臭氧改性及搅拌桨结构对大直径双层球制备的影响

随着高功率激光器的飞速发展,ICF物理实验对聚苯乙烯（PS）-聚乙烯醇（PVA）双层空心微球的规格要求逐渐提高,直径要求将达到700～900 m。针对该直径范围的PS-PVA双层空心微球,通过采用PS球臭氧化表面改性技术和搅拌桨叶轮结构优化技术,对传统乳液微封装法制备双层空心微球工艺进行了改进,臭氧化表面改性后PS固体核心发生憎水-亲水转变,提高了PS与PVA之间的作用强度;搅拌桨叶轮结构优化,改善了体系容器内溶液流场均匀性,使得微球在整个体系中的运动相对平稳,从而初步制得了直径范围在700～900 m的双层空心微球。     

相衬照相法检测聚苯乙烯微球气泡缺陷

 利用较高能量的X射线对聚苯乙烯（PS）微球进行离焦相衬成像,球壁内密度变化较大的微小气泡的边缘衬度得到有效增强,从而在灰度变化较平滑的微球整体图像中凸显出来,分析了衬度来源及相关因素。实验采用微焦斑的X射线管及CCD作为光源及探测器,图像分辨力约为2 μm,在能量为20～30 keV时,实现了PS微球缺陷快速检测,为微球制备工艺的改善和提高提供了快速有效的监测手段。     

微封装法制备聚苯乙烯空心微球的改进

 主要介绍了密度匹配微封装技术，利用此项技术制备的聚苯乙烯空心微球 球形度好于99%，同心度好于98%。另外还对球壳内壁气泡问题及大直径球壳的制备进 行了讨论。     

聚芳亚胺酮空心微球的制备

 利用微流体技术和双重乳液技术对大直径聚芳亚胺亚胺酮空心微球的制备条件进行了讨论。完成了微球壁厚和直径的控制研究,并讨论了密度不匹配对微球质量的影响。获得了直径0.6～2.0 mm,壁厚5.0～20.0 μm的聚合物微球材料,并对微球制备过程中相分离对聚合物微球形貌的影响进行了分析,结果表明：在聚合物微球外表面易于进行spinodal分相,而在内表面易于进行binodal分相,因此微球内外表面具有不同的形貌结构。同批次制备微球中,平均直径±5%范围内的微球数占88%,球形度大于99%。     

塑料微球表面制备聚乙烯醇涂层研究进展

在聚苯乙烯（PS）-聚乙烯醇（PVA）-碳氢聚合物（CH）三层球的设计中制备PVA涂层的方法主要包括乳液微封装法、炉内成球涂层法、浸(旋)涂法、界面缩聚法及喷涂法等,前三种方法目前最为常用。总结了前三种制备PVA涂层方法的优缺点及目前的研究和制备现状。乳液微封装法适合于500 m以下小尺寸双层球的制备,具有微球成活率高、产品质量较好等优点,但制备过程受人为因素影响较大,且不易制备大直径双层球。炉内成球涂层法也适用于小尺寸双层球的制备,其制备周期短,但液滴发生器的设计苛刻,PVA层的均匀性差,且不易制得较大尺寸的双层球。浸（旋）涂法可制备1000 m以上的大直径双层球,但该方法中影响PVA涂层铺展的因素较多,得到的PVA涂层均匀性较差,且涂层很薄。     

炉内成球法制备PVA涂层理论模拟研究

 根据炉内成球法制备PVA涂层原理，建立了炉内成球法在PS微球表面制备PVA涂层的数学模型，并利用数值方法进行了求解，研究了初始PS壁厚和直径、载气种类、炉内温度、PVA含量等实验条件的影响。计算结果表明，包裹PS微球的PVA水溶液复合微球在下落过程中速度迅速增加，短时间内达到最大值后又逐渐降低；复合微球的PVA水溶液涂层厚度逐渐减少，微球表观密度降低；炉内温度较低时，PVA涂层不易烘干；空气和纯Ar做炉内气氛时，微球烘干时间延长，而在He和Ar混合气体中，随着He含量增加，微球烘干时间缩短；小直径PS微球及高含量PVA溶液有利于制备厚的PVA涂层。     

微封装球壳壁内气泡的产生和消除

介绍了微封装技术制备的聚合物空心微球壁内气泡产生的两种可能机理。实验证明 ,气泡主要是由于有机溶剂中微量水的微相分离造成的。     

聚-α-甲基苯乙烯空心微球制备过程中的缺损研究

基于二次乳化技术产生W1/O/W2双重乳液,采用乳液微封装技术制备聚--甲基苯乙烯(PAMS)空心微球,研究了部分工艺参数对PAMS微球缺损形态和比例的影响。实验结果表明:薄壁微球的低强度导致了微球表面缺损。当微球壁厚一定时,有3个因素影响缺损微球比例:W2相中聚乙烯醇质量分数、CaCl2质量分数和O/W2的相比,当它们分别为1.0%,1.5%,0.01时,薄壁(2 m)微球的缺损比例低于40%,球壳内也无气泡存在。     

搅拌法制备聚合物微球中油水相对壁厚的影响

为了研究乳液微封装技术中油水相对微球壁厚的影响,推导了在理想状态下微球壁厚、油相质量分数和油水相比这三者之间的函数关系。结果表明:当内相水滴半径和油相质量分数为常数时,微球壁厚是油水相比的单增函数;而当内相水滴半径和油水相比为常数时,微球壁厚是油相质量分数的单增函数。即提高油相质量分数或增大油水相比对增加壁厚而言具有等效性。根据此规律,在搅拌法制备小直径聚苯乙烯微球中,通过调整油水相的各参数,确定了制备小直径厚壁聚苯乙烯微球的关键工艺参数。实验表明:采用搅拌法制备10~25 m壁厚的小直径聚苯乙烯微球时,油相质量分数宜配制为5.3%~7.0%,油水相比宜控制在1.6~2.2之间,而外水相中聚乙烯醇质量分数宜控制在1%~3%之内。     

高钾空心玻璃微球的制备

 以无机化合物为初始原料，选择合理的玻璃溶液配方和成球条件，用液滴法制备出直径200 μm，壁厚2 μm，K₂O摩尔分数大于10 %的空心玻璃微球（HGM）。利用扫描电镜X射线能量色谱仪对玻璃球壳的组分进行了分析。结果表明，所制备的高钾空心玻璃微球各项技术指标能基本满足神光-Ⅱ物理实验的要求，微球球壳成份实测结果与理论计算结果吻合。     

干凝胶炉法制备聚苯乙烯空心微球

研究了一步乳化法制备初始粒子的过程中相比及搅拌强度对初始粒子直径的影响 ,初步探讨了干凝胶炉内成球过程中 ,炉温、炉内气氛、压力等对聚苯乙烯 (PS)空心微球产率及同心度的影响。以分子量为 2 2万的聚苯乙烯制得了直径在 70～ 550μm的初始粒子 ,经乙醇浸泡后 ,制得了含 2 %质量分数发泡剂的干凝胶粒子 ,并在 Polymer-70 0干凝胶炉上制备出了外直径为 4 0 0～ 90 0 μm、壁厚为 2～1 0 μm、同心度≥ 95%的     

Fabrication of polystyrene hollow microspheres as laser fusion targets by optimized density-matched emulsion technique and characterization

Inertial confinement fusion, frequently referred to as ICF, inertial fusion, or laser fusion, is a means of producing energy by imploding small hollow microspheres containing thermonuclear fusion fuel. Polymer microspheres, which are used as fuel containers, can be produced by solution-based micro-encapsulation technique better known as density-matched emulsion technique. The specifications of these microspheres are very rigorous, and various aspects of the emulsion hydrodynamics associated with their production are important in controlling the final product. This paper describes about the optimization of various parameters associated with density-matched emulsion method in order to improve the surface smoothness, wall thickness uniformity and sphericity of hollow polymer microspheres. These polymer microshells have been successfully fabricated in our lab, with 3–30 μm wall thickness and 50–1600 μm diameters. The sphericity and wall thickness uniformity are better than 99%. Elimination of vacuoles and high yield rate has been achieved by adopting the step-wise heating of W₁/O/W₂ emulsion for solvent removal.     

ICF靶用微球弹跳的影响因素分析

 通过对微球弹跳模型的建立,对微球弹跳过程进行了受力分析,解释了微球弹跳过程中遇到的微球粘连或“不跳”、弹跳率起伏不定及弹跳幅度高低不同等现象。通过对加载信号方向与大小、微球质量及尺寸大小、微球及反弹盘表面特性、环境湿度等影响微球弹跳效果因素的分析,提出了改善涂层表面粗糙度和弹跳效果的措施,包括根据微球大小调整微球弹跳激励方式、等离子体中和微球表面电荷、反弹盘表面改性减小球盘之间的相互作用力。     

Synthesis of carbon black/polystyrene conductive nanocomposite. Pickering emulsion effect characterized by TEM

In this study, carbon black/polystyrene electrically conductive composites were obtained by suspension polymerization technique. The composite was characterized using transmission electron microscopy, which indicated two outstanding features concerning to the carbon black; first, that the carbon particles were adsorbed onto the surface of the polystyrene particles, similarly as in the Pickering emulsion phenomenon and second, that the primary aggregate structure of the carbon black was significantly affected by the dispersion process. On the other hand, the composite resistivity was in the order of 200 Ωcm, which was attributed to the direct contact of primary carbon black particles (percolation) and not to the tunneling effect. The obtained composite was evaluated as the electrically conductive element in SBR matrix.     

A highly flexible polymerization technique to prepare fluorescent nanospheres for trace ammonia detection

The preparation of pH-sensitive nanospheres by emulsion polymerization for the detection of trace levels of ammonia is described. A fluorescent, polymerizable xanthene dye was copolymerized with styrene, crosslinkers and further copolymers aimed at enhancing the sensitivity to obtain materials for sensing of ammonia. A half-seeded technique was used to obtain stable emulsions of the monomers which were cured to obtain nanospheres with covalently attached active components. The nanospheres were embedded in a silicon matrix and the sensor films obtained were investigated regarding their response to ammonia at concentrations between 25 and 1,000 ppb. Sensors containing polystyrene nanospheres crosslinked with divinylbenzene showed the best performance in ammonia measurements exhibiting detection limits (LODs) of less than 25 ppb ammonia.     

Imaging contrast effects in alginate microbeads containing trapped emulsion droplets

This study focuses on spherical microparticles made of cross-linked alginate gel and microcapsules composed of an oil-in-water emulsion where the continuous aqueous phase is cross-linked into an alginate gel matrix. We have investigated the use of these easily manufactured microbeads as contrast agents for the study of the flow properties of fluids using nuclear magnetic resonance imaging. Results demonstrate that combined spin-spin (T(2)) relaxation and diffusion contrast in proton NMR imaging can be used to distinguish among rigid polymer particles, plain alginate beads, and alginate emulsion beads. Multi-echo CPMG spin-echo imaging indicates that the average spin-lattice (T(1)) and spin-spin (T(2)) relaxation times of the plain alginate and alginate emulsion beads are comparable. Meanwhile, diffusion-weighted imaging produces sharp contrast between the two types of alginate beads, due to restricted diffusion inside the embedded oil droplets of the alginate emulsion beads. While the signal obtained from most materials is severely attenuated under applied diffusion gradients, the alginate emulsion beads maintain signal strength. The alginate emulsion beads were added to a suspension and imaged in an abrupt, annular expansion flow. The emulsion beads could be clearly distinguished from the surrounding suspending fluid and rigid polystyrene particles, through either T(2) relaxation or diffusion contrast. Such a capability allows future use of the alginate emulsion beads as tracer particles and as one particle type among many in a multimodal suspension where detailed concentration profiles or particle size separation must be quantified during flow.     

占空比对微球a-C:H薄膜制备的影响

采用低压等离子体化学气相沉积方法（LPPCVD）,以反式二丁烯（T₂B）和氢气（H₂）为工作气体,利用间歇跳动模式在微球表面制备30 μm厚a-C:H涂层.利用原子力显微镜（AFM）和X射线照相技术对涂层表面形貌及壁厚均匀性进行表征,结果表明：随占空比减小,制备出的微球a-C:H薄膜表面粗糙度呈下降趋势,而壁厚均匀性随占空比的减小变化不明显;当占空比为1/5时,在直径为（280±50） μm 的聚乙烯醇-聚苯乙烯（PVA-PS）双层球表面制备出30 μm厚的a-C:H涂层,表面均方根粗糙度（RMS）低于30 nm;占空比为1/7时,不能维持微球的稳定跳动. 关键词： 微球 a-C:H薄膜 粗糙度 壁厚均匀性     

Surface properties of ionomers based on styrene-b-acrylic acid copolymers obtained by copolymerization in emulsion

Surface properties of styrene-b-acrylic acid copolymers obtained in emulsion and suitable ionomers before and after UV-irradiation were studied by measurements of contact angles and FTIR-ATR spectroscopy.The research focused on the influence of different content of carboxylic acid groups in copolymers, of various types and contents of alkali metal salts in ionomers and of cesium acrylate or methacrylate in ionomers on hydrophilicity of the surfaces of these samples and the course of photodegradation in them.Hydrophilicity of initial copolymer surfaces was higher than this of polystyrene as a result of presence of carboxylic acid groups, which also made the surfaces of these copolymers more sensitive to UV-irradiation.Hydrophilicity of the surfaces of ionomers containing cesium acrylates depended on the content of cesium salt in the samples. The course of ionomer photooxidation was also dependent on the content of this salt.The surface of ionomer containing cesium methacrylate was more polar than this of ionomer containing cesium acrylate.Styrene-based ionomers containing 3.7 mol% of various alkali metal acrylates had less polar surfaces than initial copolymer and they were also more resistant to UV-irradiation in comparison to the initial copolymer.Copolymers obtained in emulsion and suitable ionomers had more polar surfaces and they were more sensitive to UV-light compared to copolymers obtained in bulk and their ionomers.