The purpose of this study is to investigate the retention mechanism. which is the key to the prediction of retention and to the systematical optimization for benzenes in reversed-phase liquid-solid chromatography. The retention data. capacity factors(k') of twelve benzenes was measured in the systems containing 75-100% of methanol and acetonitrile as organic modifiers. and PRP-l column. From the retention data, two extensive approaches are examined in order to elucidate the retention mechanism : 1) the comparison of the retention data of the solutes containing different substituents : 2) the relationship between the thermodynamic values and the retention data, i.e., van’t Hoff plots and enthalpy- entropy compensation phenomena. The retention behaviors of benzenes having different substituents. such as normal, iso. and tertiary alkyl groups. are well interpreted in both mobile phases by the liquid-solid adsorption phenomenon. which is closely related with displacement mechanism. The effect of temperature on retention is investigated by van' t Hoff plots in the temperature range of 35-55℃. The linearity(R>0.999) means that the retention of solutes is consistent in the above temperature range. From the observation of enthalpy-entropy compensation phenomenon. some conclusions interpreting the retention mechanism are drawn as follows : 1) the retention mechanism of solutes depends on the type of organic modifier in hydro-organic media ; 2) in methanol-water mobile phase. the retention mechanism of benzenes is consistent and identical in the range of 75-100% methanol-water ; 3) on the other hand. in the case of acetonitrile-water mobile phase, the retention mechanism depends on the acetonitrile composition. It means that the retention mechanism can not be explained only by a simple mechanism. Consequently. the retention of solutes is controlled by the displacement mechanism in methanol-water mobile phase. while the mixed mechanism. involving concurrent adsorption and partition phenomena. must be considered in acetonitrile-water mobile phase.