New Conceptual Model for Soil Treatment Units: Formation of Multiple Hydraulic Zones during Unsaturated Wastewater Infiltration

Onsite wastewater treatment systems are commonly used in the United States to reclaim domestic wastewater. A distinct biomat forms at the infiltrative surface, causing resistance to flow and decreasing soil moisture below the biomat. To simulate these conditions, previous modeling studies have used...

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Bibliographic Details
Published in:Journal of environmental quality 2013-07, Vol.42 (4), p.1196-1204
Main Authors: Geza, Mengistu, Lowe, Kathryn S., Huntzinger, Deborah N., McCray, John E.
Format: Article
Language:English
Subjects:
Conductivity
Domestic wastewater
Effluents
Flow resistance
Fluid flow
Hydraulics
Influence
Load distribution
Mathematical models
Microorganisms
Moisture content
Organic chemicals
Ponding
Saturation
Sensitivity analysis
Soil
Soil (material)
Soil moisture
Soil treatment
Viruses
Waste Disposal, Fluid
Waste Water
Wastewater treatment
Water Movements
Water Purification
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Summary:Onsite wastewater treatment systems are commonly used in the United States to reclaim domestic wastewater. A distinct biomat forms at the infiltrative surface, causing resistance to flow and decreasing soil moisture below the biomat. To simulate these conditions, previous modeling studies have used a two‐layer approach: a thin biomat layer (1–5 cm thick) and the native soil layer below the biomat. However, the effect of wastewater application extends below the biomat layer. We used numerical modeling supported by experimental data to justify a new conceptual model that includes an intermediate zone (IZ) below the biomat. The conceptual model was set up using Hydrus 2D and calibrated against soil moisture and water flux measurements. The estimated hydraulic conductivity value for the IZ was between biomat and the native soil. The IZ has important implications for wastewater treatment. When the IZ was not considered, a loading rate of 5 cm d−1 resulted in an 8.5‐cm ponding. With the IZ, the same loading rate resulted in a 9.5‐cm ponding. Without the IZ, up to 3.1 cm d−1 of wastewater could be applied without ponding; with the IZ, only up to 2.8 cm d−1 could be applied without ponding. The IZ also plays a significant role in soil moisture distribution. Without the IZ, near‐saturation conditions were observed only within the biomat, whereas near‐saturation conditions extended below the biomat with the IZ. Accurate prediction of ponding is important to prevent surfacing of wastewater. The degree of water and air saturation influences pollutant treatment efficiency through residence time, volatility, and biochemical reactions.
ISSN:0047-2425
1537-2537
DOI:10.2134/jeq2012.0441