Correlation of SiO x layer thickness and properties of BOPP/SiO x composite films with spin coating process parameters

The effects of the spin coating process parameters on the thickness of the SiOx layer of the BOPP/SiOx composite film were investigated. When the concentration of tetraethoxysilane (TEOS) increased from 12.5 vol% to 55% vol%, the SiOx thickness increased from about 80 nm to 470 nm. In the sol time range of 1.5 h to 5 h the SiOx layer thickness reached a maximum at about 4 h and the change of the thickness roughly matched the change of the silica colloidal sphere sizes in sol. When the spin-coating speed of the dispensing stage increased from 450 r/min to 500 r/min, the SiOx layer thickness drastically decreased from about 1.67 μm to 400 nm. While the spin-coating speed of the thinning and drying stage went up to 1200 r/min, the SiOx layer thickness was in the range of 330 nm to 390 nm. It was also found that the SiOx layer thickness was almost increased linearly from about 500 nm to 1.02 μm with the ratio of the commercial silica colloidal to the TEOS from 0.2 to 1.0. The water contact angles decreased to about 23.0° for the BOPP/Si-Sol composite film with 1.67 μm SiOx layer and about 4.0° for the BOPP/mixing Si-Sol composite film with 1.02 μm SiOx layer. Compared to BOPP, the light transparency of the BOPP/Si-Sol composite films decreased by about 5.5% with the SiOx layer from about 80 nm to 1.67 μm and by 7.0% for the BOPP/mixing Si-Sol composite film with the SiOx layer from about 350 nm to 1.02 μm respectively.     

悬浮聚合制备大尺寸梭形聚苯乙烯粒子新方法及机理研究

利用氢氧化钾对苯乙烯-马来酸酐交替共聚物(SMA)进行水解,所得中等皂化程度的SMA水解产物(SMAA)在水溶液中具有刚性棒状直链构型;将此特殊结构的大分子作为分散剂用于苯乙烯悬浮聚合,通过控制搅拌速度和油水比,可得到梭形聚苯乙烯粒子;在优化条件下,粒子平均长度6.8 mm,宽度1.4 mm,厚度0.5 mm,长径比约5.0.其可能的机理为,中等皂化程度的刚棒直链型SMAA在聚合物"软粒子"表面能形成难以"回复"的有效保护层,使由剪切形成的变形聚合物"软粒子"在聚合过程中能保持形状和尺寸的稳定,从而得到梭形聚合物粒子.     

“活”的α-甲基苯乙烯共聚物:聚合反应新化学和材料工程新技术

高于临界聚合反应温度时,α-甲基苯乙烯(AMS)单体和其聚合物处于聚合-解聚平衡.基于AMS聚合物在受热时可裂解生成大分子链自由基的特性,提出了含AMS结构单元的共聚物是一种"活"的,可作为大分子自由基引发剂的概念,并通过实验对AMS共聚物的引发性能和应用进行了研究.首先,合成了AMS与(甲基)丙烯酸酯类单体、丙烯酸、苯乙烯和马来酸酐等的共聚物.然后以上述共聚物为大分子引发剂,在90℃引发(甲基)丙烯酸酯类单体和苯乙烯等的本体聚合、溶液聚合和乳液聚合,得到了嵌段共聚物.用ESR谱证明了AMS的共聚物在加热时能裂解生成以碳原子为中心的大分子链自由基.此外,在聚合物的熔融共混中,AMS分解产生的大分子链自由基通过偶合反应形成接枝链,原位生成相容剂.AMS共聚物还可以对碳纳米管及无机粒子进行表面原位接枝改性.AMS共聚物是一类无小分子残留的绿色自由基引发剂,可以用于低成本制备两嵌段共聚物,也可以用于聚合物的熔融共混增容.     

α-甲基苯乙烯-马来酸酐共聚物的合成及其引发的甲基丙烯酸甲酯的无皂乳液聚合

以α-甲基苯乙烯(AMS)、马来酸酐(MANH)为共聚单体,偶氮二异丁腈(AIBN)为引发剂,采用自稳定沉淀聚合法合成了α-甲基苯乙烯和马来酸酐的共聚物,再将其皂化后得到具有引发和乳化双重作用的共聚物.该共聚物可以作为大分子引发剂再引发甲基丙烯酸甲酯(MMA)进行无皂乳液聚合.采用扫描电镜、红外光谱仪、乌氏黏度计等仪器对AMS-MANH共聚物以及乳液聚合产物进行了表征.结果表明,乳液聚合产物是以PMMA为主长链,AMS和MANH低聚物为短链的嵌段共聚物.单体最高转化率可达到85%,特性黏数在80 mL/g左右.乳胶粒子粒径在150～200 nm之间.聚合速率随着引发剂浓度的增加而增大,聚合物的特性黏数随着转化率的提高基本呈线性增大.     

光聚合制备PVC大分子引发剂及两亲接枝共聚物

利用UV光照自引发、双异丙基硫杂蒽酮(BIITX)和异丙基硫杂蒽酮(ITX)引发氯乙烯(VC)聚合得到含缺陷结构或/和ITX残基的PVC.考察了不同引发方式时单体浓度、光强、反应时间和温度对单体转化率、产物分子量及其分布的影响,UV-Vis、1H-NMR和FTIR分析表明所得PVC含缺陷氯或/和ITX残基.以此PVC为大分子引发剂(缺陷结构和ITX残基为引发点),50℃下有效引发了甲基丙烯酸二甲氨基乙酯(DMAEMA)聚合,获得了PVC-g-PDMAEMA共聚物.相比起始PVC,接枝共聚物分子量稍有提高,PDI下降.1H-NMR和FTIR分析证实了接枝共聚物的形成,接枝共聚物在水(pH=3)中组装形成了稳定核-壳结构胶束,显示其具有两亲性.     

一种利用梯度光掩模制备梯度表面的简便方法

以自制杂化双向拉伸聚丙烯/氧化硅(BOPP/SiOx)有机/无机杂化膜为基材,由喷墨打印机直接在杂化膜表面打印色阶图案,制备出对紫外光强度呈梯度透过的梯度光掩模;通过此掩模控制,在双向拉伸聚丙烯(BOPP)和聚对苯二甲酸乙二醇酯(PET)表面实施受限光催化氧化(CPO)光感应羟基化反应、受限光接枝丙烯酸(AA)以及表面...     

有机聚合物材料表面受限光感应C–H键转换反应研究进展

有机聚合物材料普遍具有表面能低和反应惰性的特点,限制了其在光、电、分离、生物医用等高端领域的应用.表面改性是有机高分子材料高性能化的重要手段,其涉及的核心科学问题是表面C–H键的活化/转换化学.光化学反应具有快速高效、化学选择性高、环境友好、可低温反应、时间/空间精确可控等特点,在有机聚合物材料表面改性上具有突出优势.本文介绍了本课题组多年来在有机聚合物材料表面受限光感应C–H键转换反应方面的研究进展,系统介绍了此类反应的机理,以及在生长/固定无机、导电材料、生物分子等方面的应用,并展望了光感应C–H键转换反应今后的发展方向.     

Introducing NH2 onto polymeric films via photo-induced C—H bond transformation with phenol derivatives as building blocks

A one-step process to introduce both the aromatic and aliphatic primary amino groups with high chemoselectivity was developed.Triplet state acetone abstracts the hydrogen atoms from both the C-H bond of the polymeric film substrate and the O-H bond of phenol which is the building block and the amino group carrier.As a result,two kinds of free radicals, confined carbon-centered chain radicals of the polymer substrate and mobile oxygen-centered phenoxy radicals,were generated.Then the C-O bonds were formed by the coupling reaction between these two kinds of free radicals.p-Tyramine and p-aminophenol were used as amino carriers.The successful introduction of amino groups onto LDPE,BOPP and PET film substrates was demonstrated by measurements of water contract angle（CA）,ultraviolet spectra（UV）,X-ray photoelectron spectroscopy（XPS） and fluorescent microscopy.The processing factors,such as the UV-light intensity and irradiation time,concentrations of p-tyramine and p-aminophenol,and the ratio of acetone/water were investigated.The optimized process parameters are as follows:UV light intensity 9500μW/cm²;irradiation time 18 min for BOPP and LDPE, 22 min for PET;the ratio of acetone/water = 1;and concentration of p-tyramine and p-aminophenol 15%for BOPP and LDPE,1%for PET.Based on the UV absorbance,the amino groups on the polymeric substrates were estimated to be in the range of 6.3×10^-6-9.5×10^-6 mmol/mm².     

以TiCl4为共引发剂的阳离子聚合体系的络合竞争

通过聚合物的GPC谱图分析以及紫外光谱测试证明了以TiCl₄为共引发剂的阳离子聚合体系中微量水与引发剂和TiCl₄之间存在着络合竞争,提出了抑制水对阳离子聚合影响的方法.     

Copolymerization of α-Methylstyrene and Styrene

In this paper, the effects of temperature from 60 °C to 80 °C and the molar ratios in monomer feed on the copolymerization of α-methylstyrene(AMS) and styrene(St) were studied. The resulting copolymers, designated as PAS, were characterized by FTIR, GPC, NMR and TGA. When the reaction temperature was below 75 °C, the molecular weights increased almost linearly as the evolution of the copolymerization. The phenomenon revealed that AMS could mediate the conventional free radical polymerization having some features of a controlled system. As the AMS/St = 50/50(molar) in feed, the overall fraction of the AMS unit incorporated into the copolymer was as high as 42 mol%, the monomer conversion could be more than 90 wt% and the molecular weights could reach as high as 4400. However, since the styrene is more reactive than AMS, the AMS fraction in copolymer increased with the overall monomer conversion. The 13C-NMR revealed the products were random copolymers which had triads, such as-AMS-AMS-AMS-,-St-AMS-AMS-(-AMS-AMS-St-) and-St-AMS-St-. TGA curves demonstrated that the degradation temperature of the resulting copolymers went down from about 356.9 °C(0 mol% AMS) to 250.2 °C(42 mol% AMS). This behavior demonstrated that there exist weak bonds in the AMScontaining sequences which could be used as potential free radical generators.