Affiliation:
1. Department of Engineering East Carolina University
2. Department of Geological Sciences East Carolina University
3. Department of Biological Systems Engineering Virginia Tech
Abstract
AbstractElevated concentrations of phosphorus (P) and other nutrients common in wastewater treatment plant (WWTP) effluent have been shown to contribute to the proliferation of harmful algal blooms, which may lead to fish kills related to aquatic hypoxia. Increased understanding of the negative effects associated with elevated P concentrations have prompted more strict regulation of WWTP effluent in recent years. The use of low‐cost and potentially regenerative adsorptive phosphate filters has the potential to decrease P concentrations in WWTP effluent released to natural waters. This research focuses on assessing the capacities of recycled concrete aggregate (RCA), expanded slate, and expanded clay to remove phosphate from P‐amended WWTP effluent. Results from a flow‐through column study indicate that RCA consistently removed an average of 97% of phosphate over 20 weeks of continuous flow at an 8‐hour hydraulic retention time (HRT). Expanded clay removed an average of 63% of introduced phosphate but decreased in removal capacity from 91 to 42% over the 20‐week duration. Sorption data from batch studies were fitted to Langmuir models and RCA was shown to have the highest maximum sorption capacity (6.16 mg P/g), followed by expanded clay (3.65 mg P/g). RCA and expanded clay are promising options for use in passive filters for further reduction of phosphate from WWTP effluent.
Funder
Division of Research, Economic Development and Engagement, East Carolina University
North Carolina Sea Grant, North Carolina State University