Publication: Gel formation in natural rubber latex: 2. Effect of magnesium ion
Issued Date
2003-01-01
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ISSN
00359475
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2-s2.0-10644260603
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Mahidol University
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SCOPUS
Bibliographic Citation
Rubber Chemistry and Technology. Vol.76, No.5 (2003), 1185-1193
Suggested Citation
L. Tarachiwin, J. T. Sakdapipanich, Y. Tanaka Gel formation in natural rubber latex: 2. Effect of magnesium ion. Rubber Chemistry and Technology. Vol.76, No.5 (2003), 1185-1193. doi:10.5254/1.3547796 Retrieved from: https://repository.li.mahidol.ac.th/handle/20.500.14594/20959
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Title
Gel formation in natural rubber latex: 2. Effect of magnesium ion
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Abstract
The effect of Mg2+ions on the gel formation in fresh and commercial high ammonia natural rubber latices (FL-latex and commercial HA-latex) was analyzed from the gel content and Mg2+content after treatment with (NH4)2SO4. The gel content of rubber from commercial HA-latex decreased significantly after (NH4)2SO4treatment comparable to that of FL-latex. Long-storage commercial HA-latex containing 50% gel fraction showed no decrease in Mg2+content after (NH4)2SO4treatment. This gel fraction was not solubilized in toluene by the treatment of a proteolytic enzyme in latex or ethanol/toluene mixed solvent extraction of rubber. The Mg2+content of rubber in long-storage commercial HA-latex, 0.005% (w/w rubber), decreased after treatment with (NH4)2SO4, while the same treatment showed little change on FL-latex, 0.035%. The toluene soluble fraction of these latices showed a decrease in the Mnvalue with an increase in the (NH4)2SO4concentration. The gel content of FL- and HA-lattices increased with an increasing storage period in the presence and absence of (NH4)2SO4. The initial rate of increase in the gel content was slow in the case of FL-latex. These findings indicate that the gel fraction in HA-latex is partly formed by ionic crosslinks caused by Mg2+ions. Whereas, the gel phase in long-storage commercial HA-latex is presumed to be a hard gel predominantly formed by covalent bonding.