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r7Astrated in thephotographic Plates, rust mottling was observed within the underlying sandyta in the exploratory boring. Rust mottling occurs when anaerobic bacteria decompose <br /> gc matter and use iron (Fe") in their metabolic processes. This oxidation of iron creates rust. <br /> When these two conditions are present - organic matter and an anaerobic environment, <br /> denitrification (the conversion of nitrate to gaseous products and the primary means by which <br /> nitrate concentrations are reduced) is promoted. Although mottling may be attributed to geologic <br /> processes, it is most probably due to seasonal soil saturation whereby percolating soil water <br /> encounters slower permeability strata and accumulates. This accumulation phenomenon is observed <br /> when water percolating through a fine-grained soil encounters a coarser-grained soil, as observed in <br /> photographic Plate D. <br /> The drilling procedures also included the Standard Penetration Test(SPT). The Log of Boring for <br /> the deep perc test boring illustrate the number of blows needed to advance the split spoon sampler, <br /> one foot per ASTM D-1586. SPT results for this boring are illustrated below in Table 1. The <br /> correlations between the soil conditions and the SPT are dependent upon the soil type encountered <br /> and are different for fine-grained vs. coarse-grained soils. Test results reveal the underlying soils to <br /> be relatively dense. <br /> This density may have some influence on saturated vs. unsaturated flow conditions, particularly in <br /> the thick sand stratum (8.0 ft to 20 ft) that was observed. It is known that a thick sand stratum also <br /> exists at the opposite end of Clements. Although this sand stratum is dense, significant permeability <br /> exists, which contributes to saturated flow. However, this stratum is thick enough that saturated <br /> flow conditions may not develop due to the distance percolating water or effluent must travel. <br /> The six soil samples retrieved from the 25 ft boring were analytically tested. These samples were <br /> submitted to A& L Western Agricultural Laboratories in Modesto under the attached Chain of <br /> Custody. The SOIL ANALYSIS REPORT (Appendix 4) illustrates the important parameters <br /> associated with nitrate loading potential. As expected, the test results indicate relatively low <br /> Cation Exchange Capacity. Jhc or anic matter is of medium c ncentration in tic s �Ge so <br /> which is favorable for denitrification. The nitrate-nitrogen oils_ <br /> at 14 ppm, with an estimated nitrogen release ENR of 94 lbs/Acre. <br /> An important soil parameter in nitrate loading assessment, is the cation exchange capacity(CEC). <br /> Clay soils have a higher CEC than other soil types. Cations (positively charged ions) such as NH4" <br /> Kt, Ca" and Mg" are removed from solution by the clay soil fraction because the clay particles <br /> possess a negative charge. In cation exchange, a positively charged ion within the clay complex is <br /> replaced and released by another type of ion. Ionic exchange, through its effects on nutrient <br /> availability and acidity, has an effect on biological and chemical transformations. The significance <br /> of cation exchange becomes important when the chemistry of septic effluent is analyzed. Nitrogen <br /> in septic tank effluent consists of approximately 75%N in the ammonium ion (NH4') form. and <br /> 25%N in the organic form. If the ammonium ion is bound and eventually utilized, nitrification <br /> cannot occur. Nitrification is an aerobic reaction accomplished predominately by autotrophic <br /> bacteria which convert ammonium (NH4*) to nitrite (NO,) and subsequently to nitrate (NOO. <br /> Page -4- <br /> Chesney Consulting <br />