Initially, the focus is on the development of a conceptual and predictive model based on the nature of contamination, the actual geological complexity of the subsurface, and the mass transport processes themselves, which is unquestionably oversimplified. Nevertheless, this approach results in an increased understanding of the equilibrium limits and the transport processes, which is most useful as a basis for further evaluation. Often, the assumption of uniform and homogeneous site conditions can enable the use of mathematical models that yield analytical, closed-form solutions that may be reliable within an order of magnitude. This is, in many cases, sufficient for further evaluations. Should more precise estimates be needed, the additional complexity, concerning both the contamination and the subsurface conditions, will typically dictate the need for the use of dynamic numerical models that require an extensive amount of data for reliable calibration and verification. Our objective is not to take the analysis to this level in this treatment, but rather, to focus on providing a good understanding of the contaminant migration pathways that can occur, the definition of pertinent equilibrium states and potential upper limits of contamination, and those steady-state mass transport analyses that can be used to generate predictive estimates most easily. The major focus is on the transport and behavior of organic compounds of low water solubility.

It is useful to think in terms of a hierarchy of evaluations concerning the movement of chemicals in the subsurface. Initially, one needs a good understanding of subsurface geology and the movement of water within the subsurface. This can be obtained through the performance of fairly fundamental hydrogeological investigations designed to map the subsurface geology in the vicinity of the chemical release. Typically, soil borings are performed to nee...