n-alkanoate + n-alkane mixtures: folding of hydrocarbon chains of n-alkanoates

Abstract

The mixtures CH3(CH2)u-1COO(CH2)v-1CH3 (u=5-13, v=1,2; u=1,2,3, v=3,4; u=1,2,4, v=5) + n-alkane have been investigated using experimental data (viscosity and excess molar functions: enthalpy, HmE, volume, VmE, isobaric heat capacity, and isochoric internal energy, UVmE) and models (Flory, Grunberg-Nissan, Bloomfield-Dewan). They are characterized by weak orientational effects. Large structural effects are found in some systems, like those containing pentane. Some considerations from standard enthalpies of vaporization, cohesive energy densities and VmE of heptane mixtures reveal the existence of structural changes in longer n-alkanoates, which lead to stronger interactions between them. The observed decrease of HmE for systems with a given n-alkane seems to be more related to the steric hindrance of the COO group than to interactional effects. The UVmE(n) function (n= number of C atoms in the n-alkane) shows a minimum for systems with esters with (u≥4, v=1); (u≥7, v=2), or (u≥ 1, v=4,5). A similar dependence was found for n-alkane mixtures involving cyclic molecules (cyclohexane, benzene). This result suggests that certain n-alkanoates, in an alkane medium, can form quasi-cyclic structures. Viscosities are well described by means of free volume effects only. For systems with butyl ethanoate or methyl decanoate, the variation of η (n) (deviation of dynamic viscosity) is consistent with that of UVmE(n), which supports the existence of cyclic structures in these esters. The Flory model provides poor results on HmE for systems with large structural effects. Results improve when the model is applied to UVmE(n) data.