Effect of Added Perfume on the Stability of Discontinuous Cubic Phase

Abstract

In water-polyoxyethylene(n) alkyl(m) ether (C_mEO_n; C₁₂EO₂₅, C₁₆EO₂₅, C₁₆EO₃₀, C₁₆EO₄₀, C₁₈EO₂₀, C_18;1EO₅₀, C₂₂EO₃₀) systems and water-polyoxyethylene(n) cholesterol ether (ChEO₃₀) system, the effect of chemical structures of surfactants and added perfume compounds on the stability of discontinuous cubic (I₁) phase were investigated. When the hydrophobic chain length of surfactant is kept constant, the maximum temperature up to which the I₁ phase can exist increases with increasing HLB value or the EO-chain length of surfactant. On the other hand, the maximum temperature of I₁ phase increases with increasing the molecular size of surfactant at constant HLB value. Upon addition of hydrocarbon-type perfume, d -limonene (LN), the maximum temperature of I₁ phase is almost unchanged, whereas it decreases largely upon addition of amphiphilic polar oil, such as α-hexyl cinnamic aldehyde (HCA), β-ionone (IN), benzyl acetate (BA), linalool (LL), geraniol (GL), eugenol (EL), and cis -3-hexenol (HL), and is in order LN>HCA>IN>BA>LL>GL>EL>HL, which is the same as the HLB temperature in the water/C₁₂EO₈/perfume systems. In general, the maximum temperature of ChEO_n systems is higher than that of C_mEO_n systems, because even amphiphilic polar perfume compounds do not largely penetrate in the surfactant palisade layer in ChEO_n systems. The interaction between cholesterol groups may be very strong, and therefore, may prevent the penetration of oil in the palisade layer.