Abstract
Continuous use of recycled water (treated wastewater) over a long period of time may lead to the accumulation of salt in the root zone of the soil. This is due to the relatively higher levels of salt contained in the recycled water compared to a town water supply. The increase in salt concentration in the soil can adversely influence the amount of water a plant can uptake from the soil due to the osmotic effect. Despite significant benefits, recycled water may deteriorate soil health in terms of increased salinity and sodicity. Although several studies in the past have highlighted the increase of soil salinity due to recycled water irrigation, the phenomenon depends on the variability of soil characteristics. In this study, the impact of using three different types of irrigation water (with electrical conductivity 0.2, 0.8, and 2.0 dS/m) on the mechanism of salt accumulation in the soil was investigated. To contribute to the addition of the existing knowledge of soil salinisation, soil from two paddocks (i.e., D33 and Yarramundi) in Western Sydney, Australia were analysed, and relationships among parameters associated with salt accumulation were evaluated using the results from continuous column studies. Results show that if the irrigation is conducted with high saline water, there is a possibility for salinisation of soil to occur. To prevent this from occurring, one of the solutions could be to use a normal town water supply for irrigation at some intervals. This will allow for the leaching of excess salt accumulated in the soil to deeper layers.
Highlights
Recycling is one feasible approach for achieving sustainable wastewater management
More accumulation occurred in saline water (SW) irrigated columns than in recycled water (RW) and tap water (TW) irrigated columns
A column study integrating real-time salinity monitoring in the soil profile was done to determine the effect of irrigation water salinity on salt build-up in the soil of two paddocks in Hawkesbury, NSW, Australia (D33 and Yarramundi)
Summary
Recycling is one feasible approach for achieving sustainable wastewater management. The benefits of recycled water are numerous, including alleviating pressure on existing fresh water supplies, minimising effluent discharge to surface or coastal waters, and providing a steady volume of water in comparison to rainfall-dependent sources [1]. The advancement of technology and the economic viability of wastewater treatment have enabled wastewater recycling and expanded the most sustainable use of recycled water. One such reuse option is to apply recovered urban water to open fields, such as paddocks and sporting ovals. The application of supplied recycled water included: 23% for the replacement of drinking water in residential, commercial, and industrial uses; 36.2% for environmental use, such as improving the water quality of rivers; 36.2% for use in recycling water systems in wastewater treatment plants; and 4.25% for irrigation of parks, sporting fields, and agricultural lands. Using urban effluent or recycled water to irrigate urban open fields in lieu of fresh water is an important goal for local and national governments seeking to accomplish sustainable water management
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