共轭微孔聚合物的制备与应用

共轭微孔聚合物(CMPs)是一类有机多孔聚合物,与常规共轭聚合物或多孔材料相比,其最大的特点是既有π共轭骨架又具有大量微孔。这类材料在解决能源和环境问题方面显示出巨大的潜力,已在气体吸附、非均相催化、发光材料、化学传感器、电能存储和生物杂化物等领域显示出巨大的应用前景。目前已开发出多种用于CMPs结构单元设计与合成的新方法,用于制备具有不同结构和特定性质的多种CMPs,有效推动了该领域的快速发展。本综述总结了CMPs的理论模型和结构设计,合成原理、常用合成方法和影响因素分析,以及CMPs在各领域的应用。     

有机微孔聚合物研究进展

有机微孔聚合物(MOPs)是一类新型的多孔材料,具有合成方法多样、化学和物理性质稳定、孔尺寸可调控、表面可修饰等优点。近年来,MOPs在物理吸附储存气体方面表现出巨大潜力,从而在储氢和温室气体封存方面成为研究的热点之一。本文首先介绍了MOPs的结构类型及特点,分别介绍了自具微孔聚合物、超交联聚合物、共价有机网络以及共轭微孔聚合物的最新进展,分析结构与性能间的关系,并对其在催化、分离和气体储存方面的应用做了简单总结。最后对MOPs未来的研究进行了展望。     

基于水溶性共轭聚合物的蛋白质检测*

近年来,以共轭聚合物作为生物传感元件,在生物大分子（如核酸、蛋白质）特异性识别、检测方面的研究越来越受到人们的关注。共轭聚合物具有强的光捕获能力,具有倍增光学响应性,可用来放大荧光传感信号,大大提高检测的灵敏度,为生物传感器的发展提供了新的传感模式。基于共轭聚合物的新型生物传感器在医疗诊断、环境检测以及国家安全防御等方面具有广泛的应用前景。本文简要介绍了共轭聚合物的荧光信号放大机制以及在蛋白质、酶、抗原－抗体检测方面的应用。最后对共轭聚合物在蛋白质检测方面的未来发展趋势进行了展望。     

含金属配合物的共轭聚合物研究进展

综述了含金属共轭聚合物材料在分子结构设计、性能及在光电子器件领域应用等方面的最新研究进展,主要阐明了共轭聚合物或低聚物的结构和金属配合物生色团对含金属共轭聚合物材料光电特性等物理性质的影响,并指出了这类聚合物在电致发光器件及聚合物光伏器件中的潜在应用价值。     

共轭聚合物光声造影剂的研究进展

光声成像是一种新兴医学影像成像技术。作为一种非侵入式和非电离式的成像技术,光声成像具有高分辨率、高对比度和穿透深度高的特点。这种成像技术在对组织进行诊断时需要加入造影剂与组织相结合才能产生显著的光声信号。然而,目前光声成像技术仍缺乏合适的造影剂,制约了其在生物医学领域的应用。共轭聚合物因其具有优异的光热性能和良好的生物相容性,被广泛应用于光声成像领域。本文综述了共轭聚合物作为外源性造影剂在光声成像领域的应用的研究进展,并对共轭聚合物光声造影剂的发展进行了展望。     

基于能量转移机理的水溶性荧光共轭聚合物体系的设计制备及应用

水溶性共轭聚合物由于具有优异的光学性能,如强大的光捕获能力和独特的分子线效应,在化学、生物和医疗领域都有良好的应用前景。共轭聚合物受光激发后,所产生的激子可以沿着长程共轭的π骨架自由迁移,在分子骨架的任何位点都可以转移给能量受体,从而实现高效的能量传递。因此,水溶性共轭聚合物适合于构建各种能量传递体系,从而实现荧光信号放大、多色发光、活性氧产生效率提高等光学性能的优化。本文简述了基于水溶性共轭聚合物构建能量转移体系的原理和方法,总结了其在生物传感、生物成像、光动力杀菌和光动力抗癌等领域的应用,最后对水溶性共轭聚合物存在的主要问题以及未来的发展方向进行了分析和展望。     

含氟共轭微孔聚合物的制备及其吸附应用研究

共轭微孔聚合物由于其高的比表面积、优良的物理化学稳定性、多样的合成方法以及沿分子骨架延伸的共轭结构等特点,近几年得到广泛关注和快速发展.本工作以1,3,5-三氟-2,4,6-三碘苯作为含氟单体与1,3,5-三乙炔基苯通过Sonogashira偶联反应聚合得到含氟共轭微孔聚合物F-CMP.通过把氟原子引入到共轭微孔聚合物骨架中,F-CMP显示出良好的疏水性能,与水的接触角达到145°.得益于良好的疏水性能和适宜的孔隙结构,相比于骨架结构相似的不含氟共轭微孔聚合物（H-CMP）,F-CMP对油和有机溶剂的吸附量得到大幅提高,且显示出高的吸附速率和良好的吸附循环性.     

树枝状共轭聚合物研究

本文介绍了树枝状共轭聚合物的最新发展,包括全共轭、部分共轭树枝状聚合物及树枝化共轭聚合物的特点及其在电致发光、电极、传感器以及光探测等领域的功能化应用;详细讨论了包括代数、支化单元、端基、核、金属离子的络合等结构因素以及溶剂和浓度等工艺因素对电荷传输的影响;并进一步提出该领域研究前景及有待于解决的问题。     

四苯基乙烯基共轭微孔聚合物的制备及其气体吸附

共轭微孔聚合物由于其在气体吸附与分离、非均相催化和光电子等领域的巨大应用前景而广受关注. 本文以四苯基乙烯为基本构筑单元, 通过Sonogashira-Hagihara偶联反应制备了3种共轭微孔聚合物新材料, 研究了结构组成和构建模块对制备聚合物孔性能和气体吸附性能的影响. 氮气吸附测试结果表明, 由1,1,2,2-四炔四苯基乙烯自聚合制备的TPE-CMP1具有较大的比表面积, 为1096 m²·g^-1. 在1.13 bar/273 K条件下, TPE-CMP1的CO₂吸附能力为2.36 mmol·g^-1; 在1.13 bar/77.3 K条件下, TPE-CMP1对H₂的吸附能力为1.35 wt%. 另外, 制备的共轭微孔聚合物展示出较高的CO₂/N₂选择性吸附值. 由于这类多孔聚合物材料具有合成方法简单、优良的物理化学及热稳定性、高的比表面积和CO₂吸附性能, 因此将在气体吸附与分离方面具有潜在的应用前景.     

树枝状共轭聚合物研究

本文介绍了树枝状共轭聚合物的最新发展,包括全共轭、部分共轭树枝状聚合物及树枝化共轭聚合物的特点及其在电致发光、电极、传感器以及光探测等领域的功能化应用;详细讨论了包括代数、支化单元、端基、核、金属离子的络合等结构因素以及溶剂和浓度等工艺因素对电荷传输的影响;并进一步提出该领域研究前景及有待于解决的问题.     

Conjugated Microporous Polymers for Heterogeneous Catalysis

Conjugated microporous polymers (CMPs) are a class of crosslinked polymers that combine permanent micropores with π‐conjugated skeletons and possess three‐dimensional (3D) networks. Compared with conventional materials such as metal–organic frameworks (MOFs) and covalent organic frameworks (COFs), CMPs usually have superior chemical and thermal stability. CMPs have made significant progress in heterogeneous catalysis in the past seven years. With a bottom‐up strategy, catalytic moieties can be directly introduced into in the framework to produce heterogeneous CMP catalysts. Higher activity, stability, and selectivity can be obtained with heterogeneous CMP catalysts in comparison with their homogeneous analogs. In addition, CMP catalysts can be easily isolated and recycled. In this review, we focus on CMPs as an intriguing platform for developing various highly efficient and recyclable heterogeneous catalysts in organic reactions. The design, synthesis, and structure of these CMP catalysts are also discussed in this focus review.     

Regulating Charge-Transfer in Conjugated Microporous Polymers for Photocatalytic Hydrogen Evolution

Bandgap engineering in donor–acceptor conjugated microporous polymers (CMPs) is a potential way to increase the solar-energy harvesting towards photochemical water splitting. Here, the design and synthesis of a series of donor–acceptor CMPs [tetraphenylethylene (TPE) and 9-fluorenone (F) as the donor and the acceptor, respectively], F_0.1CMP , F_0.5CMP , and F_2.0CMP , are reported. These CMPs exhibited tunable bandgaps and photocatalytic hydrogen evolution from water. The donor–acceptor CMPs exhibited also intramolecular charge-transfer (ICT) absorption in the visible region (λ_max=480 nm) and their bandgap was finely tuned from 2.8 to 2.1 eV by increasing the 9-fluorenone content. Interestingly, they also showed emissions in the 540–580 nm range assisted by the energy transfer from the other TPE segments (not involved in charge-transfer interactions), as evidenced from fluorescence lifetime decay analysis. By increasing the 9-fluorenone content the emission color of the polymer was also tuned from green to red. Photocatalytic activities of the donor–acceptor CMPs ( F_0.1CMP , F_0.5CMP , and F_2.0CMP ) are greatly enhanced compared to the 9-fluorenone free polymer ( F_0.0CMP ), which is essentially due to improved visible-light absorption and low bandgap of donor–acceptor CMPs. Among all the polymers F_0.5CMP with an optimum bandgap (2.3 eV) showed the highest H₂ evolution under visible-light irradiation. Moreover, all polymers showed excellent dispersibility in organic solvents and easy coated on the solid substrates.     

An Elastic Monolithic Catalyst: A Microporous Metalloporphyrin‐Containing Framework‐Wrapped Melamine Foam for Process‐Intensified Acyl Transfer

The advent of conjugated microporous polymers (CMPs) has had significant impact in catalysis. However, the presence of only micropores in these polymers often imposes diffusion limitations, which has resulted in the low utilization of CMPs in catalytic reactions. Herein, the preparation of a foam‐supporting CMP composite with interconnective micropores and macropores and elastic properties is reported. Metalloporphyrin‐based CMP organogels are synthesized within the melamine foam by a room‐temperature oxidative homocoupling reaction of terminal alkynes. Upon drying, the CMP‐based xerogels tightly wrap the framework skeletons of the foam, while the foam cells are still open to allow for the preservation of elasticity and macroporosity. Such a hierarchical structure is efficient for acyl transfer, facilitates substrate diffusion within interpenetrative macropores and micropores, and could be used to intensify catalytic processes.     

Reversible Doping of a Dithienothiophene‐Based Conjugated Microporous Polymer

Dithienothiophene (DTT) based conjugated microporous polymers (CMPs) were synthesized by bulk and electrochemical oxidative polymerizations. Spectroelectrochemical measurements showed that DTT‐CMP can be reversibly oxidized and reduced, accompanied by a significant change of the absorption properties making the material interesting for electrochromic devices. Reversible doping and dedoping of the bulk polymer network was also observed using iodine and ammonia, respectively. Nitrogen gas sorption measurements of the neutral, doped, and dedoped polymer networks indicated the presence of iodide species within the pores, and the conductivity of the networks is highly increased upon doping with iodine. The introduction of the strong electron donor DTT into a conjugated porous network, and the ability for redox switching, make DTT‐CMPs interesting materials for organo(opto)electronic devices and sensors.     

Carbon nanofiber vs. carbon microparticles as modifiers of glassy carbon and gold electrodes applied in electrochemical sensing of NADH

Carbon materials (CMs), such as carbon nanotubes (CNTs), carbon nanofibers (CNFs), and carbon microparticles (CMPs) are used as doping materials for electrochemical sensors. The efficiency of these materials (either before or after acidic treatments) while being used as electrocatalysts in electrochemical sensors is discussed for β-nicotinamide adenine dinucleotide (NADH) detection using cyclic voltammetry (CV). The sensitivity of the electrodes (glassy carbon (GC) and gold (Au)) modified with both treated and untreated materials have been deeply studied. The response efficiencies of the GC and Au electrodes modified with CNF and CMP, using dimethylformamide (DMF) as dispersing agent are significantly different due to the peculiar physical and chemical characteristics of each doping material. Several differences between the electrocatalytic activities of CMs modified electrodes upon NADH oxidation have been observed. The CNF film promotes better the electron transfer of NADH minimizing the oxidation potential at +0.352 V. Moreover higher currents for the NADH oxidation peak have been observed for these electrodes. The shown differences in the electrochemical reactivities of CNF and CMP modified electrodes should be with interest for future applications in biosensors.     

Preparation of microporous polymer-encapsulated Pd nanoparticles and their catalytic performance for hydrogenation and oxidation

Palladium nanoparticles (Pd NPs) encapsulated by conjugated microporous polymers (CMPs) were prepared by the Pd-catalyzed polymerization followed by a thermal treatment with N₂ or H₂. The Pd catalysts were embedded in the porous network during polymerization and used as a precursor for the generation of Pd NPs in CMP. Although no Pd NPs were formed in the as-synthesized Pd/CMPs, Pd NPs with 1.6–3.5 nm size were formed after the thermal treatment. The obtained Pd/CMP-N₂ and -H₂ catalysts were highly selective in the hydrogenation of 4-nitrostyrene to 4-ethylnitrobenzene, whereas Pd NPs supported on carbon (Ketjen black) gave a fully reduced product, 4-ethylaniline. Substituents in CMP framework could change the catalytic activity of Pd NPs; hydroxy-substituted CMP encapsulated Pd NPs showed higher catalytic activity than Pd/CMP-H₂ for benzyl alcohol oxidation.     

Controlled Synthesis of Conjugated Microporous Polymer Films: Versatile Platforms for Highly Sensitive and Label‐Free Chemo‐ and Biosensing

Conjugated microporous polymers (CMPs), in which rigid building blocks form robust networks, are usually synthesized as insoluble and unprocessable powders. We developed a methodology using electropolymerization for the synthesis of thin CMP films. The thickness of these films is synthetically controllable, ranging from nanometers to micrometers, and they are obtained on substrates or as freestanding films. The CMP films combine a number of striking physical properties, including high porosity, extended π conjugation, facilitated exciton delocalization, and high‐rate electron transfer. We explored the CMP films as versatile platforms for highly sensitive and label‐free chemo‐ and biosensing of electron‐rich and electron‐poor arenes, metal ions, dopamine, and hypochloroic acid, featuring rapid response, excellent selectivity, and robust reusability.     

Complementary mobile-phase optimisation for resolution enhancement in high-performance liquid chromatography

An optimisation methodology in high-performance liquid chromatography (HPLC) is presented for the selection of two or more mobile phases having an optimal complementary resolution. The complementary mobile phases (CMPs) are selected in such a way that each one resolves optimally only some compounds in the mixture, while the remainder, resolved by the other mobile phase(s), can overlap among them. The methodology is based on the computation of a peak purity measurement for each solute, using an asymmetrical peak model for peak simulation. Two global resolution criteria (product of elementary resolutions and worst elementary resolution) and two methods for solving the problem (a systematic examination of all possible solute arrangements, and the use of genetic algorithms to expedite the calculation time) were used to find the optimal CMPs. The CMP optimisation methodology was applied to the resolution of a mixture of 10 diuretics and beta-blockers, which could not be resolved using a single mobile phase; virtual baseline resolution was achieved, however, with two CMPs.     

Polarization-induced charge separation in conjugated microporous polymers for efficient visible light-driven C-3 selenocyanation of indoles

Conjugated microporous polymers (CMPs) are cost-effective photocatalysts in organic transformations, while they are usually limited by the insufficient separation of photogenerated charges. Here we report a polarization strategy through molecular geometry optimization to promote the charge separation of CMPs. Three CMP photocatalysts with an alternative donor–acceptor skeleton and tunable symmetry were synthesized by the oxidative coupling of bis-carbazoles with electron-deficient bridges (benzene/pyridine/pyrimidine). Simply regulating the polarization of the starting monomers leads to tailorable porosity, photoelectric properties, and photocatalytic activity of the CMPs. They exhibited high efficiency in C-3 selenocyanation of indoles under visible-light and at room temperature, and pyridine-based CMPs with the largest dipole moment gave a yield of up to 94%, superior to their state-of-the-art photocatalyst counterparts. Photo-physical experiments combined with theoretical calculations further supported that the incorporation of the polarized linker introduced an internal electric field, benefitting efficient charge separation. This offered new insight into developing high-performance photocatalysts.

An internal electric field was used to promote the charge separation of conjugated microporous polymers (CMPs). Those with the largest dipole moment exhibited high efficiency in C-3 selenocyanation of indoles under visible-light and room temperature.     

Predicting Collagen Triple Helix Stability through Additive Effects of Terminal Residues and Caps

Collagen model peptides (CMPs) consisting of proline-(2S,4R)-hydroxyproline-glycine (POG) repeats have provided a breadth of knowledge of the triple helical structure of collagen, the most abundant protein in mammals. Predictive tools for triple helix stability have, however, lagged behind since the effect of CMPs with different frames ([POG]_n, [OGP]_n, or [GPO]_n) and capped or uncapped termini have so far been underestimated. Here, we elucidated the impact of the frame, terminal functional group and its charge on the stability of collagen triple helices. Combined experimental and theoretical studies with frame-shifted, capped and uncapped CMPs revealed that electrostatic interactions, strand preorganization, interstrand H-bonding, and steric repulsion at the termini contribute to triple helix stability. We show that these individual contributions are additive and allow for the prediction of the melting temperatures of CMP trimers.