AI Article Synopsis
- The odd-even effect in the physical properties of organic molecules is noted, impacting the emulsification ability of single-chain surfactants based on the number of carbons in their aliphatic chains.
- The study shows that single-chain surfactants can effectively emulsify disodium cromoglycate (5'DSCG) in a water-in-oil-in-water system, with odd-numbered carbon chains being more effective than even-numbered ones.
- This phenomenon suggests that the arrangement of surfactant tails in a highly ordered structure may influence their emulsification capabilities, pointing to potential new applications in the development of organic soft materials.
Article Abstract
The physical properties of many organic molecules often oscillate when the number of carbons in their aliphatic chains changes from odd to even. This odd-even effect for single-chain surfactants in solution is rarely observed. Here, we report the ability of single-chain surfactants to emulsify a class of non-amphiphilic organic salts, disodium cromoglycate (5'DSCG) oscillates as a function of the odd or even number of the aliphatic carbons. This system provides a water-in-oil-in-water emulsion, in which aqueous droplets of 5'DSCG in liquid crystal phases are coated with single-chain surfactants in a bulk carrying aqueous solution. For both surfactants of [Formula: see text] and CH3(CH2)nCOO(-)Na(+), the ability to emulsify 5'DSCG molecules in water is stronger for surfactants with an odd number of sp(3)-hybridized carbon atoms in the aliphatic chains than those with an even number. This observed odd-even effect is consistent with the notion that conventional micelles possess a core of randomly arranged surfactant hydrocarbon tails. However, this water-in-oil-in-water resembles a vesicle system in which the surfactants assemble in a highly ordered structure that separates two aqueous systems. These new self-assembled phases have potential application in the formulation and design of new organic soft materials.
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| http://dx.doi.org/10.1016/j.jcis.2013.08.044 | DOI Listing |
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