Many organic contaminants, including petroleum products, such as gasoline, have low aqueous solubilities and migrate through the subsurface as a separated phase called NAPLs (non aqueous liquid phases). In its flow path into the porous media the NAPLs let behind disconnected segments of organic liquids entrapped as ganglia or lenses that form the residual phase of the contaminant. The presence of the residual contaminant has been reported as one of the most difficulties in the development of an appropriate cleanup strategy as the residual phase represents a long and continuum source of contamination of soils and groundwater, specially by its dissolution into the water.In this thesis the effect of ethanol on dissolution of residual gasoline was studied, aiming at a better understanding of a scenario of groundwater contamination involving gasoline and ethanol, since 20 percent of ethanol has been added to the Brazilian gasoline in the last 20 years and also ethanol has been used as fuel in Brazil in these years. The use of oxygenated additives into the gasoline, such as alcohols, has the advantage of improving engine performance and reducing the air impact pollution by CO2 and its use has increasing in many countries.Equilibrium batch tests and column experiments were carried out to investigate the effect of ethanol on solubility of gasoline constituents and on the mass transfer coefficient from gasoline to aqueous phase. The results of the column experiments were interpreted with a dissolution numerical model proposed by Frind et al.(1997), modified in this thesis to include the cosolvent effects of the ethanol on the solubility of gasoline constituents.In terms of soil and groundwater contamination related to gasoline spills, chemicals like benzene, toluene, ethylbenzene and xylenes (BTEX group) have acute toxicity or carcinogenicity, are the most water- soluble and mobile gasoline components, receiving the greatest concern. In this work, an enormous enhancement of gasoline constituents solubility due to ethanol was observed, and it was also noticed that the mass transfer coefficient diminished due to ethanol. The highest increase in solubility were for the less water soluble components. Therefore, gasoline components, other than BTEX, are expected in significant concentrations, in a scenario of contamination involving ethanol and therefore more concern about this potential threat should be addressed.