Strategies for evaluating thermodynamic properties of lattice mixtures of differently-sized particles and chain molecules: Application to partitioning data involving alkanes
Cd. Eads, Strategies for evaluating thermodynamic properties of lattice mixtures of differently-sized particles and chain molecules: Application to partitioning data involving alkanes, J PHYS CH B, 103(28), 1999, pp. 5869-5880
Simple approximate strategies for treating thermodynamic properties of latt
ice mixtures of differently sized particles and chain molecules are describ
ed. Based on these strategies, expressions for chemical potentials and part
ition coefficients are derived. These expressions account in a simple way f
or effects of particle size and chain length. In the limit of long chains a
nd for single-cell solute molecules, the resulting expression for chemical
potential reduces to the Flory-Huggins expression. However, for shorter cha
ins such as alkanes and for large globular solutes, the predicted contribut
ion of chain entropy to the chemical potential differs from the Flory-Huggi
ns treatment. The results are used to interpret published partitioning data
on xenon in alkanes as a function of chain length and temperature and to i
nterpret published partitioning data on pure alkanes and water. On the basi
s of these latter results, a contact free energy for the hydrophobic effect
of 29 cal A(-2) mol(-1) is determined. The first strategy for handling dis
parate molecular sizes gives expressions for the numbers of contacts betwee
n differently sized globular particles by introducing weighting factors for
particle numbers based on the number of contacts each particle can make wi
th particles of the other type. The second strategy addresses the entropy o
f mixtures of differently sized globular particles by using a parameter in
the partition function that gives the probability that a lattice with a giv
en population of large globular particles can accept another large globular
particle inserted at random. The third strategy evaluates chain configurat
ion entropy by calculating the number of configurations available to a mixt
ure of chain and globular particles without regard for intersegment chain c
onnectivity, followed by correction for the fraction of configurations that
are consistent with proper chain covalent bonding.