amount of CO2 and the π-π stacking structure in COFs can promote charge transfer, which can greatly improve the efficiency of CO2 reduction. COFs can be used as photo/ electrocatalysts to efficiently reduce CO2 to CO,CH4 ,HCOOH and other products. This review discusses the important achievements of CO2 RR catalyzed by COFs, including photo/electrocatalytic CO2 RR and photoelectric coupling CO2 RR. In addition,the future development of COFs as CO2 RR catalysts is also prospected. © 2022, Science Press (China). All rights reserved.     

Recent Advances in Covalent Organic Frameworks for Catalysis

Covalent organic frameworks (COFs) as an emerging type of crystalline porous materials, have obtained considerable attention recently. They have exhibited diverse structure and attractive performance in various catalytic reactions. It is highly expected to have a systematic and comprehensive review summing up COFs‐derived catalysts in homogeneous and heterogeneous catalysis, which is favorable to the judicious design of an efficient catalyst for targeted reaction. Herein, we focus on summarizing recent and significant developments in COFs materials, with an emphasis on both the synthetic strategies and targeted functionalization, and categorize it in accordance with the different types of catalytic reactions. Their potential catalysis applications are reviewed thoroughly. Moreover, a personal view about the future development of COFs catalysts with respect to the large‐scale production is also discussed.     

Site-Selective Synthesis and Concurrent Immobilization of Imine-Based Covalent Organic Frameworks on Electrodes Using an Electrogenerated Acid

Imine-based covalent organic frameworks (COFs) are crystalline porous materials with prospective uses in various devices. However, general bulk synthetic methods usually produce COFs as powders that are insoluble in most of the common organic solvents, arising challenges for the subsequent molding and fixing of these materials on substrates. Here, we report a novel synthetic methodology that utilizes an electrogenerated acid (EGA), which is produced at an electrode surface by electrochemical oxidation of a suitable precursor, acting as an effective Brønsted acid catalyst for imine bond formation from the corresponding amine and aldehyde monomers. Simultaneously, it provides the corresponding COF film deposited on the electrode surface. The COF structures obtained with this method exhibited high crystallinities and porosities, and the film thickness could be controlled. Furthermore, such process was applied for the synthesis of various imine-based COFs, including a three-dimensional (3D) COF structure.