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INFORMATION SHEET ORDER NO, R5-2008-0149 3 <br /> INSITU GROUNDWATER REMEDIATION AT SITES WITH VOLATILE ORGANIC F^ >- <br /> COMPOUNDS, NITROGEN COMPOUNDS, PERCHLORATE, PESTICIDES, <br /> SEMI-VOLATILE COMPOUNDS AND/OR PETROLEUM HYDROCARBONS <br /> effectively reduce cis-1 ,2-DCE and vinyl chloride is an option to correct the <br /> problem. <br /> Hydrogen has a lead role as a direct electron donor in the anaerobic <br /> dechlorination of chlorinated aromatic hydrocarbons. Hydrogen is generated by <br /> fermentation of non-chlorinated organic substrates, including naturally occurring <br /> organic carbon, accidental releases of anthropogenic carbon (fuel), or introduced <br /> substrates such as carbohydrates (sugars) , alcohols, and low-molecular-weight <br /> fatty acids (lactates, acetates, etc.). As hydrogen is produced by fermentative <br /> organisms, it is rapidly consumed by other bacteria, including denitrifiers, iron- <br /> reducers, sulfate-reducers, methanogens, and dechlorinating microorganisms. <br /> For anaerobic reductive dechlorination to occur, dechlorinators must successfully <br /> compete against other microorganisms that also utilize hydrogen (ITRC, 2007) . <br /> Generally, there are not sufficient numbers of bacteria naturally present to <br /> conduct an effective anaerobic dehalogenation process. To increase the <br /> concentration of bacteria biostimulation is implemented by injecting a carbon <br /> source or substate into the groundwater. For the degradation of chlorinated <br /> ethenes, the injected carbon source provides for cell growth and ferments to <br /> produce products like hydrogen , providing an electron donor for the reductive <br /> dechlorination process. By adding electron donors, methanogenic and/or sulfate- <br /> reducing conditions can be achieved at a site, which can be used to dechlorinate <br /> cis-1 ,2-DCE and vinyl chloride. Complete reductive dechlorination to ethene <br /> without the accumulation of cis-1 ,2-13CE and vinyl chloride is most likely to occur <br /> under these strongly-reducing conditions (ITRC, 2007) . <br /> IB dssUmul—a ion also may include infectin—g—lImlfing nut Ients, such as phosphorus <br /> or nitrogen . The advantage of biostimulation is that native populations present in <br /> the subsurface are already acclimated to the site, so enhancements such as the <br /> addition of nutrients will increase their biodegradation capacity. The <br /> disadvantage is that subsurface geology of a site may interfere with the <br /> introduction of nutrients, including the formation of preferential flow patterns due <br /> to fractures and impermeable lithology affecting the distribution of additives. <br /> Important subsurface characteristics to consider for biostimulation include <br /> velocity of the groundwater, and hydraulic conductivity of the soil. Pilot studies <br /> are usually conducted to provide additional site-specific information before full- <br /> scale implementation (ITRC, 2007). <br /> Substrates added to promote reductive dechlorination come in many forms and <br /> may be soluble, low viscosity, high viscosity or solid. Soluble substrates, such as <br /> sugars, citric acid and lactic acid, may be applied in an aqueous phase offering <br /> uniform distribution throughout the aquifer. These dissolved substrates travel <br /> with advective groundwater flow and are typically applied continuously or <br />