Constitutive model and failure locus of a polypropylene grade used in offshore intake pipes

BorECO^®™ BA212E is a polypropylene block co-polymer which has become a common material in the manufacturing of large diameter non-pressurized gravity offshore intake pipelines. These lines are used for transportation of sea water for cooling of petrochemical process plants. The pipe sections are joined by butt heat fusion welding to create the pipeline. Recently a few premature failures of such pipelines have been reported in the field. Hence, there is a need to characterize the constitutive behavior of the pipe and weld material in order to properly design these pipes. The aim of this work is to determine the material constitutive behaviors of the pipe material and the welded joint material. Uniaxial tensile tests of both the pipe and weld joint material are conducted at various strain rates. Both the pipe and weld material show a rather high strain rate dependency, with the weld material having about half the yield strength than that of the pipe material. An analytical constitutive material model is developed for both the pipe and weld material, incorporating the effect of strain rate. The failure locus, expressed in terms of the equivalent plastic strain at failure vs. the stress triaxiality, for both materials is also determined as part of the constitutive model using notched dumbbell specimens. The constitutive model and failure loci for the pipe and weld material are implemented in a finite element model (FEM) and are validated by conducting a series of independent four-point bend experiments on both material types. The validation is carried out by comparing the FEM results of the four-point bend model with the experimental results, which show a rather good agreement.     

石墨烯材料与模拟生物膜界面相互作用的研究进展

石墨烯材料在生物领域的蓬勃发展使其纳米生物界面研究已成为纳米生物学研究的热点方向。生物膜是石墨烯材料进入生物体系环境中的第一道屏障,深入理解石墨烯材料与磷脂膜间的相互作用,对于石墨烯基生物材料的功能界面优化设计和生物学效应控制具有极为重要的意义。本文对石墨烯材料进行了简要介绍,系统总结了近几年石墨烯材料与模拟生物膜相互作用的研究进展,并对其研究方向进行了展望。     

Behavior of intumescent epoxy resins in fireproofing applications

The thermal degradation process of a commercial intumescent epoxy resin for fireproofing applications was investigated. The changes in the morphology of the material during exposure to fire-like conditions were interpreted in the light of the degradation of single material components and of the overall swelling mechanism. An apparent kinetic model was developed to describe the thermally activated conversion and the weight loss of the material. The dramatic change in the key properties of the material (thermal conductivity, volume swelling, and apparent density) was investigated and linked with the thermal degradation phenomena governing the swelling process. Models were developed to describe material properties as a function of temperature and material conversion. The models provide the simulation of the fire-triggered degradation of the sample material at the heating rates of interest, allowing a detailed analysis of fireproofing performance.     

一种新型物证摄影技术的探索

低温荧光摄影是用摄影方法记录物证在低温状态下被激发出荧光图像的一种技术，同普通荧光摄影一样，它是利用光致发光原理来显现隐性痕迹物证，但又克服了普通荧光摄影中被拍物荧光亮度低、物证细节特征无法再现等缺陷，增加了物证的反差，而且对检材不造成任何损坏，是物证摄影中非常有效的一种技术手段．着重阐述了低温荧光摄影的方法、类型，以及在物证检验中的运用，     

新型生态环境替代材料

环境材料是指与环境相协调或具有环境意识的材料,其特点是对资源和能量消耗少,环境污染小,再生利用率高,同时又具有优异使用性能.用环境负荷小的材料替代环境负荷大的材料是21世纪新型生态环境材料应用开发的重要内容.本文重点介绍替代氟里昂的制冷材料、替代含磷洗涤剂材料、替代建筑用石棉材料以及新型环境相容性材料的研究和应用进展.     

Electrostatic charging due to separation of ions at interfaces: contact electrification of ionic electrets

This Review discusses ionic electrets: their preparation, their mechanisms of formation, tools for their characterization, and their applications. An electret is a material that has a permanent, macroscopic electric field at its surface; this field can arise from a net orientation of polar groups in the material, or from a net, macroscopic electrostatic charge on the material. An ionic electret is a material that has a net electrostatic charge due to a difference in the number of cationic and anionic charges in the material. Any material that has ions at its surface, or accessible in its interior, has the potential to become an ionic electret. When such a material is brought into contact with some other material, ions can transfer between them. If the anions and cations have different propensities to transfer, the unequal transfer of these ions can result in a net transfer of charge between the two materials. This Review focuses on the experimental evidence and theoretical models for the formation of ionic electrets through this ion-transfer mechanism, and proposes--as a still-unproved hypothesis--that this ion-transfer mechanism may also explain the ubiquitous contact electrification ("static electricity") of materials, such as organic polymers, that do not explicitly have ions at their surface.     

Extrusion processing for ammonia fiber explosion (AFEX)

The ammonia fiber explosion (AFEX) process, previously run only in a batch reactor, has been adapted to run on a twin-screw extruder. The sugar yield of AFEX material after enzymatic hydrolysis has been increased up to 3.5 times over that of completely untreated material. The ruminant digestibility of corn fodder has been increased up to 32% (from 54–71%) over completely untreated material, and 23% (from 63–77%) over material extruded with no ammonia. Extrusion-treated material proved more digestible by the ruminant at 48 h than material treated in the batch reactor.     

Morphology and electrochemical properties of a composite produced by a peroxide method on the basis of tin dioxide and carbon black

Using peroxostannate as a precursor, a composite material based on tin dioxide and carbon black was obtained, in which tin dioxide forms a coating on the surface of carbon black nanoparticles. The synthesized material was characterized by electron microscopy and X-ray powder diffraction analysis, and also the electrochemical characteristics of this material as an anode material for lithium-ion batteries were studied. The material demonstrates good stability and rate performance, which is indicative of the efficiency of the peroxide method for producing promising inexpensive anode materials based on tin dioxide and carbon black.     

建立食品安全中有毒(害)物标准物质体系的设想

介绍标准物质的概念,食品标准物质的重要性、种类、现状及其研制过程。提出了我国食品安全中有毒(害)物标准物质研制应从3大范围入手,全方位展开,建立并健全我国食品安全中有毒(害)物标准物质体系的设想。     

Preparation and certification of tea leaves reference material

Summary Tea leaves reference material was prepared and certified for elemental composition. Japanese green tea leaves were ground, sieved to pass a 80-mesh screen, blended and bottled. The prepared material satisfied the homogeneity criteria for a reference material. Trace element analysis of the material was carried out by flame and graphite furnace atomic absorption and inductively coupled plasma atomic emission spectrometry.Certification of the material was performed using the data obtained by various analytical techniques and certified values are provided for Al, Ca, Cd, Cu, K, Mg, Mn, Na, Ni, Pb and Zn. The elemental composition of the tea leaves reference material is considered typical of Japanese green tea leaves.     

Multimaterial hydrogel with widely tunable elasticity by selective photopolymerization of PEG diacrylate and epoxy monomers

We present a method to make continuous multi‐material structures from a monomer solution that becomes a soft hydrogel when exposed to blue light and a hard solid when exposed to UV light. We show that the material can be varied between a hard epoxy material to a several hundred times softer poly(ethylene glycol)‐diacrylate material. Moreover, the elastic properties of the material depend on both the wavelength of and exposure time of the light, which is used to produce a material with an elasticity gradient. We expect our material to find use in a range of fields, with immediate applications as 2D sheets with tunable mechanical properties for cell durotaxis studies, and 3D stereolithographically printed tissue mimicks, for example, for disease models and tissue engineering. Spatially resolved photo‐polymerization of a mixture of epoxy and acrylate monomers can be used to make multi‐material structure, with unique freedom to polymerize each monomer individually. The elastic compressive properties of the material are shown to be fully tunable from <100 kPa to >20 MPa depending on the light exposure time. This is used to make a functionally graded continuous material with a large variation in elastic properties. © 2016 Wiley Periodicals, Inc. J. Polym. Sci., Part B: Polym. Phys. 2016 , 54, 1195–1201     

Fabrication of Siloxane Hybrid Material With High Adhesion and High Refractive Index for Light Emitting Diodes (LEDs) Encapsulation

A novel inorganic-organic siloxane hybrid material with self-adhesion ability and high refractive index for high-power light emitting diodes (LEDs) encapsulation is introduced. Under the catalysis of an anion exchange resin, the hybrid material was synthesized by a sol-gel condensation process from methacryloxy propyl trimethoxyl silane (MPTS), γ-(2, 3-epoxypropoxy)propytrimethoxysilane (EPTS) and diphenylsilanediol (DPSD). This hybrid material was characterized by Fourier-transform infrared spectroscopy and ¹H-NMR. The resin-type encapsulation material was then prepared by hydrosilylation of the newly synthesized inorganic-organic siloxane hybrid material and methylphenyl hydrogen-containing silicone resin. The cured silicone resin-type encapsulation material can be used as a LEDs encapsulant, owing to high refractive index (n = 1.544), high transparency, appropriate hardness, and excellent thermal stability, as well as good adhesive strength between the encapsulating material and the substrate of LED lead frame.     

SnNi-deposited carbonaceous mesophase spherule as anode material for lithium ion batteries

Carbonaceous mesophase spherule (CMS) is a commercial anode material for rechargeable lithium batteries. A composite anode material of SnNi deposited carbonaceous mesophase spherule was prepared by co-precipitation method. The structural and electrochemical characterization of the SnNi/CMS composite anode material was studied. According to the measurement of its electrochemical characterization, the prepared SnNi/CMS composite anode material shows much better electrochemical performance than CMS. The first discharge capacity of 360 mA h g⁻¹ was obtained for the SnNi/CMS composite anode material, and its discharge capacity maintained at 320–340 mA h g⁻¹ in the following cycles. It indicates that the modification of CMS with SnNi alloy can further improve the intercalation performance of CMS. SnNi/CMS composite material shows a good candidate anode material for the commercial rechargeable lithium batteries.     

Measurement of water by oven evaporation using a novel oven design.

Using an automated oven evaporation technique combined with the coulometric Karl Fischer method, the mass fraction of water has been measured in cement, coal, and refined oil samples. The accuracy of this method was established by using SRM 2890, water-saturated 1-octanol that was added to white oil. The samples were analyzed for total reactive Karl Fischer reagent (KFR) material, for interfering materials, and for material that does not react with the aldehyde–ketone KFR. All of the samples yielded volatile material that reacted with the standard KFR. None of the samples contained significant masses of material that reacted with iodine. The cement and coal SRMs contained no material that reacted with methanol and very little material that did not volatilize at 107°C. The refined oils contained some material that was volatile at 107°C and some at 160°C. However, none of this material reacted with the aldehyde–ketone reagent. These results show that the material in the solid samples is water and that the material in the refined oils is a material other than water which reacts with methanol to form water.     

Thermo-mechanical characterisation of in-plane properties for CSM E-glass epoxy polymer composite materials – Part 2: Young's modulus

The in-plane Young's modulus of a CSM E-glass/epoxy material is characterised through the use of dynamic mechanical analysis (DMA). The measured data is used to generate material models which describe the property behaviour as a function of conversion and temperature. Gelation of the epoxy resin plays a major role in the modulus development and is measured directly on the glass/epoxy material. The Young's modulus is described through a bi-functional model including the liquid/solid transition of the material. The evolution of Young's modulus is modelled by decoupling modulus increments caused by time and temperature, and is graphically illustrated through a Modulus-Temperature-Transformation (MTT) diagram. Based on the established material models presented in this paper and models in Part-1, it is feasible to assess residual stresses and shape distortions of composite parts made from this glass/epoxy material.     

Optical analysis of polymer powder materials for Selective Laser Sintering

This study increases the basic understanding of optical material properties of polymer powders used in selective laser sintering (SLS). Therefore, different polymer powder materials were analyzed regarding their optical material properties with an integration spheres measurement setup. By the measurements a direct connection between the absorption behavior of the solid material and the overall optical material characteristics of the same material in powdery form could be shown. The results were used to develop an advanced explanation model for the optical material properties of powders. At present, existing explanation models only consider the occurring of multiple reflections in the gaps between the particles to explain the overall optical material properties of powder materials. Thus, by also considering the absorption behavior of the single particles, the basic understanding of the beam-matter interaction and their effect on the optical material properties of powder materials can be expanded.     

Chromatographic characterisation of a novel type of monolithic methylsilsesquioxane-based HPLC column

A novel monolithic methylsilsesquioxane-based material with hierarchical pore structure was prepared and tested for its applicability as stationary phase for RP-HPLC. The monolithic material is produced using sol-gel chemistry according to a proprietary protocol developed in our working group. A procedure for the production of HPLC columns from the self-contained monolithic material is described. The chromatographic performance and the reproducibility of the column production was tested using the procedures of the widely accepted Tanaka test and suitable parts of the Engelhardt test which were applied to a set of four monolithic columns produced under identical conditions. The test proved the excellent hydrophobic selectivity and silanophilic behaviour of the new stationary phase material. According to the tests on steric and shape selectivity, there are strong indications that this type of material also acts as restricted access material. This assumption is further supported by the presence of a high fraction of micropores as was evidenced by physical characterisation of the material. The novel stationary phase material showed great potential for the separation of small apolar substances and was found to be particularly useful in the separation of basic compounds due its excellent silanophilic interaction.     

Technology and structural characteristics of electrode material in the Pt/C–Taunite-MD–Nafion system

Laboratory technique was developed for fabrication of an electrode material containing a platinized carbon black, carbon nanofibers, and proton-conducting polymer Nafion. Scanning and transmission electron microscopy was used to study the structure of the material and experimental dependences were obtained that relate the properties and structure of the electrode material to its structure and fabrication technique and make it possible to obtain a material with prescribed service characteristics.     

Towards Realization of a Micro- and Mesoporous Composite Silicate Catalyst

A composite silicate material, which possesses the characteristics of both microporous zeolite and mesoporous silica materials, is developed by top–down and bottom–up synthesis techniques. In order to realize a micro- and mesoporous composite material, several essential points must be clarified, since each porous material is synthesized under very different metastable conditions: zeolite is a silicate crystal, while the wall of mesoporous material is composed of amorphous silicate. Here, some aspects of the realization of a micro- and mesocomposite porous material are described, as are our experimental results regarding the successful production of composite catalyst.     

Intercalation of magnesium into a graphite-like layered material of composition BC2N

Magnesium was intercalated into a graphite-like layered material with an approximate composition of BC(2)N. The obtained material was a second-stage compound with a d-spacing of 0.367 nm for the intercalated layers. This is the first example of magnesium intercalation into a graphite-network-based material.