聚合物分散剂对氟虫脲水悬浮剂分散稳定性的影响

通过测定药物颗粒界面Zeta电位和平均粒径, 研究了聚合物分散剂苯乙烯磺酸聚合物钠盐(GY-D08)用量、pH和盐离子对氟虫脲水悬浮剂分散稳定性的影响, 研究结果表明, 分散剂GY-D08的加入量与水悬浮剂分散效果密切相关, 制备质量分数为5%氟虫脲水悬浮剂的GY-D08最佳用量为2%, GY-D08用量过多或过少都会使分散效果下降; pH影响分散剂GY-D08在水中的电离能力, 当pH=9时, GY-D08分子完全电离, 能为颗粒提供较大的静电位阻, 水悬浮剂分散稳定性最好; Mg²⁺或Ca²⁺压缩颗粒界面的双电层, 降低Zeta电位, 使颗粒因带电量减少而聚结, 导致水悬浮剂分散稳定性变差, 且Mg²⁺或Ca²⁺浓度愈大, 其分散稳定性愈差; 当离子浓度相同时, Ca²⁺压缩双电层的能力比Mg²⁺强, 添加Ca²⁺后的水悬浮剂的分散稳定性更差.     

溶剂替换法制备氟铃脲水悬浮剂及其分散稳定性

采用溶剂替换法制备了氟铃脲水悬浮剂,通过测定颗粒的平均粒径Dav和颗粒界面的Zeta电位,研究了分散剂种类、添加量以及有机相中乙醇的加入量对水悬浮剂分散稳定性的影响。 结果表明,在相同条件下,以苯乙烯丙烯酸共聚物(MOTAS)作为分散剂制备的水悬浮剂的分散效果较好;当MOTAS添加质量分数为1%时,Dav最小,Zeta电位绝对值最大,体系分散稳定性最好;在有机相中添加乙醇可以显著提高氟铃脲水悬浮剂的分散稳定性,当有机相中乙醇的加入质量分数增加至31.2%时分散稳定性达到最好。     

聚羧酸盐分散剂在农药水悬浮剂中的应用及作用机理分析

聚羧酸盐分散剂具有独特的分散性能,可显著提高农药水悬浮剂等剂型的稳定性.本文应用3种聚羧酸盐分散剂分别制备了3种农药水悬浮剂,研究了聚羧酸盐分散剂在原药颗粒表面的吸附特征和吸附热力学,研究了聚羧酸盐分散剂对农药水悬浮体系Zeta电势和流变性质的影响,并分析了体系在热贮前后各稳定性参数的变化,最终得到了具有长期储存稳定性的农药水悬浮剂产品.研究结果显示,聚羧酸盐分散剂在原药颗粒表面的吸附符合Langmuir单分子层吸附模型,其中吸附热力学参数?G_(ad)0、?S_(ad)0、?H_(ad)0且|?H_(ad)|40 kJ mol~(-1),表明该吸附为自发进行的、放热、熵增的物理吸附过程.聚羧酸盐分散剂通过提高悬浮体系的Zeta电势,使得分散粒子间相互排斥,改善了体系的流动性能,从而提高农药水悬浮剂产品的长期储存稳定性.     

纳米SiO2/HPAM/SDS分散体系稳定性的改进及其对驱油性能的影响

分析了60℃、1. 0×104mg/L氯化钠盐水和模拟地层水中纳米SiO2/HPAM/SDS分散体系的浊度实验及Zeta电位,发现Ca2+、Mg2+离子是体系失去稳定性的主要原因。根据沉降实验及Zeta电位分析仪探讨了降低p H值和添加络合剂对模拟地层水中纳米SiO2/HPAM/SDS体系稳定性的改善效果及机理,同时利用流变仪及界面张力仪分析了两种方法对体系驱油性能的影响。结果表明,p H值降低,体系的Zeta电位绝对值降低,但SiO2周围H+保护层的形成及水化作用力的增强改善了体系的稳定性;络合剂Na2EDTA、ATM P和Na4EDTA均能增强体系的稳定性,Na2EDTA和ATM P络合Ca2+、Mg2+的同时降低了体系的p H值,而体系的黏度随p H值的降低急剧下降; Na4EDTA加入后,体系的p H值增大,稳定配位化合物的形成使体系的Zeta电位绝对值、黏度、储能模量和损耗模量增加,降低界面张力的能力增强。因此,在SiO2质量分数为0. 5%的体系中加入质量分数为0. 4%的Na4EDTA(最佳质量分数),采收率提高了3. 1%。     

含不同氨基酸反相微乳体系中胆红素钙的形成与稳定性

在聚乙二醇辛基苯基醚(OP)/正己醇/环己烷/水反相微乳液和甘氨酸、精氨酸、组氨酸3种含不同氨基酸的反相微乳液体系中成功地制备了胆红素钙,考察了氨基酸对胆红素钙的组成、形貌、配位方式及稳定性的影响。采用透射电子显微镜、表面Zeta电位、红外光谱和紫外光谱等测试技术对样品进行了表征。结果表明,此反相微乳体系中所得球形颗粒为中性胆红素钙,平均粒径80nm,在水分散体系中颗粒的稳定性随分散体系pH值的升高而先降低后增加,当pH=4.9时,颗粒表面Zeta电位值为0。3种亲水性氨基酸的加入促进胆红素钙颗粒的成核,最终影响胆红素钙的微结构、颗粒形貌和稳定性。当加入的氨基酸为组氨酸、甘氨酸时,所得胆红素钙球形颗粒形貌无明显变化,但平均粒径依次减小至60和40nm,其水分散体系中的稳定性明显增加;当加入的氨基酸为精氨酸时,所得胆红素钙颗粒形貌不规则,粒径非常小,不稳定,易形成聚集体。     

K~+、Na~+、Ca~(2+)、Mg~(2+)对胜利褐煤平衡复吸水的影响

以胜利褐煤为研究对象,利用FT-IR等手段,用灰分、不同湿度下的平衡复吸水含量等,系统研究了不同相对湿度下K+、Na+、Ca2+、Mg2+的水合作用对胜利褐煤平衡复吸水含量的影响。结果表明,相同浓度不同类型的金属离子与煤样的交换能力的趋势为Ca2+Na+K+Mg2+。金属离子对胜利褐煤平衡复吸水含量影响力的顺序为Mg2+Ca2+Na+≈K+。相对湿度高时,平衡复吸水含量的主要控制因素为游离水分子之间的分子作用力;相对湿度中等时,平衡复吸水含量的主要控制因素为金属水簇与毛细管之间的毛细管作用力;相对湿度低时,平衡复吸水含量的主要控制因素为金属离子的水合作用。     

有机膦与聚合物抑制剂对氟硅酸钠（钾）结垢性能的协同抑制作用

采用浊度法和静态抑垢法,研究了抑制剂2-膦酸基-1,2,4-三羧酸丁烷(PBTCA)与水解聚马来酸酐（HPMA）对氟硅酸钠（钾）结晶的影响。 运用经典结晶成核理论解释了抑制机理,利用扫描电子显微镜和X射线衍射技术表征了氟硅酸钠（钾）的晶体形貌和晶型。 结果表明,PBTCA与HPMA通过提高氟硅酸钠（钾）结晶时的表面自由能而抑制氟硅酸钠（钾）的析出。 PBTCA与HPMA之间存在明显的协同作用,PBTCA与HPMA共同作用使Na2SiF6的结晶表面自由能从108 mJ/m2升高至126 mJ/m2,溶液中Na+的阻垢率从6.2%上升至70.3%;使K2SiF6的结晶表面自由能从199 mJ/m2升高至230 mJ/m2,溶液中K+的阻垢率从10.2%升高至45.3%。 PBTCA与HPMA的加入使氟硅酸钠（钾）的粒径变小,颗粒分散;空白溶液中晶体主要为NaKSiF6,PBTCA与HPMA混合体系中结晶产物主要为Na2SiF6和K2SiF6。     

莠灭净悬浮剂物理稳定性

通过颗粒平均粒径测定和形貌表征研究了分散剂种类和用量对莠灭净悬浮剂物理稳定性的影响。 结果表明,相同条件下,双子型分散剂马来松香聚氧丙烯-氧乙烯醚磺酸盐（SC-3）可以在农药颗粒表面形成双层吸附,产生双层屏蔽结构,有效阻隔了颗粒与水的接触,抑制了颗粒团聚和奥氏熟化引起的结晶长大。 其用量(质量分数)大于4.0%时,所制备的莠灭净悬浮剂热贮前后颗粒粒径及形貌基本不变,其结晶长大现象得到有效地抑制,体系物理稳定性较好。     

壳核结构增韧剂对热塑性共聚酯/聚乙烯辛烯弹性体共混体系增容与增韧的影响

研究了马来酸酐接枝的聚乙烯辛烯弹性体 /半结晶性塑料共混物 (TPEg)对热塑性共聚聚酯(PETG) /聚乙烯辛烯弹性体 (TPE)共混体系增容增韧作用的影响 .马来酸酐接枝物显著地改善了PETG与TPE之间的相容性 ,导致TPE分散相颗粒细化 ,并促使分散相颗粒面间距等于甚至小于实现脆韧转变所需的临界面间距 .在固定PETG基体含量为 85wt %的前提下 ,当TPEg在 15 %分散相中的含量由 2 0 %增加到30 %时 ,即TPEg在共混体系中的含量由 3 %增加到 4 5 %时 ,共混体系出现了由脆性到韧性的转变 ,冲击强度急剧升高     

Zeta电位法选择农药悬浮剂所需润湿分散剂

采用Zeta电位法对质量分数为20%的吡氟草胺悬浮剂所需润湿分散剂进行筛选,以激光粒度分布仪对实验体系的平均粒径(Dav)进行了验证。研究结果表明,除木质素磺酸钠以外,阴离子型润湿分散剂均可使体系的Zeta电位绝对值(│ζ│)达到40mV以上,体系较为稳定;阴离子型润湿分散剂NNO和MorwetD425复配后,相同使用量下体系的│ζ│较单一使用NNO和MorwetD425的大;当m(NNO):m(MorwetD425)=1:4,复配润湿分散剂的总质量分数为1%时,│ζ│达到最大值,颗粒平均粒径最小,热贮前后变化很小,体系达到最佳分散效果。因此,Zeta电位表征润湿分散剂在农药悬浮剂中的润湿分散性能与体系颗粒平均粒径的变化规律有良好的对应关系,故Zeta电位可作为表征润湿分散剂分散性能优劣的指标。     

酯化淀粉乳化剂制备的高效氯氟氰菊酯O/W乳液的稳定机制

通过测定辛烯基琥珀酸淀粉钠的用量、盐离子、pH值和温度等因素对油滴Zeta电位及表面吸附量的影响,分析了以酯化淀粉辛烯基琥珀酸淀粉钠为乳化剂制备的5％高效氯氟氰菊酯水乳剂的稳定机制.结果表明,辛烯基琥珀酸淀粉钠质量分数为7％时,Zeta电位达到最大值,油滴表面吸附量接近饱和;Na+、Mg2+和Al3+压缩油滴表面的双电层,降低Zeta电位,削弱静电排斥作用,增加辛烯基琥珀酸淀粉钠分子柔性,提高辛烯基琥珀酸淀粉钠表面吸附量,且随着Na+、Mg2、Al3+离子强度依次增大,压缩双电层能力依次增强,Zeta 电位降低和表面吸附量增加程度依次增大;pH值影响辛烯基琥珀酸淀粉钠在水中的解离,在碱性范围内解离出较多羧酸根,静电排斥力较大,Zeta电位较高,但表面吸附量有所降低;温度升高,辛烯基琥珀酸淀粉钠在水溶液中溶解度增大,呈舒展状态,且辛烯基琥珀酸淀粉钠从油滴表面逃逸的趋势增加,油滴表面Zeta电位和表面吸附量均随着温度升高而降低,在低温区差别不大,温度越高二者变化越明显.辛烯基琥珀酸淀粉钠通过吸附于油滴表面为其提供较强的静电斥力和空间位阻作用而维持O/W乳液稳定.     

Studies of the Atrazine Aqueous Suspension Stability in the Presence of an Anionic Polymer—Influences of Polymer Molecular Weight and Solution pH

The influence of the molecular weight of sodium salt of styrene/methacrylic acid (SSMA) copolymers and solution pH value (range of 3–11) on the stability of the atrazine suspension was studied. SSMA with different molecular weights was synthesized by emulsion polymerization. Adsorption, zeta potential measurements, microscopy, and suspension stability measurements were carried out. The obtained results indicate that the adsorption of SSMA on the surfaces of atrazine particles decreases with the increase of the molecular weight, and the hydrogen bonding is the main adsorption force. The presence of SSMA improves the stability of the atrazine suspension. The stability of the atrazine suspension decreases with the increase of the molecular weight of SSMA. On the other hand, the stability of the atrazine suspension with SSMA increases firstly and then decreases with the increase in solution pH in the range of 3–11.     

碳纳米管的羟甲基化及其马来酸酐接枝研究

利用甲醛的亲电性能, 对化学气相沉积法(CVD)制备的多壁碳纳米管(MWCNTs)进行羟甲基化, 并在此基础上酯化接枝马来酸酐, 运用透射电子显微镜(TEM)、红外光谱和Zeta电位仪表征了改性后的MWCNTs的表面结构. TEM结果显示, 酯化后的MWCNTs明显增粗, 说明表面已附有物质. 红外结果表明, 羟甲基后的MWCNTs的表面有了羟基和亚甲基, 而马来酸酐酯化接枝后的MWCNTs有亚甲基和酯基官能团. 光学图像分析表明, 经甲醛处理后的MWCNTs在水溶液中的分散性明显提高, 而马来酸酐酯化接枝后的MWCNTs在二甲苯中的分散性明显增强. Zeta电位的测试结果表明, 甲醛处理过的MWCNTs颗粒在水中, 负电荷增多, 增强了其在悬浮液在溶液中的稳定性.     

Effect of Dispersant on the Colloidal Stability of Nano‐sized CuO Suspension

The stabilization of nano‐sized CuO suspensions was examined to look for the primary mechanism of dispersion. The dispersion stability of suspension was characterized by sedimentation tests, Zeta potential, granularity tests, and infrared spectroscopy (IR). Influence factors such as pH and the concentration of the dispersant on the colloidal stability of the suspension were investigated. The results showed that sodium polyacrylate was fit to stabilize the suspension of CuO nanoparticles through electrosteric repulsion. Also, smaller viscosity and better dispersion effects were achieved when sodium polyacrylate mass fraction was 0.4%～0.8% (based on the powder), pH was 10.     

Interaction of hydroxyapatite with sodium chondroitin sulfate and calcium chondroitin sulfate in an aqueous phase

The suspension pH at a given concentration of hydroxyapatite (HAP) decreased with the concentration of calcium chondroitin-6-sulfate (CaChs), whereas it increased with the concentration of sodium chondroitin-6-sulfate (Na2Chs). The former effect is due to the increase in the concentration of H+ by ion exchange between H+ on the surface of HAP and Ca2+ of CaChs, and the latter is due to the protonation of phosphate ion (Pi) released from the surface of HAP. The absorbed amount of chondroitin-6-sulfate anion (Chs) by HAP was higher with CaChs than with Na2Chs over the concentration range examined. The equilibrium concentration of Pi decreased with increasing concentration of added CaChs because the concentration of free Ca2+, which dissociates from CaChs, regulates the free concentration of Pi through the restriction of the solubility product of HAP (Ksp). In contrast, that in the presence of Na2Chs increased with increasing concentration of added Na2Chs owing to the anion exchange between Chs and Pi of the HAP surface. The total concentration of Ca2+, which was released from HAP into the solution phase, increased after passing through a minimum with increasing concentration of added Na2Chs. That is, the concentration of Ca2+ free from Chs decreased with an increase in the concentration of released Pi owing to the restriction of the solubility product, whereas that of Ca2+ bound by Chs increased with increasing concentration of added Na2Chs through the ion exchange of Na+ with Ca2+. It was confirmed by the dialysis method that the value of Ksp was almost constant around 10, although HAP dissolves incongruently in the presence of Na2Chs.     

Characterization of concentrated colloidal ceramics suspension: a new approach

The dispersion behavior of a concentrated ceramic suspension (Al(2)O(3)) has been investigated in terms of capillary suction time (CST) with varying solids concentration both in the absence as well as in the presence of dispersant (APC). The CST value is found to be the lowest at the pH(iep) whereas it increases as the pH is changed either to the acid side or alkaline side due to the repulsive forces acting among the neighboring particles keeping them in more dispersed state. It has been further observed that the CST value increases with increasing concentration of solids in the suspension. The dispersability of the suspension has been quantified in terms of dispersion ratio (DR). The higher the dispersion ratio of a particular system above unity, the better is the dispersability and vice versa. Further, quantification of dispersion stability by the CST technique is found to be useful and practical for optimization of different parameters concerning suspension stability. A correlation is found among the CST, zeta potential, colloidal stability, and maximum solids loading. It has been finally concluded that the CST method could be potentially employed as a quantitative and diagnostic technique for characterizing concentrated ceramic suspension.     

Preparation and characterization of Fe_3O_4/Au composite particles

Colloid gold with different sizes has been widely used in immunoassay and nucleic acid detection mainly because of their properties for immobilization of biomolecules, such as antibodies and oligonucleo-tides, through chemical reactions via active group SH on the biomolecules. Magnetic particles modified with various chemical groups on their surface can not only exhibit good magnetic responsiveness to an external magnetic field but also immobilize biomolecules through these chemical groups. As…