淀粉乳液形成过程主要影响因素的耗散粒子动力学模拟与实验

以环己烷为油相、淀粉乳液为水相、Span60和Tween60为乳化剂, 用耗散粒子动力学(DPD)方法研究了淀粉乳液形成过程及油水比、乳化剂用量等因素对淀粉乳液形成的影响. 结果表明, 模拟6000步时, 体系达到平衡状态; 乳滴的粒径随乳化剂含量的增加先减小而后增加, 随淀粉含量的增加而增加, 随环己烷含量的减小而增加; 形成稳定淀粉乳液体系的参数范围: 7＜油水比≤20, 9%＜乳化剂用量≤18%. 实验结果表明, 乳化剂含量为11%～15%时, 微球的粒径随乳化剂含量的增大而减小; 乳化剂含量大于15%时, 微球的粒径反而增大. 实验与模拟的结果吻合.     

聚苯乙烯-甲基丙烯酸甲酯功能微球的合成

本文研究了在用乳液聚合法合成苯乙烯/甲基丙烯酸甲酯共聚功能微球过程中,乳化剂、电解质、油水比、溶剂等因素对共聚胶乳微粒的粒径大小和粒度分布的影响。结果表明,乳化剂的种类和浓度对生成胶乳微粒的粒径有很大影响,且胶乳微粒的粒径随电解质浓度的增加以及油水比的减小而减小,加入溶剂可明显提高所得微粒的粒径。     

明胶微球粒径控制的研究

采用乳化-凝聚法,在油包水(w/o)的体系中对明胶微球(GMs)粒径、微球的形态和分散性等进行了研究.扫描电子显微镜(SEM)和粒径分布曲线的结果表明在乳化体系中,提高明胶溶液的浓度或水油比例,明胶微球的粒径增大;增加乳化剂的用量,微球的粒径减小;选择合适的乳化时间和搅拌速率,可以改善微球的分散性和表面光滑程度.同时,通过调控实验条件,在明胶溶液浓度0.100 g/mL,水油比1/5,乳化剂浓度0.05g/mL时研制出了平均粒径为3.58μm的表面光滑、分散性好的明胶微球.     

中性条件下魔芋胶微球的制备及其药物释放

以span-80为表面活性剂,石蜡为油相(O),魔芋胶溶液为水相(W),采用W/O乳化法,在中性条件下添加硫酸钠制备魔芋胶微球。研究表明:在85℃反应5 h,当油水体积比(O/W)处于6~10时,微球粒径为0.120~0.330 mm;增加O/W比,可减小微球粒径;增加反应物浓度,可减少微球的溶胀度。对包裹牛血清蛋白(BSA)的微球进行体外释放表明,增加微球粒径、反应物浓度可以减缓药物释放速率。     

W/O型微乳法制备淀粉基纳米粒

在正己烷、Span-60和NaOH水溶液的W／O型淀粉微乳液中,进行淀粉与环氧氯丙烷交联反应制备淀粉微球,用质量分数为1％的淀粉水浆液制备出微球的流体力学半径Rb为7．08—113nm,其中粒径不超过100nm的纳米粒在整个微粒体系中占69％,平均粒径为92．2nm。TEM和DLS结果表明,制得的微粒呈圆球形,且微粒的流体力学半径随淀粉水浆液浓度的增加而增大并分布变宽,淀粉水浆液的浓度低有利于淀粉基纳米粒的形成。     

粒径和孔径可控的多孔交联聚苯乙烯微球的制备

采用悬浮聚合方法合成了多孔交联聚苯乙烯微球,研究发现微球的粒径与分散剂含量、水油比、搅拌速度和成孔剂有关,而微球的孔径与成孔剂的种类和含量有关。 增加分散剂的用量,提高水油比和加快搅拌速度都能导致微球的粒径减小。 微球的孔径和粒径均随着成孔剂与聚合物溶度参数差值变大而增加。通过改变以上条件得到粒径为100~300 μm和孔径为8~36 nm的交联度为27%的多孔交联聚苯乙烯微球,并利用光学显微镜、场发射扫描电子显微镜(SEM)和氮气吸附解吸法对微球进行了相应的表征。 得到的微球在固相合成载体中有一定的应用前景。     

淀粉/丙烯酸反相乳液体系的稳定性研究

以丙烯酸(AA)单体的水溶液为水相,液体石蜡为油相,失水山梨醇三油酸酯(Span 85)和辛基苯基聚氧乙烯醚(Opan 10)为复合乳化剂,合成了淀粉/丙烯酸反相乳液;考察了乳化剂亲水亲油平衡值(HLB值)、油水比、乳化剂用量、单体浓度、温度对乳液稳定性和类型的影响.结果表明,合成淀粉/丙烯酸稳定反相乳液体系的适宜条件...     

影响反相微乳液导电性能的因素

分别以聚乙二醇辛基苯基醚(Triton X-100)或十六烷基三甲基溴化铵(CTAB)为表面活性剂, 与正己烷、正己醇和水构成反相微乳液. 研究了水相H+浓度、表面活性剂、助表面活性剂等对微乳液导电性能的影响. 结果表明, 增加水相H+浓度可大幅度提高反相微乳液的导电能力, 当H+浓度由1.0 mol•L-1增加到10 mol•L-1时, 微乳液的电导率可提高1~2个数量级. 当水相H+浓度为10 mol•L-1时, 微乳液的电导率随溶水量的增大而增大, 水油体积比为3:10时, 两种体系的电导率均达到3200 μS•cm-1. Triton X-100浓度对微乳液的电导率影响较大, 电导率随其浓度增加而增大；而CTAB浓度对微乳液电导率的影响较小, 电导率随其浓度增加略有减小；助表面活性剂正己醇使非离子型反相微乳液的电导率下降, 而使阳离子型反相微乳液的电导率先增大, 然后减小, 呈骆峰状变化.     

月桂醇微小球制作及缓释机理的研究

本文用溶剂蒸发法制备了月桂醇缓释微小球。阐述了微球粒径与搅拌速度、温度、核心材料与基质材料比例以及乳化剂浓度、油水相体积比等制备条件的关系。测定了它在乙醇介质与空气中的释放速率;证明了它的释放机制属于整体型扩散渗透体系并用扫描电镜(SEM)观察了微球表现形态。     

微波辐射无皂乳液聚合制备聚氰基丙烯酸正丁酯微球

在微波辐射的"非致热效应"作用下,采用不含乳化剂的无皂乳液聚合,制备了聚氰基丙烯酸正丁酯(PBCA)微球。通过透射电子显微镜观察了微球的形态结构,利用激光光散射粒度测定仪测定了微球的粒径大小及其分布,探讨了柠檬酸浓度、氰基丙烯酸正丁酯(BCA)用量、微波辐射功率等对微球粒径的影响。研究结果表明,与常规无皂乳液聚合相比较,微波作用下的无皂乳液聚合反应时间缩短,得到的PBCA微球粒径更小,分散性更好。柠檬酸浓度增加,PBCA微球粒径逐渐增大;单体浓度增加,或微波功率增加,PBCA微球的粒径先减小后增大。当柠檬酸质量分数为0.005%、BCA体积分数为1.0%、微波功率为600W时,所制得的微球粒径最小,为200nm左右。     

Tuning the morphology of amphiphilic copolymer aggregates by compound emulsifier via emulsion–solvent evaporation

A series of poly(4-vinylpyridine)-b-poly{6-[4-(4-butyloxyphenylazo)phenoxy]hexyl methacrylate} (P4VP-b-PAzoMA) were employed to fabricate aggregates via the emulsion–solvent evaporation method. The emulsion was stabilized by compound emulsifier composed of SDS and span60. By tuning the ratio of two emulsifiers, P4VP-b-PAzoMA could self-assemble into various morphologies including porous microspheres, tremella-like aggregates, bowl-like aggregates and wrinkled microspheres. The transformation of the morphologies could be ascribed to three major aspects: the stability of emulsified chloroform droplets, the permeation of water into chloroform and the dispersity of the interior water droplets with regard to different HLB values. Besides, the morphology could even be tuned by changing the block ratio and the concentration of P4VP-b-PAzoMA, and the HLB dependent morphology changing was also proved within other block ratio or different concentration. The study uncovers a convenient and effective technique to manipulate the morphology of amphiphilic copolymer aggregates.     

水溶液中嵌段共聚物的耗散颗粒动力学模拟

用耗散颗粒动力学(dissipative particle dyanmics)模拟方法研究了Pluronic L64(PL64)和Pluronic 25R4(25R4)三嵌段共聚物水溶液中的介观相分离,模拟了聚合物聚集的动力学变化过程. 结果发现,在水溶液中,不同浓度的聚合物溶液表现出不同的介观结构,如分散相、球形胶束、双连续相(bicontinuous)等；而Pluronic L64在低浓度时更容易形成双连续相. 耗散颗粒动力学模拟可以作为实验的一个辅助,提供介观层次上的信息,对实验起到指导作用.     

Self-assembly and gel formation processes in an aqueous solution of L-cysteine and silver nitrate

The experimental and theoretical study of self-assembly and gel formation processes in an aqueous solution of L-cysteine and silver nitrate (CSS) is performed. A method to obtain CSS-based hydrogel is described. Its characteristic feature is the formation of a spatial gel network at a low concentration of the dispersed phase (～0.01%) and the thixotropic behavior. The experimental examination of this system provides the formulation of a phenomenological model of the gel formation. Based on it, an atomistic computer model is made to verify our assumptions. It is shown that due to the formation of donor-acceptor sulfur-silver bonds there form clusters from silver mercaptide (SM) zwitterions, from which in turn filamentous aggregates form. An analysis of the molecular configurations formed shows that the filamentous aggregates are stabilized by the interaction of 3 ?NH ₃ ⁺ and ?C(O)O^? groups belonging to SM zwitterions in the composition of the neighboring clusters. The obtained conclusions underlie the mesoscopic model based on which we managed to illustrate the processes of generation and growth of filamentous aggregates in large spatial scales.     

催化剂对乳液模板法制备碳材料形貌的影响

以液体石蜡为油相,间苯二酚和甲醛的水溶液为水相,吐温80和司班80为乳化剂,获得油/水(O/W)型乳状液.将该乳状液聚合、碳化去除模板后制得了碳材料,研究了不同催化剂对所得碳材料形貌的影响.结果表明:选择NaOH为催化剂时,制得的碳材料是一种具有孔壁和孔洞的多孔碳泡沫,典型样品的孔径约为1-2μm;当氨水为催化剂时,所得碳材料是由微球或者相互缠绕的蠕虫状粒子组成的块体材料,这些微球或粒子的直径主要集中在1-2μm,与NaOH为催化剂时所得碳泡沫的孔径尺寸相当.研究发现,氨水的加入使得乳液体系发生了相转化,由原来的O/W型乳液逐渐转变为W/O型高内相乳液.从分子间氢键出发,应用内聚能理论探讨了催化剂导致的乳液相变以及不同形貌碳材料的形成过程.     

Synthesis and plugging effect of inverse emulsion polymerization microspheres (OPME) for oil-based drilling fluids

It is difficult to seal oil-based drilling fluids in the large pore and micro-fracture formation, and there are few suitable materials for the oil phase with good sealing ability at present. In order to solve the problem of the lack of sealing ability of oil-based drilling fluids, acrylamide, 2-acrylamido-2-methylpropane sulfonic acid, and acryloyl morpholine were used as monomers, N'N-methylenebisacrylamide was used as a cross-linking agent, Span-80 and Tween-60 were used as emulsifiers, and 2,2′-azobis(2-methylpropionamidine) dihydrochloride was used as an initiator. Polymer microsphere emulsion OPME was synthesized by inverse emulsion polymerization. The structure of polymer microspheres was characterized by infrared spectroscopy, scanning electron microscopy, electron microscopy, H NMR, laser particle size analysis and thermogravimetric analysis. The optimal synthesis conditions were determined by the control variable method: the monomer ratio of acrylamide, 2-acrylamido-2-methylpropane sulfonic acid, and acryloyl morpholine was 45:20:15, the amount of emulsifier was 8%, and the reaction temperature was 55℃. The synthetic polymer microspheres were added to the oil-based drilling fluids to perform filtration and loss plugging at atmospheric pressure and high-temperature and high-pressure, as well as pore and artificial fracture core plugging evaluation. The evaluation results show that the permeability reduction rate of pore core can reach 82%, and that of fracture core can reach 100% by adding polymer microspheres with 3% dosage. Finally, the pressure transmission experiment proves that the addition of polymer microspheres can slow the pressure transmission and filtrate intrusion, and enhance the stability of wellbore. Therefore, polymer microspheres are a micron-level plugging agent with good compatibility and high performance with oil-based drilling fluids, and the 3% dosage can better seal the formation of large pores and micro-fractures, which has a good potential for field application.     

Mesoscopic Simulation of Aggregates in Surfactant／Oil／Water Systems

The aggregates in sodium dedecylsulphate(SDS)/dimethylbenzene/water systems have been investigated using dissipative particles dynamic(DPD) simulation method.Through analyzing three-dimensional structures of aggregates,three simulated results are found.One is the phase separation,which is clearly observed by water density and the aggregates in the simulated cell;another is the water morphology in reverse micelle,which can be found through the isodensity slice of water including bound water,trapped water and bulky water;the third is about the water/oil interface,i.e.,ionic surfactant molecules,SDS,prefer to exist in the interface between water and oil phase at the low concentraion.     

三嵌段共聚物EO20PO70EO20相分离行为的耗散粒子动力学模拟

采用耗散粒子动力学(DPD)方法研究了嵌段共聚物EO₂₀PO₇₀EO₂₀(P123)在水、乙醇/水溶液及二氧化硅溶胶体系中的相分离行为. 不同质量分数的P123在水溶液中共形成4种相分离状态: 球状胶束(10%); 椭球胶束(20%)、棒状胶束(30%)和三维立方胶束(50%). 在模板剂质量分数为10%的乙醇/水溶液中, 模板剂胶束稳定性随着乙醇含量的增加而变差. 在二氧化硅溶胶体系中, 模板剂质量分数低于5%时无胶束形成; 模板剂质量分数增至10%时, P123发生相分离形成三维球状胶束; 随着模板剂质量分数的进一步增加, 模板剂分子夹含着水分子形成三维椭球状结构(20%)、三维立方结构(40%)和层状结构(60%). 模拟结果与实验结果一致, 说明DPD模拟可以从计算角度推测模板剂对介孔材料结构的影响.     

Microfluidic Synthesis of Rigid Nanovesicles for Hydrophilic Reagents Delivery

We present a hollow‐structured rigid nanovesicle (RNV) fabricated by a multi‐stage microfluidic chip in one step, to effectively entrap various hydrophilic reagents inside, without complicated synthesis, extensive use of emulsifiers and stabilizers, and laborious purification procedures. The RNV contains a hollow water core, a rigid poly (lactic‐co‐glycolic acid) (PLGA) shell, and an outermost lipid layer. The formation mechanism of the RNV is investigated by dissipative particle dynamics (DPD) simulations. The entrapment efficiency of hydrophilic reagents such as calcein, rhodamine B and siRNA inside the hollow water core of RNV is ≈90 %. In comparison with the combination of free Dox and siRNA, RNV that co‐encapsulate siRNA and doxorubicin (Dox) reveals a significantly enhanced anti‐tumor effect for a multi‐drug resistant tumor model.     

Experimental research and DPD simulation on the interaction between an ethoxy-modified trisiloxane and F127

The interactions between surfactants and polymers are widely investigated due to favorable changes on properties in their mixtures. Silicone surfactants and pluronic copolymers, both having low toxicity, are used in the detergent, cosmetics, medical, and pharmaceutical fields. Their mixture may gain better performance in their further applications. Therefore, we investigated the interaction between an ethoxy-modified trisiloxane (a silicone surfactant named Ag-64) and a block polyether F127 in this paper. From aggregation behavior of Ag-64 and F127, the formation mechanism and conformation of the aggregates were proposed based on experiments and dissipative particle dynamics (DPD) simulation. The surface activity and aggregation behavior of Ag-64 are affected by F127 in aqueous solutions. As the amounts of added Ag-64 increase, two types of aggregates (Ag-64/F127 aggregate with F127 as skeleton and the “pearl- necklace” aggregate in which Ag-64 micelles are strung along F127 chain) form successively. At higher polymer concentration, F127 twists together to form a coil/cluster aggregate with Ag-64. The results of DPD simulation approve that two main factors, the hydrophobic association and twist of F127 coil, contribute to the formation of different aggregates of Ag-64 and F127.