Characterization of the pore-surface gel phase in functionalized macroporous polymeric materials

Covalently immobilized pore-surface gel phases were prepared in a functionalized macroporous ultra-high-molecular-weight polyethylene by covalent coupling of lightly cross-linked polymer colloid particles [50% styrene, 49.8% (chloromethyl)stryrene, 0.2% divinylbenzene] to the interstitial pore surfaces. Swelling the covalently coupled colloid particles in a good solvent followed by chemical derivitization resulted in an immobilized pore-surface gel phase rich in primary amine groups. The macromolecular reactivity and molecular size-exclusion characteristics of the aminated pore-surface gel phase were then determined using monofunctional, amine-reactive, poly (ethylene glycol)s (PEG). Pegylated pore-surface gel phases that ranged from 71% (10,000 molecular weight PEG) to 56% (40,000 molecular weight PEG) PEG by weight resulted from reaction of the aminated gel phase with the PEG probe molecules. The number of PEG molecules reacting with the aminated pore-surface gel phase depends only on the Flory radius (or radius of gyration) of the PEG molecule to the negative 2.49th power i.e., 1/R _f ^2.49, corresponding to a M^−1.48 dependence. The immobilized and pegylated polymer colloid particles swell by a factor of 16–25 times the diameter of the original polymer colloid particles in water, thereby demonstrating that pegylation occurred though a substantial fraction of the volume of the immobilized colloid particles. Received: 18 January 1999 Accepted in revised form: 8 June 1999     

Nucleophilic catalysis of halide displacement from brominated poly(isobutylene-co-isoprene)

The dynamics of halide displacement from brominated poly(isobutylene-co-isoprene)(BIIR) by carboxylate nucleophiles are detailed and discussed in terms of a general reaction mechanism. The exomethylene allylic bromide isomer within BIIR is shown to undergo simultaneous S_N2 alkylation of Bu₄Nacetate and S_N2′ rearrangement with Bu₄NBr. The latter generates a Z-BrMe isomer that is more reactive toward esterification. Hence, overall polymer modification rates are auto-accelerating, as Bu₄NBr liberated by esterification catalyzes allylic bromide rearrangement to a more reactive electrophile. This knowledge of reaction mechanisms is used to develop nucleophilic catalysis techniques involving iodide intermediates.     

Selective modification of two-dimensional MoS2 nanosheets by polymer grafting

We reported on the direct creation of polymer brushes on two-dimensional molybdenum disulfide via the formation of C-S bond by UV-induced photopolymerization. The functionalization can be manipulated in forming polymer grafts on one side or both sides of the nanosheets.     

Self-organization of dipeptide-grafted polymeric nanoparticles film: A novel method for surface modification

Novel dipeptide-grafted polymeric nanoparticles were prepared by grafting the dipeptide (Gly-Gly) to a block copolymer backbone, comprised of styrene-alt-(maleic anhydride) and styrene. In aqueous solution PSt₁₃₀-b-P(St-alt-MAn)₅₈-g-GlyGly₂₆ formed stable dispersed spherical aggregates of ca. 75 nm. The critical micelle concentration for the dipeptide-grafted block copolymer self-aggregates was 6.3 × 10⁻³ mg mL⁻¹. The zeta-potential of the aggregates was estimated experimentally. The dispersed polymer nanoparticles effectively self-organized to form stable nanoparticle thin films on hydrophobic solid surfaces, such as octadecyltrichlorosilane modified glass (OTS-G). As the ionic strength and temperature of the polymer suspension increased the surface coverage of the nanoparticle film increased and its hydrophobicity (water contact angle) decreased. Significantly less bovine serum albumin (BSA) adsorbed to nanoparticles modified surfaces with compared OTS-G surfaces. Diglycine grafted polymer nanoparticles have the potential to be used as a novel platform to study protein-protein interactions and to control fouling.     

The pellicular monolith: pore-surface functionalization and surface-phase construction in macroporous polymeric materials

We report synthesis and characterization of a macroporous polymeric material containing a covalently immobilized pore-surface phase of well-defined thickness, gel-phase porosity and organic functional group content. The pore surfaces of otherwise inert macroporous (32 μm mean pore size) ultrahigh-molecular-weight polyethylene (UHMWPE) are aminated throughout using a low-pressure flowing-discharge process to enable covalent immobilization of lightly cross-linked polymer colloid particles on all pore surfaces in the monolith. Solvent swelling and chemical derivitization of the covalently immobilized polymer colloid particles produce a pore-surface gel phase of well-defined thickness, organic amine content, and gel-phase porosity. The low degree of cross-linking in the polymer colloid particles prevents dissolution of the immobilized colloid in good solvents and enables the formation of pore-surface gel phases having high gel porosity on swelling in good solvents. The pore-surface amination introduced by the flowing discharge process varies by less than 17% through 5-mm thickness of the macroporous UHMWPE material. The properties of the pore-surface gel phase also vary by less than 17% through the cross section. The pore-surface immobilized polymer colloid particles swell by a factor of 10 in water and tetrahydrofuran after derivitization with polyethylene glycol. Received: 20 November 1998 Accepted in revised form: 21 January 1999     

生物催化剂酶在高分子改性中的应用

生物催化剂酶用于高分子合成及改性的研究正在成为国外学者的一个新的研究热点，酶催化反应的专一性，高效性，高选择性及反应条件的相对温和性，使酶催化反应在高分子改性领域更具吸引力，为高分子改性开辟了一条更为清洁，更高效的途径。本文综述了近年来酶催化反应在高分子改性方面的研究进展。     

YBa2Cu3O7-x/Thermoplastic polymer composite thermistors

Conducting YBa₂Cu₃O_7-x was incorporated in to polyethylene matrices to produce composite materials with low room temperature resistivity and sizable positive temperature coefficient (PTC) resistance effects. The intensity of the PTC effect for these composites was found to be as large as 10 orders of magnitude. The location of the PTC phenomenon is determined by the choice of polymer matrix. The mechanism for the PTC effect in crystalline polymer composites is related to the percolation behaviour of the composites and the thermal expansion of the polymer matrix.     

Blending to Make Nonhealable Polymers Healable: Nanophase Separation Observed by CP/MAS 13C NMR Analysis

Can commodity polymers are made to be healable just by blending with self-healable polymers? Here we report the first study on the fundamental aspect of this practically challenging issue. Poly(ether thiourea) (PTUEG₃; T_g=27 °C) reported in 2018 is extraordinary in that it is mechanically robust but can self-heal even at 12 °C. In contrast, poly(octamethylene thiourea) (PTUC₈; T_g=50 °C), an analogue of PTUEG₃, cannot heal below 92 °C. We found that their polymer blend self-healed in a temperature range above 32 °C even when its PTUEG₃ content was only 20 mol %. Unlike PTUEG₃ alone, this polymer blend, upon exposure to high humidity, barely plasticized, keeping its excellent mechanical properties due to the non-hygroscopic nature of the PTUC₈ component. CP/MAS ¹³C NMR analysis revealed that the polymer blend was nanophase-separated, which possibly accounts for why such a small amount of PTUEG₃ provided the polymer blend with humidity-tolerant self-healable properties.     

Effect of Polymer and Surfactant‐Polymer Couples on the Acid-Catalyzed Hydrolysis of Phenyl Urea

The mechanism of the hydrolysis decomposition of phenyl urea in acid, polymer, and surfactant‐polymer media was investigated, the addition‐elimination mechanism with rate determining attack of water at N‐protonated substrate having already been studied. This study has introduced the polymer PEG (MW‐400) and (surfactant‐polymer) (ceteyl trimethyl ammonium bromide‐poly ethylene glycol) (CTAB‐PEG), (cetyl pyridinium bromide‐polyethylene glycol) (CPC‐PEG) (sodium dodecyl sulphate‐poly ethylene glycol) (SDS‐PEG), (Triton X‐100‐poly ethylene glycol) (TX‐100‐PEG), and (Brij35‐poly ethylene glycol) (Brij35‐PEG) in acid media. The results indicate that the presence of polymer and surfactant‐polymer enhances the rate of reaction at 80°C in the presence of 0.9 M H₂SO₄. Kinetic studies show that the reaction obeyed first‐order kinetics. The reaction kinetics can be well explained by micellar catalysis models like the PPIE.     

Polymers to Selectively Remove Oxidizing Anions from Non-Oxidizing Anions and NO3 − and NO2 − and NO2 − From Polluted Waters

Abstract

A copolymer of 1-phenyl-2-diethylaminoethyl-p-aminobenzoate and polyvinyl-benzyl chloride was found to have a greater capacity for NO₃ ^? and NO₂ ^? than a previously reported nitron polymer but did not react as rapidly. The resin is readily regenerated with NH₄OH or NH₄Cl and is not affected by the pH of the water over the range of 4–10.

A copolymer of 1-(4′-nitrophenyl)-2-diethyl aminoethyl-p-nitrobenzoate and polyvinylbenzyl chloride was found to react nearly as fast as the nitron polymer and have a larger capacity for NO₃ ^? and NO₂ ^?.     

Synthesis and characterization of a new network polymer electrolyte containing polyether in the main chains and side chains

A new network polymer electrolyte matrix with polyether in the side chains and main chains was synthesized by the azo-macroinitiator method and urethane reaction. The macroinitiator, polymer and network polymer were confirmed by Fourier-transform infrared (FT-IR) spectroscopy and ¹H NMR. FT-IR was also used to study the environment of lithium ions doped in these network polymer electrolytes. Three important groups are considered: N-H, carbonyl, and ether groups. The thermal properties of the polymer electrolytes were measured by differential scanning calorimetry and thermogravimetric analysis. The T_g value of this polymer is less than that of a general comb-like polymer. Added lithium ions interact with the oxygen atoms on ether groups, causing the T_g of the polymer electrolyte to increase. Moreover, the interaction between lithium ions and ether groups decreases the decomposition temperature of the polymer. The conductivity measured by AC impedance reached a maximum of 10⁻⁴ S cm⁻¹. A plot of conductivity vs. temperature fit the Vogel-Tamman-Fulcher equation, indicating that ionic mobility in this network polymer electrolyte is coupled to segmental chain movements.     

两性离子在高分子膜表面功能化改性中的研究进展

两性离子的合成工艺简单,官能团适用性强,且在水溶液中具有较强的水合能力与抑制蛋白质吸附性,因此两性离子在高分子膜表面的功能化改性中显示出很大的优势。将两性离子接枝于高分子膜表面可得到抗污染性强,血液相容性好,环境刺激响应性迅速的功能化膜。两性离子功能化改性高分子膜不仅能广泛应用于水处理和医务治疗中的人工器官材料、血浆分离等领域,在生物医药工业中的蛋白质浓缩、净化与分离等方面同样显示出巨大的应用空间。     

端基功能化聚合物的表面性能

综述了端基功能化聚合物表面结构与性能的最新研究进展.聚合物端基功能化是实现聚合物表面改性的一种有效技术.通过端基功能化可以精确控制聚合物表面功能基团的种类和数量,从而影响聚合物表面的化学结构与性能.重点论述了功能化端基在聚合物表面的离析现象和产生这一现象的原因,以及功能化端基对聚合物表面分子运动能力的影响.本文还介绍了近年来用于研究端基功能化聚合物表面的表征新技术,如SFG、NR、SSIMS等.对端基功能化聚合物表面的环境响应性也进行了阐述.指出了利用不同功能化端基可以有效地控制聚合物表面的亲疏水性.并对端基功能化聚合物的应用进行了展望.     

高分子药物学的研究进展与期盼

自从20世纪70年代提出高分子前药的概念以来,伴随着纳米技术的发展,"高分子药物学"作为高分子科学和材料学、纳米科学、药物学、临床医学、分析科学的交叉学科,正在悄然形成.本文综述了近年高分子药物在药物化学、制剂学、药效学等方面所取得的进展,概述了高分子药物的药理学和药代动力学与小分子药物的区别与联系,指出了高分子药物药效学、药理学和药代动力学研究中的难题和瓶颈,特别是高分子药物可能存在的"三种状态"及从"纳米颗粒药"到"单个高分子药"再到"小分子药"的转变,分析了高分子药输送过程中存在的多重屏障如毛细血管壁、细胞外基质和细胞壁等,阐述了高分子药物的"生理靶向"和"EPR"效应的竞争,指出了高分子药在靶向输送和逆转耐药方面的优势,强调了发展相关分析方法的必要性,期盼高分子科学家与药物学家进行真诚有效的合作,大力促进我国高分子药物学和高分子药物产业的创新和发展.     

Branched versus linear polyisoprene: Fractionation and phase behavior

Branched polyisoprene (PI) was prepared from PI-macromonomers. Linear byproducts of the synthesized polymer were removed by means of inverse spin fractionation, using the solvent cyclohexane (CH) and the precipitant acetone (AC). A well-defined fraction (M_w = 17.5 kg/mol, M_w/M_n = 1.8) of the branched polyisoprene obtained in this manner was used to determine different phase diagrams with branched and/or linear PI in the mixed solvent CH/AC at 25 °C. For comparable molar masses of the polymers the two-phase area is smallest for the branched PI and slightly larger for the linear PI; in the case of the unfractionated original sample of the branched polymer one observes a pronounced peninsula of immiscibility extending into the region of high CH concentrations. This feature is attributed to a large miscibility gap between the branched and the linear polymer, which was studied in more detail for the ternary system CH/branched PI/linear PI.     

Electrochemical characterization of plasticized polymer electrolytes based on ABS/PMMA blends

Electrochemical characteristics of plasticized polymer electrolytes based on poly(acrylonitrile-butadene-styrene) and poly(methyl methacrylate) (abbreviated as ABS/PMMA) blends have been studied. The ionic conductivity of the polymer electrolyte with an ABS/PMMA ratio of 6/4 and a plasticizer content of 60% was highest when the LiClO₄ content was 4.8%. The transference numbers (T ₊) of the polymer electrolytes were measured using the steady-state current method, and the T ₊ values were found to be less than 0.5. The electrolyte system was found to have an electrochemical stability window up to 4.5 V. The properties of the electrode interface in contact with the polymer electrolyte were also investigated by impedance spectroscopy, and the evolution of these spectra as a function of storage time was explained and interpreted using a solid-polymer layer (SPL) model. The time evolution of the impedance parameters indicated that a passivation film grew rapidly on the lithium surface immediately after assembly of the cell. Electronic Publication     

超临界二氧化碳在聚合物整体接枝改性中的应用

聚烯烃膜的整体改性是优化其性能并增加附加值的重要途径之一。常用的方法是在溶液中或者熔融状态下均相共混或接枝,但是对于那些既不溶解亦不熔融的聚合物,非均相法将是最佳的选择。而利用超临界二氧化碳可以将反应单体溶胀进入聚合物基体当中进行聚合反应,生成聚合物共混或接枝聚合物。本文综述了近年来超临界二氧化碳在固相聚烯烃整体接枝改...     

A new click reaction generated AIE-active polymer sensor for Hg2+ detection in aqueous solution

We described herein a new AIE-active polymer sensor incorporating triazole moiety for Hg²⁺ detection in aqueous solution. The polymer sensor P1 was synthesized from tetraphenylethene and diazidobenzene via click reaction. It shows typical AIE feature, and emits cyan fluorescence in the mixture of tetrahydrofuran and water, reaching the strongest fluorescence when the fraction of water (f_w) is 90%. In aqueous solution (f_w?=?90%), the polymer sensor can exhibit fluorescence quenching response towards Hg²⁺ over other competing metal ions, with the fluorescence color changed from cyan to almost no emission, which can be clearly observed by the naked eyes under 365?nm UV lamp.     

Role of plasticizer's dielectric constant on conductivity modification of PEO-NH4F polymer electrolytes

The addition of plasticizer to the polyethylene oxide (PEO)-ammonium fluoride (NH₄F) polymer electrolytes has been found to result in an increase in conductivity value and the magnitude of increase has been found to depend upon the dielectric constant of the plasticizer used. The addition of dimethylacetamide as a plasticizer with dielectric constant (?=37.8) higher than that of PEO (?∼5) results in an increase of conductivity by more than three orders of magnitude whereas the addition of diethylcarbonate as a plasticizer with dielectric constant (?=2.82) lower than that of PEO does not enhance the conductivity of PEO-NH₄F polymer electrolytes. The increase in conductivity has further been found to depend upon the concentration of plasticizer, the concentration of salt in the polymer electrolyte as well as on the dielectric constant value of the plasticizer used. The conductivity modification with the addition of plasticizer has been explained on the basis of dissociation of ion aggregates formed in PEO-NH₄F polymer electrolytes at higher salt concentrations.     

Oxidation of halides by redox enhanced ferricyanide in the [Fe---CN---Pt]n coordination polymer: an optically triggered process

The mechanism of photolysis for a cyanometalate coordination polymer composed of [(NC)₅Fe^II---CN---Pt^IV(NH₃)₄]_n repeat units, is deduced based on the results of several photogalvanic techniques. These techniques are validated through characterization of the previously established photochemistry of [(NC)₅Fe^II---CN---Pt^IV(NH₃)₄---NC---Fe^II(CN)₅]⁴⁻. Analysis of the polymer photoproducts indicates the presence of iron centers with a redox potential higher than that of the expected photoproduct, ferricyanide. Additionally, the charge collected at the electrode surface is greater than the number of iron centers freed from the polymer network by photolysis. A mechanism based on the creation of oxidized ferricyanide centers with multiple bridging cyanides is proposed. Each bridging cyanide to a Pt center increases the redox potential of the associated ferricyanide center. Ferricyanide centers with a sufficient number of bridging cyanides have redox potentials high enough to oxidize various halides to the corresponding halogen. The ability to convert chloride to chlorine suggests potential applications in the area of solar energy conversion.