采用高速冷冻离心处理天然鲜胶乳制备离心胶乳,通过改变胶乳中酸碱度和电解质,结合激光多普勒技术、扫描电子显微镜以及电感耦合等离子体质谱仪等仪器对处理前后的胶乳进行电动特性、形貌及金属离子含量分析.结果表明pH值的降低能使胶乳电泳迁移率的正负发生反转.增加电解质浓度,天然鲜胶乳负的电泳迁移率随之降低,相同浓度条件下阴离子电解质对天然胶乳电泳迁移率与电导率的影响顺序为NaCl>NaBr>NaNO3>SDS(十二烷基硫酸钠).金属阳离子压缩天然胶乳双电层效率由大到小依次为Al3+>Fe3+?Fe2+>Cu2+?Mn2+>Co2+>Ca2+>Na+.高价金属阳离子如铜离子、铁离子与铝离子能使胶乳带电性质反转,酸碱度及形貌分析表明这些电解质会改变胶乳pH值环境,使胶乳发生团聚甚至破乳现象.
Fresh natural rubber latex was used to prepare centrifuged latex through high-speed refrigerated cen-trifuge.Combining laser Doppler electrophoresis,scanning electron microscope and inductively coupled plasma mass spectrometer and other instruments,the writer analyzed the electric properties,morphology and metal ion content of freshed and centrifuged natural rubber latex by changing the pH and electrolyte.The results showed that as the pH was lowered,the plus or minus of latex electrophoretic mobility was inverted.With the increasing electrolyte concen-tration,the negative electrophoretic mobility of natural fresh latex decreased accordingly.Under the same condition of concentration,the order of anions′effects on natural rubber latex′s electrophoretic mobility and conductivity was NaCl>NaBr>NaNO3>SDS (sodium dodecyl sulfate sodium).The descending order of compressing the electric double layer efficiency of metal cation was Al3+>Fe3+?Fe2+>Cu2+?Mn2+>Co2+>Ca2+>Na+.There was a special si-tuation that high metal cations such as copper ions,iron ions and aluminum ions could invert the latex′s charged na-ture.pH and electrolyte and the Morphology analysis showed that these electrolytes change latex′s pH environment, leading to latex agglomeration,even emulsion breaking.
参考文献
| [1] | Ho CC.;Muramatsu N.;Ohshima H.;Kondo T..SURFACE STRUCTURE OF NATURAL RUBBER LATEX PARTICLES FROM ELECTROPHORETIC MOBILITY DATA[J].Journal of Colloid and Interface Science,19962(2):442-445. |
| [2] | Christophe N. Rochette;Je?ro?me J. Crassous;Markus Drechsler;Fabien Gaboriaud;Marie Eloy;Beno?t de Gaudemaris;Je?ro?me F. L. Duval.Shell Structure of Natural Rubber Particles: Evidence of Chemical Stratification by Electrokinetics and Cryo-TEM[J].Langmuir: The ACS Journal of Surfaces and Colloids,201347(47):14655-14665. |
| [3] | Jerome F.L.Duval;Hiroyuki Ohshima.Electrophoresis of Diffuse Soft Particles[J].Langmuir: The ACS Journal of Surfaces and Colloids,20068(8):3533-3546. |
| [4] | Adamczyk, Z.;Nattich, M.;Wasilewska, M.;Zaucha, M..Colloid particle and protein deposition - Electrokinetic studies[J].Advances in colloid and interface science,20111/2(1/2):3-28. |
| [5] | Jerome F.L. Duval;Fabien Gaboriaud.Progress in electrohydrodynamics of soft microbial particle interphases[J].Current opinion in colloid & interface science,20103(3):184-195. |
| [6] | Wang, Long-Fei;Habibul, Nuzahat;He, Dong-Qin;Li, Wen-Wei;Zhang, Xing;Jiang, Hong;Yu, Han-Qing.Copper release from copper nanoparticles in the presence of natural organic matter[J].Water research: A journal of the international water association,2015Jan.1(Jan.1):12-23. |
| [7] | Ghosh S;Mashayekhi H;Pan B;Bhowmik P;Xing BS.Colloidal Behavior of Aluminum Oxide Nanoparticles As Affected by pH and Natural Organic Matter[J].Langmuir: The ACS Journal of Surfaces and Colloids,200821(21):12385-12391. |
| [8] | Andrew L. Rose;T. David Waite.Kinetic model for Fe(II) oxidation in seawater in the absence and presence of natural organic matter[J].Environmental Science & Technology: ES&T,20023(3):433-444. |
- 下载量()
- 访问量()
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%