生物降解材料

本文介绍了生物降解材料的含义、作用机理、影响微生物降解的因素、以及生物降解材料的应用,并列举了几种主要的可生物降解的材料。     

高分子材料的生物降解性能表征

生物降解能够使高分子材料回归自然界物质循环,被认为是解决塑料污染的一大重要途径.高分子材料的生物降解性能表征对相关材料开发、改性和产业应用十分重要.本文针对高分子材料的需氧生物降解,从降解产物和降解残留材料两个方面介绍常用表征方法 .降解产物的表征主要从CO2生成量、O2消耗量和小分子产物三方面开展,降解残留材料的表征围绕其组成结构变化和性能变化.介绍了各表征方法的简单原理和典型案例,并对未来发展进行了展望.     

PBS基生物降解材料的研究进展

PBS(聚丁二酸丁二醇酯 )是一种具有良好生物降解性的聚酯塑料。本文简述了PBS的基本特性、降解机理和制备方法 ,对各种PBS基生物降解材料的特性进行了分析 ,介绍了PBS基生物降解材料的研究进展     

改性淀粉材料生物降解性分析体系的建立及应用

测定了热塑性淀粉(TPS)和热塑性双醛淀粉(TPDAS)在堆肥条件下的生物降解能力。根据ISO 14855建立了一套新的测试体系并且验证了这个体系测定高分子材料生物降解性能的可行性。对热塑性淀粉材料生物降解性的测试结果发现化学改性对于淀粉的降解速率和降解速度都有很大的影响。在可控堆肥条件下TPS比TPDAS降解的要快。TPDAS的降解速度和最终的生物降解百分率和双醛淀粉(DAS)的氧化度有密切的关系。文中讨论了存在这种关系的可能原因。有不同降解速率的TPS和TPDAS的降解过程呈现出三个阶段,即迟滞阶段。降解阶段和平稳阶段。     

苯乙烯-马来酸酐共聚物的生物降解性研究

合成了一系列苯乙烯．马来酸酐共聚物(SMA)。并对共聚物的结构进行了表征。用土埋法和CO2释放法研究了共聚物的生物降解性。探讨了分子量、组成、环境等因素对生物降解性的影响,发现共聚物的分子量降低。降解率增大;共聚物中马来酸酐含量提高。降解率增大;适宜的环境有利于生物降解。     

脂肪族聚碳酸酯(PPC)与聚乳酸(PLA)共混型生物降解材料的热学性能、力学性能和生物降解性研究

通过溶液浇铸法制备了脂肪族聚碳酸酯与聚乳酸的共混物(PPC/PLA).采用示差热分析(DSC)和热重分析(TG)研究了材料的热性能.采用拉伸力学试验研究了共混物的力学性能.通过土壤悬浊拟环境培养降解实验法和扫描电子显微镜分析(SEM)对共混材料的生物降解性能进行了研究.实验结果表明,随着PPC含量的增加,共混物的拉伸强度和杨氏模量降低,而生物降解速率却显著提高.但是,在一定的降解时间内,某些比例共混物的降解速率比100%PPC还要快.综合分析表明,PPC/PLA是力学性能和降解性能可以互补的共混体系.     

纤维素纤维材料几种降解方法的研究

测试和比较了天然棉纤维织物和几种人造可再生纤维素纤维(竹原纤维、莫代尔纤维和天丝纤维)在实验室条件下和大环境堆肥条件下的生物降解性.生物降解行为的测试分别采用ASTM D5988-03、堆肥法和酶催化降解法,以比较几种织物在自然环境和微生物培养基条件下的降解速度;结合红外光谱通过分析降解前后结构的改变研究不同的降解方法对纤维素材料的降解程度.结果表明纤维素类纤维织物均表现出良好的生物降解性,并且人造可再生纤维素纤维的降解速度高于天然棉纤维.和传统的实验室条件下测量织物降解性的方法相比,堆肥中含有更多的微生物和酶活性组分,加速了纤维素材料的分解.     

竹纤维增强可生物降解复合材料研究进展

天然植物纤维增强可生物降解复合材料是一类性能优良、环境友好、可自然降解的绿色环保复合材料。众多天然植物纤维中,竹纤维不仅资源丰富、有优异的力学性能,还具有天然抗菌、除臭、吸湿放湿、抗紫外线等优点,广泛应用于复合材料的制备。本文对竹纤维增强可生物降解复合材料的增强体材料和基体材料特性、改性预处理方法、成型工艺和生物降解特性等性能评价的国内外研究现状进行了综述,同时还对竹纤维增强可生物降解复合材料的未来研究和发展趋势进行了展望。     

生物降解性聚酯

本文阐述了生物降解性聚酯的主要产品，生物降解性聚酯的降解机理及生物降解性聚合物的存在问题和研究方向．     

应用于药物控释系统中的生物降解高分子材料

生物降解高分子材料具有良好的生物相容性和生物降解性而成为人们关注的药物控释材料。本文简要介绍了生物降解高分子材料的降解机理，综述了生物降解高分子材料的发展现状，展望了今后的发展方向。     

Methods for determination of polybrominated diphenyl ethers in environmental samples - review

Polybrominated diphenyl ethers (PBDEs) are a group of persistent organic pollutants. They are used as flame retardants in plastics, paints, varnishes and textile materials. PBDEs pose great risk to the environment because of their high persistence and ability to get into the environment easily due to the lack of chemical bonds with the matrix of materials, to which they are added. Global research studies confirmed the occurrence of those compounds in the majority of elements of water and land environment. Analysis of PBDEs in environmental samples is one of the specific analytical methods of criteria that comprise low detection limits and high selectivity. The analysis of PBDEs in environmental samples is one of the specific analytical methods, in which the main criteria are low detection limits and high selectivity. In this article, a literature review of methods for environmental sample preparation and analysis of the PBDE content was presented. The article discusses the potential of modern extraction techniques such as: solid-phase microextraction, single-drop microextraction, dispersive liquid-liquid microextraction, microwave-assisted extraction, cloud point extraction, hollow fibre-liquid phase microextraction and others for the separation of PBDEs from environmental samples with a complex matrix. Among the methods for qualitative and quantitative determination of PBDEs, a particular focus was put on gas chromatography/mass spectrometry with various injection techniques and different types of sample ionisation.     

Tape polymer materials for anti-corrosion insulation of pipelines

The article discusses peculiar features of polymer tape coatings for protecting pipelines and main methods of applying them in a field environment. It is shown that the design of polymer tape coating depends on operational conditions, the conditions of the coating application, and the method of pipeline construction. The main Russian and Western insulating materials are reviewed and some of the technical characteristics of these materials are presented.     

Total scattering investigation of materials for clean energy applications: the importance of the local structure

In this Perspective article we give an account of the application of total scattering methods and pair distribution function (PDF) analysis to the investigation of materials for clean energy applications such as materials for solid oxide fuel cells and lithium batteries, in order to show the power of this technique in providing new insights into the structure-property correlation in this class of materials.     

Miniaturized sample preparation and separation methods for environmental and drug analyses.

Miniaturized extraction and separation media have been successfully developed from precisely controlled technologies. In this article, recent developments in these high performance analytical methods, such as miniaturized sample preparation methods and the coupling of these techniques with microscale separation systems, have been reviewed, along with some applications to environmental and biological analysis. The advantage of the miniaturization is not only for the environmental compatibility but also for the developments of the high performance analytical systems. Down-sizing also makes it possible to investigate and introduce various compounds and materials as novel media (such as tailor-made materials and devices) in separation science. As a typical example of the novel miniaturized sample preparation system, the applications of fibrous materials for microcolumn liquid-phase separation methods are described.     

多羟基对苯二甲酸类化合物的合成与应用研究进展

多羟基对苯二甲酸类化合物在医药及功能材料上的应用研究得到广泛关注。 选择了其中4个具有重要应用价值的多羟基对苯二甲酸的合成及应用进行了综述。 从中归纳出以苯酚类化合物为起始原料,经Koble-Schmitt法制备,其工艺具有操作简便、生产成本低及环境友好型等特点。     

在不同溶剂中制备生物质基超疏水材料的研究进展

超疏水材料因具有超高的拒水性以及自清洁能力而备受关注,但是在制备过程中也因所选用溶剂和低表面能物质不同给环境带来不同程度的压力。生物质材料可再生、价格低并且绿色无污染,常用于超疏水材料的制备。本文介绍了生物质基超疏水材料的制备方法,并按照制备技术中所用溶剂不同分类,将生物质基超疏水材料分为有机溶剂型、水基/半水基型、无溶剂型三类,同时分析了三种不同类型超疏水材料的优势以及劣势。最后,总结了制备环保型超疏水材料的方法,并且展望了生物质基超疏水材料未来的发展方向。     

The importance of radiochemistry for the characterization of NORM and of environments contaminated by NORM

Naturally occuring radioactive materials (NORM) are present in the environment and they can be concentrated by technical activities, particularly those involving natural resources. This article describes radioanalytical problems arising in the accurate determination of natural radionuclides in NORM and in the environment contaminated by NORM. The solution of these problems is of particular importance since the results can be used to estimate the dose to workers and to the population. A special emphasis is given to the reliability of the radiochemical methods and procedures applied for the detection and measurement of alpha or beta emitters by radiometric or non-radiometric techniques.     

Determination of engineered nanoparticles on textiles and in textile wastewaters

Textile materials with engineered nanoparticles (ENPs) have excellent properties as they are antibacterial, antimicrobial, water resistant and protective. The textile industry has recognized the importance and the advantages of ENPs, so they comprise one of the fastest developing branches of processing.The most important sources of ENPs released to the environment from textiles are textile-industry wastewaters and waters from large hospital or hotel laundries. In addition, waste textile materials coated with ENPs present a threat to the environment, if such materials are not properly handled and disposed of after use.Currently, the toxicity and the potential harm of ENPs widely applied on textiles are not thoroughly investigated and/or eliminated. Consequently, there is an urgent need to define the most appropriate analytical methods for monitoring ENPs on textiles.This review presents the most important techniques for monitoring ENPs on textile materials and in textile-wastewater samples, from the perspective of protecting the environment and human health.     

Graphene and its nanocomposites used as an active materials for supercapacitors

This review article investigates the hot topics by presenting the latest advances on graphene-based nanostructures for supercapacitors. In literature, many scientists have studied the nanomaterials and combination of conducting polymers in supercapacitor (SC) devices. The main aim of this review article is to present the higher capacitance, and higher power and energy density performances of the SC devices, which includes the active materials of carbon-based materials, metal oxides, conducting polymers, nanocomposites, etc. Many conventional techniques have already been used such as photolithography, inkjet printing, etc. Each of these methods has specific advantages and some drawbacks, with some working better in different environments. Among various nanoscaled materials, nanocrystal oxides of transition metals play an important role in advanced materials development. In addition to design of active material, symmetric and asymmetric supercapacitor device fabrication is also directly effect to obtain a higher capacitance, energy and power density performances. Therefore, this review article focuses on supercapacitor technology in new developments, such as design of active materials, device fabrication, etc.     

Synthetically tailored excited states: phosphorescent, cyclometalated iridium(III) complexes and their applications

Phosphorescent iridium(III) complexes are being widely explored for their utility in diverse photophysical applications. The performance of these materials in such roles depends heavily on their excited-state properties, which can be tuned through ligand and substituent effects. This concept article focuses on methods for synthetically tailoring the properties of bis-cyclometalated iridium(III) materials, and explores the factors governing the nature of their lowest excited state.