FTIR定量分析聚乙二醇/聚乙烯共混物组成

利用傅里叶转变红外光谱(FTIR)定量分析聚乙二醇/聚乙烯共混物组成,对特征谱带的选择,重叠峰的分离,数据的拟合处理作了详细讨论。采用1 378 cm-1处聚乙烯的复合峰与1 110 cm-1处聚乙二醇的复合峰强度比作为定量分析的基准,利用基于Beer-Lambert定律的理论拟合方程能较好的实现峰强度比与组分浓度的对应关系,可满足聚乙二醇/聚乙烯共混物组分的定量分析的要求。     

衰减全反射傅里叶红外光谱在聚丙烯的表面改性的应用

应用衰减全反射傅里叶变换红外光谱法(ATR-FTIR)对聚丙烯共混薄膜的表面组成进行了测试.通过比尔定律的验证,确认1 103和1 733 cm-1可以分别用于含聚乙二醇和含羰基结构单元的改性剂共混体系的定量计算.利用ATR校正程序,以相应的特征峰峰面积比作为定量测定的基准,可以减少测试误差.通过工作曲线法,定量地分析了聚丙烯共混物薄膜表层中改性剂的含量.此外,利用变角全反射,通过改变入射光线的角度,可以测定不同深度的改性剂含量,剖析改性剂在PP共混薄膜的表层分布.     

表面增强拉曼光谱研究高分子共混物薄膜相结构

采用拉曼光谱法研究了由聚苯乙烯(PS)/聚甲基丙烯酸甲酯(PMMA)的四氢呋喃(THF)溶液在玻璃基板上旋转涂膜得到的共混物薄膜。应用显微共焦拉曼光谱,根据PS在1604,1585cm-1处苯环的伸缩振动峰和PMMA在1728cm-1处羰基的伸缩振动峰,可以确定薄膜(厚度约为800nm)表面海岛状相结构的组分分布信息。另外,还对210℃下PS/PMMA(30/70)共混物薄膜退火过程中表面的变化进行了分析。采用表面增强拉曼散射效应对高聚物的增强作用得到了薄膜(厚度约为400nm)的Raman光谱,并且成功地对其组成进行了分析。     

利用红外光谱成像技术研究PP/PE共混物

利用红外光谱对不同比例条件下制备的PP PE共混物进行了研究 ,通过对PP ,PE的特征吸收峰的分析 ,发现聚丙烯 (PP)特征峰峰面积与聚乙烯 (PE)特征峰峰面积的比值与PP/PE共混物的质量比之间存在较好的对应关系。利用特征吸收峰面积之比 ,借助红外成像技术对PP纤维热压在PE薄膜上制备的样品的研究得到了复合共混物的分布信息 ,发现其成像结果与偏光显微镜的结果有很好的吻合。实验研究结果表明采用红外成像技术 ,利用特征吸收峰面积之比可以进行对聚合物共混物的分相行为的研究。     

基于聚噻吩/聚己内酯共混物的有机薄膜晶体管

选择聚3-己基噻吩(P3HT)/聚己内酯(PCL)双晶共混体系制备了不同配比的共混物有机薄膜晶体管。电学性能研究发现,随着共混物中P3HT含量降低,薄膜晶体管的场效应迁移率、开关电流比和阈值电压等性能缓慢降低。当P3HT质量分数为40%时,共混物薄膜仍具有较好的场效应性能,迁移率为0.008 cm²·V^-1·s^-1,开关电流比为5×10³,阈值电压为45.5 V。原子力显微镜测试结果表明:共混物成膜时发生明显的垂直相分离,在界面处形成连续的半导体层,有利于载流子传输。     

傅里叶变换衰减全反射红外光谱法的应用与进展

随着傅里叶变换红外光谱仪的应用及化学计量学的发展 ,傅里叶变换衰减全反射红外光谱法(ATR FTIR)成为用传统透过法制样效果不理想 (或制样复杂 )的样品及表层结构分析的有利工具和手段。ATR FTIR技术已应用到纺织、质检、公安等各个领域。目前 ,人们正在针对ATR FTIR的特性 ,开展应用研究。为此 ,文章主要介绍了国内外应用ATR FTIR技术进行深度剖析的研究 ,对材料表面的定性分析 ,组分的定量分析 ,光学纤维与ATR附件的联用技术 ,以及在其他领域 (如运用ATR FTIR技术考察中空纤维的结构及取向变化 ,研究皮肤促进剂的作用机理 )的研究现状及发展情况     

聚乙二醇在Al2O3/水界面吸附行为的ESR研究

采用电子自旋共振技术结合自旋标记研究了聚乙二醇在Al₂O₃/水界面的分子构型和运动行为.结果表明,聚乙二醇在Al₂O₃上的吸附等温线呈S型,吸附量随聚乙二醇分子量增加而减小,聚乙二醇在Al₂O₃表面是多点吸附,分子中的大部分链节平躺在Al₂O₃表面、少部分链节伸向溶液。     

FTIR/ATR光谱应用于甘蔗糖蜜锤度的快速测定

采用FTIR/ATR光谱,偏最小二乘法(PLS)和Savitzky-Golay(SG)平滑方法建立甘蔗糖蜜锤度的快速测定方法和光谱分析的优化模型。基于全谱4500—600cm-1,利用计算机算法平台,把483种SG平滑模式和1—40的PLS因子数任意组合分别建立PLS模型。根据预测效果,最优模型为原谱平滑,2、3次多项式类型,45平滑点数,PLS因子数为6,预测均方根偏差(RMSEP)、预测相关系数(rp)和相对预测均方根偏差(RRMSEP)分别为0.978%、0.902%和1.05%,预测精度很高,并且大幅度优于未做SG平滑处理直接用PLS建模的预测效果。从而表明,FTIR/ATR光谱能够应用于甘蔗糖蜜锤度的快速准确测定,SG平滑模式和PLS因子数的联合大范围筛选能够有效地应用于FTIR/ATR光谱分析的模型优选。     

利用Raman散射光谱研究铜铟镓硒薄膜表面的掺杂调节作用

主要研究了采用溅射后硒化方法制备CIGS(铜铟镓硒)薄膜太阳电池的吸收体材料中的表面层掺杂调节问题。并利用Raman散射谱分析研究了样品表面层特征峰的移用,研究结果表明: CIGS薄膜表面层由富In表面层调节为富CuGa表面层后,Raman特征峰位向高波数移动,表明薄膜表面的Ga含量随之变化,并导致表面能带的相应改变,经计算证实了富CuGa表面层样品较之富In表面层样品具有更高的表面能带,从而改善了以此材料为吸收层的太阳电池器件性能, V_oc提高了74 mV,填充因子上升8％,最终使器件转换效率η相应提高了约2％。提高了V_oc与FF。同时表明Raman散射谱作为一种灵敏的表面表征手段,在研究太阳电池吸收层表面状态时十分有力。     

光谱法研究PA612/TPU熔融共混体系相互作用

采用熔融共混制备尼龙(PA)612/热塑性聚氨酯(TPU)复合材料,通过广角X射线衍射仪(WAXD)和傅里叶变换红外光谱仪(FTIR)研究了PA612和TPU之间的相互作用。WAXD结果表明,TPU的加入影响了PA612的结晶完善度,且随着TPU含量的增加,PA612的结晶度逐渐降低。FTIR的结果证实了共混样品中PA612与TPU形成了新的氢键,且熔融共混过程中两组分之间有少量化学反应发生。     

Polymer–Clay Nanocomposites Based on Blends of Various Types of Polyethylenes and PE-g-MA: Morphology,Thermal Properties,Microhardness, and Transparency

Polymer–clay nanocomposites have been prepared by melt blending of commercial organoclay Cloisite 15A with blends of polyethylenes (PE) and maleic-anhydride-grafted PE (PE/PE-g-MA) with wide range of composition. Three types of PE/PE-g-MA blends with different molecular structure, namely blends of high-density PE (HD) with HD-g-MA (HDMA), blends of low-density PE (LD) with LD-g-MA (LDMA), and blends of linear low-density PE (LL) with LL-g-MA (LLMA) were used. The influence of the molecular structure of the PE matrixes and the compatibility between the blend components on the morphology of the nanocomposites was studied. The thermal properties, microhardness, and transparency of the nanocomposites were investigated. The influence of the degree of exfoliation/intercalation on the materials characteristics is discussed.     

Effect of the surface-modifying macromolecules on the duration of the surface functionalization

Functionalization of polystyrene films by the preferential surface enrichment of surface-modifying macromolecules (SMM) to achieve a hydrophilic surface with long effective duration is described. The comb-like amphiphilic copolymers (PKG-g-PS) based on styrene-maleic anhydride copolynier (SMA) backbone was synthesized by esterification of SMA with poly(ethylene glycol) (PEG). When PEG-g-PS was melt blended with polystyrene, the preferential surface enrichment of PEG-g-PS was much evident resulting in the large increase of the surface polarity. The effective duration of the surface functionalizatoin was also hugely extended as SMMs were added into the blends. Furthermore, more polyether chain segments on PEG-g-PS could selectively migrate to the surface by the inducement of polar solvent. Compared with the PEG-g-PS/PS and PEG/PEG-g-PS/PS blends, the surface polarity and the effective duration of surface modification both increased greatly when PEG-g-PS was used as the compatibilizer of PEG/PS blends. It was an effective solution to balance the conflict between the duration and efficiency of the surface-modifying additives.     

The study of compatibility of polyethylene and polypropylene by using irradiated polyethylene wax

The modification of the compatibility between polyethylene (PE) and polypropylene (PP) by using irradiated PE wax (PE wax) is the purpose of this study. In this part, polymer blends based on various ratios of PE and PP were blended with 2.5% PE wax in all the blend ratios to determine the optimum ratio of the blend to be compatabilized. The influence of PE wax as a compatibilizing agent for PE and PP blend was investigated through the measurements of thermal, mechanical and morphological properties. The PP/PE blends modified by this method showed higher mechanical properties than those of the unmodified blends. Also, stress and strain of the modified blend having ratio (60/40) PP/PE blend recorded the maximum mechanical behavior. Scanning electron microscopy (SEM) micrographs of modified blends showed an indication of strong interfacial adhesion and a smooth continuous surface in which giving a support to the effect of irradiated PE wax as a tool for improving the compatibility.     

Antibacterial polymeric coatings grown by matrix assisted pulsed laser evaporation

We report on a simple and environmental friendly method to produce composite biocompatible antibacterial coatings consisting of silver nanoparticles (AgNPs, size 40 nm) combined with polymer blends (polyethylene glycol/poly(lactide-co-glycolide), PEG/PLGA blends). The PEG/PLGA&AgNPs coatings were produced by Matrix Assisted Pulsed Laser Evaporation, using a Nd:YAG laser with λ=266 nm. The AgNPs were deposited either on top of a PEG/PLGA layer (i.e., bilayered coating), or simultaneously with the polymers (i.e., blended coating). In both cases, chemical analysis indicated that the polymers preserved their integrity, with no evidence of chemical interaction with the AgNPs. Morphological investigations evidenced homogenous distribution of individual AgNPs on the surface of the coatings, with no signs of aggregation. The size of the AgNPs was ～40 nm, consistent with size of the as-received ones. The presence of AgNPs in the coatings was confirmed by the absorption band at ～420 nm and their stability was checked by monitoring this absorption versus time. After exposure to air, the AgNPs from the bilayered coating showed signs of oxidation. In the blended coating, the oxidation of the AgNPs was prevented by the neighboring polymer molecules. Finally, preliminary investigations confirmed the bacterial killing activity of the coatings against Escherichia coli.     

Adhesion enhancement in polystyrene/polyethylene blends by corona treatment and triblock copolymer addition

A comparative study of interfacial effects due to styrene-butadiene-based triblock copolymer (SEBS) addition and to corona treatment has been investigated for blends of polyethylene (PE) and polystyrene (PS). Blends of PS/PE covering a wide range of weight composition have been prepared in the molten state. Scanning electron microscopy demonstrated that moderate amounts of SEBS copolymer addition (2-5%) resulted in finer particle dispersion and in better interfacial adhesion between PE and PS phases. Tensile strength and elongation at break were also significantly improved. In the case of corona treatment of both polyethylene and polystyrene, the tensile strength of the blends increased while their elongation at break remained almost unchanged. The same trend was found when small amounts of corona-treated blend (5%) were added to the non-modified PS/PE blends. Rheological measurements revealed that corona treatment resulted in a decrease of dynamic shear viscosity of both PE and PS. From a view-point of morphological and mechanical properties, the triblock copolymer was found to be the more efficient modifier. Nevertheless, much higher tensile strengths, but lower elongations at break were obtained when the blends were modified by corona-treated SEBS copolymer. The results suggest that a combination of the two modification methods may be a promising route to enhance performance properties in the immiscible PS/PE system.     

Oriented Crystallization of Polyethylene in Compatible Blends with Polyamide 11

The oriented crystallization of polyethylene (PE) in uniaxially oriented films of compatible blends with polyamide 11 (PA11) was studied. The PE sample used was a random copolymer of PE with methacrylic acid (MAA), poly(ethylene-co-methacrylic acid) (PEMAA), with 4wt% MAA units. Oriented films of PA11/PEMAA blends were prepared by uniaxial drawing of the melt-mixed blends. The drawn films with fixed lengths were heat-treated at 120°C for 3min to melt the PE component, followed by cooling the sample to room temperature at a rate of 2°C/min to recrystallize the PE (designated slowly crystallized sample). The PE component crystallized in elongated domains of PEMAA with diameters of 0.5–2 μ m and lengths of 5–10 μ m for the PA11/PEMAA = 80/20 blend, resulting in the oriented crystallization of PE crystals. The crystal b-axis of PE was highly oriented in the direction perpendicular to drawing, while the crystal a-axis was weakly oriented in the drawing direction in the slowly crystallized sample of the PA11/PEMAA = 80/20 blend. The a-axis orientation of PE crystals in the PA11/PEMAA = 80/20 blend contributes to the improvement of mechanical properties in the direction perpendicular to drawing.     

Miscibility,Crystallization, and Morphology of the Double-Crystalline Blends of Insulating Polyethylene and Semiconducting Poly(3-Butylthiophene)

A series of crystalline semiconducting poly(3-butylthiophene) (P3BT)/crystalline insulating polyethylene (PE) blends were prepared and the miscibility, crystallization, and structure/morphology were investigated. Even though phase separation was observed by transmission electron microscopy (TEM) and small-angle X-ray scattering (SAXS), several pieces of evidence indicated that limited miscibility should be present in PE/P3BT blends: small changes in both T_m and crystallinity of PE phase and a small portion of PE being dissolved in P3BT. The study of PE isothermal crystallization kinetics revealed that the introduction of P3BT significantly influenced the nucleation mechanism and growth geometry, i.e., PE was transformed from three-dimensional (3D) spherulitic to two-dimensional (2D) disc crystals. A striking reduction of nucleation density and an obvious ringed morphology of PE spherulites (2D) in PE/P3BT blends were also observed by polarized optical microscopy; it is proposed that the limited miscibility between PE and crystalline P3BT favors the formation of ringed PE spherulite in the blends. Additionally, preferred orientation of PE lamellae, with their b-axis largely constrained to the thin film plane, was observed by X-ray diffraction in PE/P3BT blend films. It is evidenced that the PE orientation was due to the b-axis being the crystal growth direction, which can only be in film plane.