Changes in P, MBAS, NH, NO3, NO2, Cl, pH, and Eh from septic effluent disposal were monitored in shallow ground waters between septic effluent disposal fields and an agricultural tile drainage system in an area composed of Typic and Aeric Ochraquults. As effluent moved through the soil system toward the agricultural tile, P and MBAS decreased logarithmically with distance. As much as 87% of the observed variation could be attributed to distance for both P and MBAS. Phosphorus and MBAS in ground waters intercepted by the tile drainage system at two of the sites had been reduced to acceptable levels. At location 1 (Typic Ochraquult), P and MBAS moved further (12 m) than might be predicted and were present in ground waters intercepted by the agricultural tile. These concentrations of P and MBAS in waters intercepted by the tile at location 1 resulted from rapid movement of effluent via saturated flow through the larger soil pores and from an inadequate soil volume for effluent purification. The concentrations of inorganic nitrogenous components in relation to the disposal area were similar at all three locations. The NH4-N concentration was highest adjacent to the drainfield (20-30 μg/ml) and decreased logarithmically with distance. A maxium of 83% of the observed decrease in NH4 could be attributed to distance. The NO3 concentration increased to a maximum at approximately 5 m and then decreased with increased distance. This was substantiated by the NO3/Cl ratios which indicated that NH4 was nitrified and the NO3 produced was subsequently denitrified to a large degree. The NO3 accumulation was seasonal with the highest concentrations present during periods of rising water tables.; Changes in P, MBAS, NH//4, NO//3, NO//2, Cl, pH, and Eh from septic effluent disposal were monitored in shallow ground waters between septic effluent disposal fields and an agricultural tile drainage system in an area composed of Typic and Aeric Ocraquults. As effluent moved through the soil system toward the agricultural tile, P and MBAS decreased logarithmically with distance. Phosphorus and MBAS in ground waters intercepted by the tile drainage system at two of the sites had been reduced to acceptable levels. The concentrations of inorganic nitrogeneous components in relation to the disposal area were similar at all three locations. The NH//4-N concentration was highest adjacent to the drainfield (20-30 mu g/ml) and decreased logarithmically with distance. The NO//3 concentration increased to a maximum at approximately 5 m and then decreased with increased distance. The NO//3 accumulation was seasonal with the highest concentrations present during periods of rising water tables.
