PBD/PDMS共混物分散相的聚并捕获行为

借助显微-剪切装置在线研究了低速剪切场下SiO2纳米粒子含量、分散相聚丁二烯(PBD)浓度和剪切速率对PBD/聚二甲基硅氧烷(PDMS)不相容体系中聚并捕获行为的影响.结果表明,聚并捕获所形成的液滴尺寸与形状规整度由粒子含量、分散相浓度和剪切速率等因素共同决定.在较低的SiO2纳米粒子含量或较高的分散相浓度下,PBD液滴在低剪切场下发生聚并捕获,形成尺寸较大、形状不规则的液滴.增加SiO2纳米粒子含量或减小分散相浓度,能够减小分散相的尺寸并提高分散相的规整度.增加剪切速率能有效地减小分散相的尺寸并提高分散相的规整度.     

SiO2纳米粒子对受限流场下聚异丁烯/聚二甲基硅氧烷共混物相形态的影响

利用显微-光学剪切联用系统构造受限剪切环境,探讨了少量不同表面性质的SiO2纳米粒子的加入对聚异丁烯(PIB)/聚二甲基硅氧烷(PDMS)不相容共混体系分散相形态演变过程的影响.研究结果表明,少量疏水性SiO2纳米粒子的加入可抑制分散相液滴的凝聚,从而抑制珍珠链状及纤维状等超级相形态的形成,使共混物表现为近似本体流体的...     

剪切场下两亲性棒状粒子对聚异丁烯/聚二甲基硅氧烷共混物相形态的影响

合成了具有两亲表面性质的棒状SiO₂粒子,借助共聚焦激光扫描显微镜研究了两亲性棒状SiO₂粒子在共混物中的选择性分布,并通过在线剪切-显微技术和流变技术研究了其对聚异丁烯/聚二甲基硅氧烷（PIB/PDMS）不相容共混物形态结构的影响.研究表明,两亲性棒状SiO₂粒子倾向于分布在两相界面处及PIB相中.分散相的剪切诱导凝聚行为强烈依赖于粒子的含量和共混物的组成比.少量两亲性SiO₂粒子会促进分散相的凝聚,而加入足够量的粒子则能抑制分散相凝聚.     

振荡剪切流场下PS/PVME/SiO2复合物的相行为

利用光学显微镜-剪切台联用系统研究了振荡剪切流场下聚苯乙烯（PS）/聚甲基乙烯基醚（PVME）/二氧化硅（SiO₂）纳米粒子复合物的热力学稳定性. 结果表明,小振幅振荡剪切可导致PS/PVME共混物出现类似在稳态流场下的剪切诱导相容及剪切诱导相分离现象. 共混体系存在临界振荡频率ω_c,当振荡频率低于ω_c时,发生剪切诱导相分离（SID）行为,反之发生剪切诱导相容（SIM）行为. SiO₂纳米粒子的加入使复合体系的相容性提高. 存在一个临界SiO₂纳米粒子含量φ_c,当SiO₂纳米粒子含量高于φ_c时,复合体系中不存在临界振荡频率ω_c,低振荡频率下的剪切诱导相分离得到抑制. 此外,复合体系的上述行为与升温速率和共混物组成密切相关.     

磁性SiO2/PSt中空复合微球的细乳液法制备及表征

采用双原位细乳液聚合工艺,将疏水改性的磁性纳米粒子(MNP)加入到细乳液反应体系的油相中,利用增长的聚合物和单体TEOS之间的相分离原理,实现了聚合物的生成和TEOS的水解缩合同步进行,一步获得了磁性SiO2/PSt中空复合微球.通过红外光谱(FTIR)、透射电镜(TEM)、热重差热分析(TGA/DSC)和振动磁强计(VSM)对中空复合微球进行了表征.结果表明,制备的SiO2/PSt中空复合微球的尺寸范围为300～600 nm,当加入磁性纳米粒子后,得到的磁性SiO2/PSt中空微球保持了原来的中空结构,中空复合微球内腔的大小可以通过改变单体TEOS的加入量来控制.SiO2/PSt中空微球对磁性纳米粒子的包封率达到了86%.磁性SiO2/PSt中空复合微球具有超顺磁性,饱和磁强度值为14.7 emu/g.     

超支化聚乙烯亚胺接枝二氧化硅的制备及在聚丙烯改性中的应用

首先利用3-缩水甘油氧基丙基三甲氧基硅烷(简称GPS)作为偶联剂,对纳米SiO2进行表面改性,获得表面含有环氧基的SiO2纳米粒子(SiO2-GPS).利用这些环氧基与超支化聚乙烯亚胺(HPEI)分子中的氨基进行反应,得到SiO2接枝超支化聚乙烯亚胺的纳米粒子(SiO2-GPS-g-HPEI).然后利用SiO2-GPS-g-HPEI与聚丙烯(PP)和PP接枝的马来酸酐(PP-g-MAH)共混、模压,制备PP/SiO2-GPS-g-HPEI/PP-g-MAH复合材料.红外光谱测试和热失重分析(TGA)测试结果表明,SiO2纳米粒子表面依次接枝了GPS和HPEI;扫描电子显微镜(SEM)的测试结果显示,SiO2-GPS-g-HPEI在聚丙烯基体中分散良好,其材料的冲击断裂为韧性断裂;复合材料共混时,扭矩的增加证明了共混物中分散相(SiO2-GPS-g-HPEI)与基体(PP/PP-g-MAH)界面之间存在一定的相互作用.少量SiO2-GPS-g-HPEI加入PP/PP-g-MAH中,冲击强度可增加96.3%,拉伸强度也有较大的提高.     

Fe3O4/聚苯乙烯纳米复合材料的结构与性能

采用油酸(OA)表面改性的粒径均一的Fe3O4纳米粒子(OA-Fe3O4)与工业化聚苯乙烯(PS)通过溶液共混挥发干燥方法得到了具有超顺磁性的OA-Fe3O4/PS纳米复合材料.透射电子显微镜表征结果表明,在OA-Fe3O4质量分数为1%~10%时,OA-Fe3O4纳米粒子均匀分散在PS聚合物基体中.示差扫描量热分析表明,随着纳米粒子加入量的增加,纳米复合材料的玻璃化转变温度逐渐降低.热失重分析表明,OA-Fe3O4的存在显著提高了PS在空气条件下的热稳定性.流变分析表明,随着纳米粒子加入量的增加(0~10%),复合材料黏度逐渐降低.进一步研究了分子量双峰分布的PS与OA-Fe3O4纳米复合体系的流变行为,结果表明,当PS基体的平均分子量大于临界缠结分子量,且填充的纳米粒子的半径小于双峰分布PS的均方旋转半径时,加入纳米粒子仍然导致体系的复合黏度降低.     

磁性纳米TiO_2/SiO_2/NiFe_2O_4的制备及其催化性能

采用溶胶凝胶法制备了核壳结构磁性纳米TiO2/SiO2/NiFe2O4催化剂.利用XRD、TEM、VSM等手段对样品的粒径、晶体结构、磁性和光催化性能进行了研究.结果表明:SiO2/NiFe2O4的加入抑制了TiO2纳米粒子的生长,使晶粒尺寸减小,促进了锐钛矿相向金红石相的转变,催化剂的回收率和光催化性能均得到提高.光催化实验结果表明,当SiO2/NiFe2O4的负载量为15%时,焙烧温度为500℃时对亚甲基兰的脱色率最高.     

SiO_2纳米粒子对PMMA/PS共混物共连续相结构退火粗化过程的影响

考察了亲水性纳米SiO2粒子的加入对聚甲基丙烯酸甲酯/聚苯乙烯(PMMA/PS)共混体系的共连续相结构在静态高温退火时形态稳定性的影响,发现静态高温退火条件下,填充体系共连续组成范围变窄幅度较小、特征结构尺寸的粗化速率减慢.流变测试表明纳米SiO2粒子加入之后PMMA/PS共混体系的黏弹性显著提高,从而能减缓破坏构成共连续相结构的纤维断裂或回缩等松弛过程的速率,有效地抑制PMMA/PS共混体系的共连续相结构粗化进程,提高相结构的稳定性.根据现有的两种粗化理论的定性分析表明,在高填充量的共混体系中,加入纳米SiO2粒子导致共混体系的黏弹性的显著改变是影响PMMA/PS共混体系在静态高温退火时共连续相结构粗化速率的主要因素,相对而言界面张力的变化对共连续相结构在静态高温退火时的粗化速率影响则应该较小.     

Versify-g-(MAH-co-St)对改善PA6/Versify共混物增韧和均衡其力学性能的影响

使用挤出机对乙丙共聚物Versify2300(乙烯含量12wt%)(V-2300)进行马来酸酐(MAH)和苯乙烯(St)多单体熔融接枝得到接枝物Versify-g-(MAH-co-St)(g-V-2300).通过SEM、FTIR和力学性能测试,研究了g-V-2300对PA6/(V-2300+g-V-2300)(70/30)共混物形态和性能的影响.研究结果表明,随着g-V-2300含量的提高,V-2300分散相粒径不断减小且分散均匀.当g-V-2300比例为25wt%时,分散相尺寸只有0.27μm,此时共混物的izod冲击强度达到324.54J/m,为PA6/(V-2300+g-V-2300)(70/(30+0))共混物的16倍.g-V-2300的加入,显著改善了PA6/(V-2300+g-V-2300)(70/30)共混物的冲击强度,其伸长率,拉伸强度和抗弯强度也得到提高,从而得到具有均衡力学性能的增韧尼龙6合金.     

The morphology of immiscible PDMS/PIB blends filled with silica nanoparticles under shear flow

The influence of surface nature (hydrophobic and hydrophilic) and concentration of silica nanoparticles on the coalescence behavior of immiscible polydimethylsiloxane (PDMS)/polyisobutylene (PIB) (90/10) blends under simple low-rate shear flow were investigated via optical shear technique. It was found that the coalescence of PIB droplets in PDMS matrix was suppressed efficiently by incorporating hydrophobic silica nanoparticles, and a constant droplet size was obtained at high particle contents. The addition of a small amount (<0.4 wt.%) of hydrophilic silica nanoparticles also decreased the size of PIB droplets. Clusters of small PIB droplets were formed at low filler concentration. When the filler concentration exceeded 0.8 wt.%, the clusters of PIB drops disappeared and elongated PIB threads with large size were formed, which suggest that the coalescence of PIB droplets was promoted. The results indicate that the discrepancy in the morphology evolution of PDMS/PIB blends upon the addition of silica nanoparticles is controlled not only by the surface chemistry of nanoparticles but also by their concentration in the blends.     

Morphological hysteresis in immiscible PIB/PDMS blends filled with fumed silica nanoparticles

The morphological hysteresis behavior of immiscible polymer blend reflects the dependence of their steady-state morphology on the shear protocol applied. In this work, the influences of hydrophobic and hydrophilic fumed silica nanoparticles on the morphology hysteresis behavior of immiscible polyisobutylene (PIB)/polydimethylsiloxane (PDMS) (10/90) blends under simple shear flow were investigated by using optical shear technique. Compared with particle-free blend, the morphology hysteresis zone of filled blends was found to be expanded by the addition of hydrophobic or hydrophilic fumed silica nanoparticles. It was found that the expansion of the morphology hysteresis zone in hydrophobic nanoparticle-filled blend stemmed from the suppression of droplet coalescence. However, the expansion in the morphological hysteresis zone for hydrophilic nanoparticle-filled blend, which was less noticeable, might originate from the more difficult breakup of PIB droplets upon the addition of nanoparticles.     

氯甲基聚苯乙烯/硅胶复合微粒的制备与表征

采用"接出(grafting from)"方式,在溶液聚合体系中将苯乙烯(St)接枝聚合在微米级硅胶表面,制备了接枝微粒PSt/SiO2;使用新型氯甲基化试剂1,4-二氯甲氧基丁烷,对接枝在硅胶表面的聚苯乙烯进行了氯甲基化(CM)反应,制得了氯甲基聚苯乙烯/硅胶(CMPS/SiO2)复合微粒.采用热重分析(TG)测定了PSt/SiO2的接枝度,并使用扫描电子显微镜(SEM)观察了其形貌;通过红外光谱法(FTIR)与佛尔哈德分析法表征了CMPS/SiO2的化学结构与组成.重点考察了各种因素对PSt/SiO2氯甲基化反应过程的影响规律.研究结果表明,CMPS/SiO2的制备不仅具有绿色环保的特点,而且反应容易控制.反应时间、溶剂种类与用量、催化剂种类与用量及氯甲基化试剂的用量等因素均会对该复合微粒的制备产生影响,如影响CMPS/SiO2的氯甲基化程度;抑制或促进已接枝的PSt大分子链之间通过Friedel-Crafts反应发生交联.若选用SnCl4为催化剂,以CH2Cl2为溶剂,在室温下反应10 h左右,可制得氯含量接近16 wt%(以接枝的PSt为基准计算)的CMPS/SiO2.     

离子液体中二氧化硅纳米微粒的制备及其摩擦学性能

以 1-甲基-3-丁基咪唑四氟硼酸盐离子液体为溶剂, 合成了二氧化硅纳米颗粒, 并以含有二氧化硅纳米颗粒的离子液体作为基础油,对其摩擦学性能进行研究; 用透射电子显微镜对二氧化硅的形貌进行分析, 用扫描电子显微镜对钢球磨斑表面的形貌进行了分析. 结果表明, 添加二氧化硅纳米颗粒的离子液体具有较好的润滑性能.     

Shapes of dispersed phase in confined PIB/PDMS blends with different compositions during shear flow

The morphology of immiscible fluid mixtures under confined environment usually displays different scenarios compared with those presented in bulk systems. In this work, the influence of confinement and component ratio on the droplet morphology of immiscible polyisobutylene (PIB)/polydimethylsiloxane (PDMS) blends in confined steady shear flow was investigated. While increasing the degree of confinement, the morphology of dispersed phase experienced a transition from the bulk behavior toward the confined behavior. Increasing the concentration of PIB phases in confined blends resulted in more coarsened structure under low shear rate and generated pearl necklace or string-like structures under a higher shear rate. The maximum aspect ratio of PIB droplets increased while increasing PIB concentration. The width and the aspect ratio of PIB droplets obtained experimentally were compared to the predictions of a single droplet MM model for bulk flow and an M model considering confinement. The experimental droplet width agreed well with the predictions of these two models only in the small droplet zone, large deviations appeared for the degree of confinement up to 0.36 and higher, whereas constant droplet width was found. The M model decreased the deviation between the experimental aspect ratio and the prediction of MM model in the high Ca zone. Good agreement between the prediction of M model and experiment results was found when the orientation angles of the droplets were corrected by using the M model.     

Improving Impact Toughness of Polylactide/Ethylene-co-vinyl-acetate Blends via Adding Fumed Silica Nanoparticles: Effects of Specific Surface Area-dependent Interfacial Selective Distribution of Silica

Adding fumed silica(SiO_2) has been considered as an effective method for tailoring the phase morphology and performance of elastomer-toughened plastic binary blends. It has been demonstrated that the selective distribution of SiO_2 plays a decisive role in the mechanical properties of plastic/elastomer/SiO_2 nanocomposites, especially for the impact toughness. In this work, we aim to illuminate the role of specific surface area in controlling their selective distribution of fumed SiO_2 and consequent mechanical properties of plastic/elastomer binary blends. Three types of SiO_2 with different specific surface areas were incorporated into polylactide/ethylene-co-vinyl-acetate(PLA/EVA) model blends by melt blending directly. It was found that the selective distribution of SiO_2 is largely determined by their specific surface areas, i.e. SiO_2 nanoparticles with low specific surface area has a stronger tendency to be located at the interface between PLA matrix and EVA dispersed phase as compared to those with high specific surface area. The specific surface area-dependent interfacial selective distribution of SiO_2 is mainly attributed to the extent of increased viscosity of EVA dispersed phase in which SiO_2 nanoparticles are initially dispersed and resultant migration rate of SiO_2 nanoparticles. The interfacial localized SiO_2 nanoparticles induce an obvious enhancement in the impact toughness with strength and modulus well maintained. More importantly, in the case of the same interfacial distribution, toughening efficiency is increased with the specific surface area of SiO_2. Therefore, this is an optimum specific surface area of SiO_2 for the toughening. This work not only provides a novel way to manipulate the selective distribution of SiO_2 in elastomer-toughened plastic blends toward high-performance, but also gives a deep insight into the role of interfacial localized nanoparticles in the toughening mechanism.     

Solubilization of silica nanoparticles in alkanes and poly(α-olefin)s by functionalized polyisobutylene oligomers

Covalent and noncovalent chemical methods that use oligomeric lipophilic agents to solubilize silica nanoparticles in heptane and poly(α-olefin) (EPAO) solvents are described. While only modest solubilization efficiencies are seen with an octadecyl group, a variety of terminally functionalized polyisobutylene (PIB) derivatives are more efficient. Both covalent and noncovalent chemistry was found to be effective. Covalent modification solubilized up to 34 wt% of silica nanoparticles (SiNPs) as stable solutions in heptane or PAOs. Noncovalent modification was however more effective, solubilizing up to 70% of SiNPs in heptane or PAOs. The most successful covalent approach used PIB oligomers containing terminal triethoxysilane groups to covalently modify SiNPs. Alternatively, SiNPs that were first functionalized with amine groups could be solubilized in heptane or PAOs with polyisobutylene containing sulfonic acid groups using acid–base chemistry. Studies of these and other solubilization chemistry was also carried out using fluorescent labels, studies that confirmed the gravimetric analyses of the heptane-solubilized SiNPs. Transmission electron microscopy of a PAO solution of these solutions showed that these SiNPs were present as small aggregates dispersed in the PAOs.     

悬浮液气-液界面二元胶体颗粒的漂浮组装机理

提出一种在悬浮液气-液界面漂浮组装亚微米单分散聚苯乙烯(PS)微球和纳米SiO2颗粒二元胶粒晶体的新方法, 并系统研究了漂浮组装机理. 研究表明, 聚苯乙烯微球和二氧化硅两种胶体颗粒在悬浮液气-液界面的漂浮组装是以PS微球的组装为主导的. 在一定PS微球相浓度范围内, 悬浮液中PS 微球与SiO2颗粒的初始体积配比基本不影响PS微球有序组装的形成. PS微球粒径在150-500 nm时易于形成有序排列, 较小或较大粒径的PS微球难以形成有序排列. SiO2颗粒的组装是一种以PS微球为“基底”的沉积过程. 二元胶粒晶体中SiO2颗粒的体积分数由其在混合悬浮液中的相浓度所决定.     

控制自由基聚合制备Fe_3O_4/SiO_2/P(AA-MMA-St)磁性复合微球

用原硅酸乙酯对Fe3O4纳米粒子进行表面改性得到Fe3O4/SiO2磁流体.在Fe3O4/SiO2磁流体存在下,以1,1-二苯基乙烯(DPE)为自由基聚合控制剂,利用乳液聚合法制备了Fe3O4/SiO2/P(AA-MMA-St)核-壳磁性复合微球.用红外光谱(FTIR)、振动样品磁强计(VSM)、透射电镜(TEM)、X光电子能谱(XPS)、热重分析(TGA)、示差扫描量热仪(DSC)对所制备的磁流体、磁性高分子复合微球的结构、形态、性能进行了表征.研究发现,原硅酸乙酯水解后能在Fe3O4表面形成硅膜保护层从而避免Fe3O4的酸蚀,使Fe3O4/SiO2/P(AA-MMA-St)复合微球的比饱和磁化强度比同样条件下制备的Fe3O4/P(AA-MMA-St)微球提高了28%;DPE能有效控制自由基在Fe3O4/SiO2磁流体表面均匀地引发单体聚合,得到平均粒径为422 nm,无机粒子含量为40%,比饱和磁化强度为34.850 emu/g,表面羧基含量为0.176 mmol/g的磁性复合微球.