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• dispersivity, Dy) is modeled at 0 33 times Dx, dispersion in the vertical direction (vertical dispersivity, D7) is <br /> modeled at 0 05 times Dx(Connor, et al, 1995) <br /> So tion <br /> Contaminants partition between the dqueous phase and the soil matrix Adsorption onto the soil surface <br /> significantly retards rnigration but does not permanently remove BTEX which may desorb later Carbon is the <br /> most effective sorption material in soils, and although clay minerals and amorphous minerals such as iron <br /> hydroxides also have some influence, only sorption to carbon in soil is included in most contaminant fate and <br /> transport computer models <br /> i <br /> Sorption is controlled by the organic carbon content of soil (fce), the chemical specific organic carbon partition <br /> coefficient(Koc), the soil bulk density(ps), and the water content of the soil as measured by the porosity(0s) Koc <br /> is a measure of the affinity of a given chemical to sorb from water onto solid organic material(Table 1) Once the <br /> porosity, bulk density, Koc, and foe have been established, the retardation factor(R) for the site can be calculated <br /> as follows <br /> R=(l +ks* ps/�s) where ks =fce *Koc <br /> The retardation factor is used in transport models (discussed below)as a measure of the degree to which the rate of <br /> plume migration is reduced by sorption processes <br /> Hydrolysis etc <br /> Other chemical reactions such as hydrolysis may reduce contaminant mass without microbial mediation <br /> Hydrolysis occurs when an organic molecule reacts with water or a component ion of water Unlike <br /> biodegradation, hydrolysis is not catalyzed by microorganisms Hydrolysis has not been observed to reduce BTEX <br /> concentrations,but is significant for halogenated volatile organics(solvents, etc) <br /> • Monitoring Groundwater For Natural Attenuation <br /> Assessment and monitoring of natural attenuation should be performed to confirm that intrinsic bioremediation <br /> and other forms of natural attenuation are occurring in the subsurface and are sufficient to limit plume migration <br /> by achieving an equilibrium between hydraulic transport (advection) and removal/degradation/reduction of mobile <br /> contaminants To confirm natural attenuation, it needs to be demonstrated that intrinsic factors are limiting <br /> migration,and that they will continue to do so until the plume has degraded to acceptable levels <br /> Natural attenuation can be evaluated by monitoring specific indicator parameters over a given period of time As <br /> further confirmation, simple fate and transport models can be applied to the site using the site-specific information <br /> obtained Several lines of evidence will generally need to be combined to provide a convincing case of natural <br /> attenuation First, it is necessary to establish that the plume is stable or being reduced in terms of size and <br /> concentrations, by review of historical data, possibly including statistical analysis At least one year of monitoring <br /> data utilizing an adequate distribution of wells should be sufficient For all chemical parameters, background <br /> concentrations need to be established by sampling one or more clean wells In addition to plume concentrations, <br /> Rifat et al , (1995), recommends, at a minimum, monitoring the following parameters <br /> • Microbial enumeration{total heterotrophic bacteria(plate count), <br /> and total hydrocarbon using bacteria(ASTM method G-2)] <br /> • Temperature(field measurement) <br /> • pH(field measurement) <br /> • Dissolved Oxygen(field measurement or EPA Method 360 1) <br /> If DO is depleted relative to background concentrations, additional monitoring for anaerobic processes may be <br /> considered and should include the following <br /> • Eh(field measurement) <br /> Sulfate(EPA method 300 or 375 4) <br /> • Nitrate/mtnte(EPA method 300, 353 1 or 353 2) <br /> CLEARWATER GRoup(NATURAL ATTENUATION) 2 revised October 3,2002 <br />