Green polymer chemistry using nature's catalysts,enzymes

The use of enzymes as catalysts for organic synthesis has become an increasingly attractive alternative to conventional chemical catalysis. Enzymes offer several advantages including high selectivity, ability to operate under mild conditions, catalyst recyclability, and biocompatibility. Although there are many examples in the literature involving enzymes for the synthesis of polymers, our search showed that very little had been done in the area of polymer modification. In this article, we will discuss enzyme catalysis in general and highlight our recent results concerning precision polymer functionalization using enzymatic catalysis—“green polymer chemistry.” © 2009 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 47: 2959–2976, 2009     

非高分子专业《高分子化学与物理》教学中的几点体会

高分子科学已渗透于各个领域与学科,形成了一个无法替代的交叉学科,因此,工科化学或材料相关专业纷纷开设高分子相关课程。《高分子化学与物理》作为哈尔滨工程大学材料化学专业的主干课之一,包括高分子化学和高分子物理两个侧面,其中高分子化学部分侧重高分子合成的基本理论知识,高分子物理部分则侧重于高分子的结构与性能。本文分析了高分子化学与物理的课程特点,总结了在课堂教学中采取的行之有效的措施和教学尝试,介绍了在课堂教学过程中,如何导入心理教育,提高学生的学习兴趣。     

A rechargeable battery based on hydrophilic radical polymer electrode and its green assessment

Abstract

A hydrophilic radical polymer electrode-based rechargeable battery was designed along the concept of green chemistry. A hydrophilic radical polymer, poly(2,2,6,6-tetramethylpiperidinyloxy-4-yl vinylether), was synthesized as an electrode-active material; its battery demonstrated a high charging–discharging rate and long cycle life. The combination of the hydrophilic polymer electrode and an aqueous electrolyte for the battery fabrication was expected to provide safety improvements such as a low ignition risk besides the high battery performance. The green characteristics were studied using the “i-Messe,” an evaluation method proposed by the committee of the Green Sustainable Chemistry Network, Japan. The electrode-active polymer was evaluated for substantial improvements in disaster safety and health safety.     

Recent advances of CuAAC click reaction in building cyclic polymer

Cyclic polymers have attracted more and more attentions in recent years because of their unique topological structures and characteristic properties in both solution and bulk state. There are relatively few reports on cyclic polymers, partly because of the more demanding synthetic procedures. In recent years, “click” reaction, especially Cu(I)-catalyzed azide-alkyne cycloaddition (CuAAC), has been widely utilized in the synthesis of cyclic polymer materials because of its high efficiency and low susceptibility to side reactions. In this review, we will focus on three aspects: (1) Constructions of monocyclic polymer using CuAAC “click” chemistry; (2) Formation of complex cyclic polymer topologies through CuAAC reactions; (3) Using CuAAC “click” reaction in the precise synthesis of molecularly defined macrocycles. We believe that the CuAAC click reaction is playing an important role in the design and synthesis of functional cyclic polymers.     

Electrochemical Synthesis of Organic Polysulfides from Disulfides by Sulfur Insertion from S8 and an Unexpected Solvent Effect on the Product Distribution

An electrochemical synthesis of organic polysulfides through sulfur insertion from elemental sulfur to disulfides or thiols is introduced. The highly economic, low-sensitive and low-priced reaction gives a mixture of polysulfides, whose distribution can be influenced by the addition of different amounts of carbon disulfide as co-solvent. To describe the variable distribution function of the polysulfides, a novel parameter, the “absorbance average s ulfur a mount in p olysulfides” (SAP) was introduced and defined on the basis of the “number average molar mass” used in polymer chemistry. Various organic polysulfides were synthesized with variable volume fractions of carbon disulfide, and the yield of each polysulfide was determined by quantitative ¹³C NMR. Moreover, by using two symmetrical disulfides or a disulfide and a thiol as starting materials, a mixture of symmetrical and asymmetrical polysulfides could be obtained.     

Photocatalyzed thiol–alkene coupling: Mechanistic study and polymer synthesis

Due to the “click” chemistry characteristics of the thiol–ene reaction, these transformations have been gaining an increasing amount of attention in current chemical research. The high efficiency and selectivity of these transformations have been useful for many areas of study, from small molecule organic synthesis, to polymer synthesis and functionalization, to bio‐conjugation reactions. In this work, a study of a novel method of photochemical thiol–ene reactions using alkyl halides and an tris[2‐phenylpyridinato‐C2,N]iridium(III) (Ir(ppy)₃) photocatalyst is investigated. This process is shown to progress rapidly and has the benefit of low catalyst and initiator concentrations relative to reagents as well as mild conditions associated with photochemical processes. To understand the mechanism of this process, catalyst and initiator concentrations and other reaction conditions are varied. To demonstrate the utility of this process, a step‐growth thiol–ene polymer is synthesized using dithiol and diene monomers and a crosslinked polymer network is synthesized as well. © 2019 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2019, 57, 1931–1937     

Biomass-based green chemistry: sustainable solutions for modern economies

Abstract

Biomass and renewable raw materials are the basis and driver for an even greater alignment of industry to the principles of green chemistry and sustainability. Nature provides a remarkably wide range of renewable raw materials with varying properties and differing chemical compositions. Renewable raw materials are therefore especially interesting as alternatives to fossil resources for energy generation and as starting materials for industrial chemistry. Since various forms of biomass are also essential for human nutrition and animal feed, their use as feedstocks for other purposes must be balanced. Ideally, the biomass remaining after the nutritious components are removed can serve as a feedstock. Examples of applications that use biomass as starting materials include adhesives, textile and leather, cosmetics, cleaning agents, coatings, paints, printing inks, crop protection, lubricants and dietary supplements.     

Core-shell particles: building blocks for advanced polymer materials

Polymer particles with submicrometer dimensions show promising applications in “bottom-to-top approach” to fabrication of materials with periodic structure, function, and composition. A novel approach to producing such materials is proposed, which employs core-shell particles with specific structures and compositions. We report on the synthesis of core-shell particles using interfacial polymerization and heterocoagulation techniques. The compositions of core-forming material and/or the shell-forming polymers were selectively controlled to be make the cores or the shells rigid or fluid, fluorescent or non-fluorescent, organic or inorganic. Several potential applications of nanocomposite materials obtained from these particles are demonstrated, including three-dimensional optical data storage and optical limiting and switching.     

绿色化学理念在高分子化学实验教学中的渗透

绿色化学是促进人类与自然和谐发展的化学,培养绿色化学意识是实现社会可持续发展的基本要求。高分子化学实验是高等院校高分子材料专业或材料化学高分子方向本科生开设的一门必修课,对学生进行绿色化学教育具有非常有利的条件。文章分析了在高分子化学实验课程中开展绿色化学教育的必要性与可行性;介绍了高分子化学实验教学中开展绿色化学教育的具体措施。通过绿色化学理念在高分子化学实验教学中渗透,在提高学生动手能力的同时,又增强了学生的绿色化学意识。     

Porous polymer monoliths for extraction: diverse applications and platforms

Polymer monoliths are becoming increasingly popular as sorbent materials, and, along with silica monoliths, they are sometimes touted as replacements for the particulate stationary phases used in HPLC. This critical and prospective review shows how polymer monoliths are in fact finding numerous extraction roles that do not resemble HPLC. They are showing great promise as extractors in a remarkable range of platforms, formats and hyphenated systems with functions ranging from chromatographic preconcentration to large-scale preparative extraction. Monolith surface chemistry, morphology and the approaches to monolith synthesis are discussed with regards to these emerging roles.     

Polymer Networks: From Plastics and Gels to Porous Frameworks

Polymer networks, which are materials composed of many smaller components—referred to as “junctions” and “strands”—connected together via covalent or non‐covalent/supramolecular interactions, are arguably the most versatile, widely studied, broadly used, and important materials known. From the first commercial polymers through the plastics revolution of the 20^th century to today, there are almost no aspects of modern life that are not impacted by polymer networks. Nevertheless, there are still many challenges that must be addressed to enable a complete understanding of these materials and facilitate their development for emerging applications ranging from sustainability and energy harvesting/storage to tissue engineering and additive manufacturing. Here, we provide a unifying overview of the fundamentals of polymer network synthesis, structure, and properties, tying together recent trends in the field that are not always associated with classical polymer networks, such as the advent of crystalline “framework” materials. We also highlight recent advances in using molecular design and control of topology to showcase how a deep understanding of structure–property relationships can lead to advanced networks with exceptional properties.     

The reactor polymer alloys: The shifting of the frontier of polymer research

The discovery (1968) of the high yield Ziegler-Natta catalysts based on active MgCl₂ was the beginning of a scientific and industrial revolution that has brought about the creation of superactive, isospecific, spheriform fourth generation catalytic systems. The rationalization of the polymer/catalyst replication phenomenon and the understanding of the catalyst “architecture” effects on polymer shape and morphology has led to the exploitation of the “Reactor Granule Technology”. This has made the generation of a broad range of homo, copolymers and multiphase alloys (Catalloy) possible by synthesis, most of which having a previously unobtainable spectrum of performance (Refs. 1,2,3). The reactor granule technology concept has also been the basis for the achievement of a family of polyolefin/non polyolefin alloys with engineering properties. More recently, the reactor granule approach has been extended so as to couple the advantages of both heterogeneous and homogeneous metallocene catalysts (mixed catalysis), thus allowing the synthesis of a very new family of “in situ” polyolefin alloys.     

Novel biobased photo‐crosslinked polymer networks prepared from vegetable oil and 2,5‐furan diacrylate

Novel biobased crosslinked polymer networks were prepared from vegetable oil with 2,5‐furan diacrylate as a difunctional stiffener through UV photopolymerization, and the mechanical properties of the resulting films were evaluated. The vegetable oil raw materials used were acrylated epoxidized soybean oil (AESO), acrylated castor oil (ACO), and acrylated 7,10‐dihydroxy‐8(E)‐octadecenoic acid (ADOD). 2,5‐Furan dicarboxylic acid (FDCA), which can be synthesized through the oxidative dehydration of C6 sugars, was identified by the US Department of Energy as one of 12 priority chemicals for establishing the green chemistry industry of the future. 2,5‐Furan dimethanol (bis‐hydroxymethylfuran), which can be derived from FDCA, was used as a starting material to synthesize 2,5‐furan diacrylate, which was used as a biobased comonomer along with AESO, ACO, or ADOD to form photo‐crosslinked polymer networks. The synthesis of acrylate derivatives was confirmed using FT‐IR and ¹H‐NMR spectroscopic techniques. The composition of the reaction mixture was changed to obtain crosslinked polymer networks with various mechanical properties. The addition of 2,5‐furan diacrylate increased the tensile strengths of the polymer films by up to 1.4–4.2 times relative to those obtained without the addition. These fully biobased polymers derived from vegetable oil and sugar can be used as environmentally friendly renewable materials for various applications to replace the existing petroleum‐based polymers currently used. Copyright © 2013 John Wiley & Sons, Ltd.     

Adaptive Catalytic Systems for Chemical Energy Conversion

The rapidly growing importance of green hydrogen and renewable carbon resources as essential feedstocks for sustainable chemical value chains opens room for disruptive innovations regarding chemical production processes. The fluctuation and variability associated with non-fossil energy and raw material supply holds many challenges for catalysts to cope with the resulting dynamics. However, many new opportunities also arise once catalyst design starts to aim at performance that is “adaptive” rather than “task-specific”. In this Scientific Perspective, we propose to define adaptivity in catalysis on the basis of three essential properties that are reversibility, rapidity, and robustness (R³ rule). Promising design strategies and selected examples are described to substantiate the scientific concept and to highlight its potential for chemical energy conversion.     

Design of coke-free methane dry reforming catalysts by molecular tuning of nitrogen-rich combustion precursors

The valorization of methane and carbon dioxide is a promising solution for mitigating global warming. The dry reforming of methane (DRM) is capable of concomitant conversion of these greenhouse gases into starting materials for production of synthetic fuels, promoting a carbon neutral avenue for fuel production. The development of efficient, stable, and economic catalysts presents a challenge owing to the comparatively rapid deactivation of DRM catalysts under reaction conditions. Here, Ni/La₂O₃ DRM catalysts are prepared by combustion synthesis of Ni and La complexes of nitrogen-rich precursors. We expound the relationship between structures of the combustion precursors, the thermochemistry of their combustion, the structures of the resultant Ni/La₂O₃ catalysts, and their performance under DRM conditions. We show that the best catalyst is derived from energetic precursor which has the sharpest exotherm and rapidly releases the largest amounts of nitrogen gas. These properties give rise to the crystallization of the Ni/La₂O₃ catalyst with high Ni dispersion and strong metal-support interactions. This work can act as starting point to expand the link between the chemistry of combustion precursors and the resulting catalyst properties, eventually realizing the rational design of high-performance catalysts prepared by combustion synthesis through tailoring the chemistry and structure of the nitrogen-rich precursors.     

Construction of ionic liquid-Pd/C based bifunction catalysts for the synthesis of UV-P

Adding light stabilizers to polymeric materials can inhibit or delay the light aging effect and improve the light resistance of materials. 2-(2′-Hydroxy-5′-methylphenyl) benzotriazole (UV-P), as a typical benzotriazole ultraviolet absorber, is widely used in various polymer synthetic materials and products owning to its outstanding oil resistance, color change resistance and low volatility. Currently, it is of great theoretical and practical significance to develop an environmentally friendly method to produce UV-P. Here, we introduce ionic liquids, tetra-butyl ammonium hydroxide, into the palladium-based catalyst, design a “transfer hydrogenation site - alkaline site” duel active center system, and investigate the physical and chemical properties and possible mechanism of this bifunction catalyst system. Such heterogeneous catalytic transfer hydrogenation method can remain 100% conversion and 93.86% selectivity. This bifunction catalyst also shows an outstanding stability when it was used for ten times, proving a green and efficient transfer hydrogenation method for the synthesis of UV-P.     

Strongly stretched polymer brushes

Polymer “brushes” are formed when long-chain molecules are somehow attached by one end at an interface with a relatively small area per chain. Such adsorbed brushes in the presence of solvent may be used to modify surface properties, stabilize colloidal particles, etc. Strongly segregated block copolymer phases, or interfacial layers of such “polymeric surfactants” may also be modeled in terms of “melt brushes,” (i.e., brushes without solvent). In both cases, when chain attachments are crowded on the interface, the chains stretch out to avoid neighboring chains. The resulting physical state has properties markedly different from polymer solutions, gels, or weakly adsorbed polymer layers. When the chains are strongly stretched, their statistical mechanics become simpler, as fluctuations around the set of most probable conformations are suppressed. This makes possible many pencil-and-paper calculations of brush properties, including bending and compressional moduli, and detailed knowledge of the chain conformations. As a recent example, I will describe calculations of phase diagrams of strongly segregated block copolymers including bicontinuous double-diamond phases. © 1994 John Wiley & Sons, Inc.     

非金属催化剂在催化环氧化物和CO2合成环状碳酸酯中的研究进展

随着科学技术的进步和工业化的发展,大量化石燃料被消耗,大气中二氧化碳浓度急剧增加,导致温室效应加剧,严重威胁到人类的生存和发展。基于可持续发展的思想,利用储量丰富且廉价的二氧化碳作为 C1资源替代有毒的气体(如一氧化碳和光气等)制备具有广泛应用的环状碳酸酯,不仅满足“绿色化学”的要求,而且符合“原子经济性”的原则。迄今为止,大量用于催化二氧化碳和环氧化物环加成反应合成环状碳酸酯的催化剂,包括均相催化剂(如金属卤化物、有机碱、离子液体和金属配合物),多相催化剂(如金属氧化物、负载型催化剂、有机聚合物、金属有机框架材料和碳材料等)被报道。其中金属催化剂占主导地位,大多表现出优异的催化活性。然而,目前可供开采的金属矿越来越少,大多数金属的回收再利用率较低,重金属污染日趋严重。因此,开发新型、廉价、绿色、高效、循环性和稳定性好的非金属催化剂具有重要意义。
　　本文主要介绍了近3年以来用于催化二氧化碳和环氧化物环加成反应合成环状碳酸酯的非金属催化剂,主要包括有机碱、离子液体、固载型催化剂、有机聚合物和碳材料等。概括了不同种类催化剂的设计思想及其催化反应机理,重点阐述了分子内以及分子间各种功能基团的协同作用对环加成反应的影响。通过比较发现,具有“C–N=C”结构的有机碱活性相对较高,氢键给体和亲核物质都能与有机碱协同作用提高其催化活性;传统离子液体的活性一般不理想,氢键给体如羟基和羧基的引入有利于促进环加成反应,且多阳离子和多氢键给体功能化的离子液体表现出更高的催化活性;负载型催化剂中,载体和活性组分之间的协同作用有利于加速环加成反应的进行,多种功能基团负载和以共价键方式多层固载能更好地提高催化剂稳定性和催化活性;利用非烯烃化合物制得的活性组分位于主链的多孔有机聚合物,催化活性和稳定性大多高于活性组分位于侧链的烯烃聚合物;碳材料催化剂中,引入不饱和的 N物种(如伯胺和吡啶氮),有利于 CO2的吸附和活化,能促进环加成反应。此外,利用密度泛函的方法,计算模拟催化反应过程,能更好地揭示反应机理,并为设计和制备高效的催化剂提供理论指导。
　　该领域目前面临的重要挑战是研发可以同时实现二氧化碳捕获和转化的新型、环保和高效非金属催化剂,终极目标是利用多孔催化材料在常温和常压下直接捕获工业废气中的二氧化碳,并利用捕获的二氧化碳实现环状碳酸酯的连续生产。基于协同催化的设计思想,利用多种基团功能化的策略合成高效吸附和活化二氧化碳以及开环活化环氧化物的非金属催化剂,有望实现上述目标。     

Aliphatic polyester polymer stars: synthesis, properties and applications in biomedicine and nanotechnology

A critical review: the ring-opening polymerization of cyclic esters provides access to an array of biodegradable, bioassimilable and renewable polymeric materials. Building these aliphatic polyester polymers into larger macromolecular frameworks provides further control over polymer characteristics and opens up unique applications. Polymer stars, where multiple arms radiate from a single core molecule, have found particular utility in the areas of drug delivery and nanotechnology. A challenge in this field is in understanding the impact of altering synthetic variables on polymer properties. We review the synthesis and characterization of aliphatic polyester polymer stars, focusing on polymers originating from lactide, ε-caprolactone, glycolide, β-butyrolactone and trimethylene carbonate monomers and their copolymers including coverage of polyester miktoarm star copolymers. These macromolecular materials are further categorized by core molecules, catalysts employed, self-assembly and degradation properties and the resulting fields of application (262 references).     

Ruthenium-Catalyzed Synthesis of Cyclic and Linear Acetals by the Combined Utilization of CO2, H2, and Biomass Derived Diols

Herein a transition-metal catalyst system for the selective synthesis of cyclic and linear acetals from the combined utilization of carbon dioxide, molecular hydrogen, and biomass derived diols is presented. Detailed investigations on the substrate scope enabled the selectivity of the reaction to be largely guided and demonstrated the possibility of integrating a broad variety of substrate molecules. This approach allowed a change between the favored formation of cyclic acetals and linear acetals, originating from the bridging of two diols with a carbon-dioxide based methylene unit. This new synthesis option paves the way to novel fuels, solvents, or polymer building blocks, by the recently established “bio-hybrid” approach of integrating renewable energy, carbon dioxide, and biomass in a direct catalytic transformation.