posted on 2000-10-21, 00:00authored byRavindra P. J. Ranatunga, Peter W. Carr
The goal of this study was to elucidate the roles played by
the stationary and mobile phases in retention in reversed-phase liquid chromatography (RPLC) in terms of their
individual enthalpic and entropic contribution to the
Gibbs free energy of retention. The experimental approach
involved measuring standard enthalpies of transfer of
alkylbenzenes from typical mobile phases used in RPLC
(methanol/water and acetonitrile/water mixtures), as well
as from n-hexadecane (a simple analogue of the stationary
phase) to the gas phase, using high-precision headspace
gas chromatography. By combining the measured enthalpies with independently measured free energies of transfer, the entropies of transfer were obtained. This allowed
us to examine more fully the contribution that each phase
makes to the overall retention. It was found that the
standard enthalpy of retention in RPLC (i.e., solute
transfer from the mobile phase to the stationary phase)
is favorable, due to the large and favorable stationary-phase contribution, which actually overcomes an unfavorable mobile-phase contribution to the enthalpy of
retention. Further, the net free energy of retention is
favorable due to the favorable enthalpic contribution to
retention, which arises from the net interactions in the
stationary phase. Entropic contributions to retention
are not controlling. Therefore, to a great extent, retention is due to enthalpically dominated lipophilic interaction of nonpolar solutes with the stationary phase and
not from solvophobic processes in the mobile phase.
Further, our enthalpy data support a “partition-like”
mechanism of retention rather than an “adsorption-like”
mechanism. These results indicate that the stationary
phase plays a very significant role in the overall retention
process. Our conclusions are in direct contrast to the
solvophobic model that has been used extensively to
interpret retention in RPLC.