We have investigated the microscopic properties of a reverse micellar aggregate consisting of 102 calcium carbonate, 11 calcium (2-hexadecyl)benzenesulfonate, and 22 water molecules in nonpolar environments (CCl4, octane, and vacuum) using molecular dynamics simulations. The simulated aggregate is a model for the micellar species in detergent additives to automotive and diesel lubricants. From our simulations we conclude that the structure of the micelle is similar in both CCl4 and octane solvents, but the structure of the two solvents in the vicinity of the micelle is different. Both solvents are ordered by the micelle, but CCl4 to a larger extent. In solution, the aggregate is roughly spherical, with an average core diameter of 23 Angstrom, surfactant layer thickness of 9 Angstrom, and total diameter of approximately 41 Angstrom. The crystalline order of the initial core configuration is, for the most part, maintained throughout the solution simulations. Conformational distributions of the hexadecane chains in solution suggest that the behavior of the middle parts of the surfactant tails is similar to that in aqueous micelles, while the ends of the chains resemble liquid alkanes. The simulations reveal that approximately 25% of the micelle core surface is exposed to solution. The polar core, water molecules, and surfactant headgroups behave similarly in the vacuum and solution simulations, but the surfactant tails behave qualitatively differently in vacuum : in the absence of solvent the hydrocarbon tails collapse onto the surface of the core, producing a much more compact micelle.