Abstract
A greenhouse microcosm study investigated the impacts of recovered iron oxyhydroxide mine drainage residuals (MDRs) on phosphorus (P) and trace metal distributions at the sediment layer/water column interface in Grand Lake o’ the Cherokees, a large reservoir receiving waters impacted by both historic mining and current agricultural land uses. Each mesocosm included 5 kg of lake sediment and 20 L of on-site groundwater. Three treatments were examined in triplicate: control (C) with no additions, low MDR (LM) with 0.3 kg added MDR, and high MDR (HM) with 0.9 kg added MDR. In the first 10 days, aqueous soluble reactive phosphorous (SRP) concentrations decreased likely due to colonizing biomass uptake with no significant differences among the three treatments. LM and HM treatments showed delayed peaks in dissolved oxygen (DO) and lesser peaks in chlorophyll-a (Chl-a) concentrations compared to the C treatment, indicating MDR addition may suppress biomass growth. During days 11 to 138, the C treatment demonstrated increasing pH, decreasing ORP, and biomass decay resulting in significantly increased SRP concentrations. In LM and HM treatments, sufficient P sorption by the MDR maintained low SRP concentrations. Although the MDRs are derived from metal-rich mine waters, all aqueous concentrations were below both hardness-adjusted acute and chronic criteria, except for Pb with regard to the chronic criterion. Metal concentrations in sediments were below the Tri-State Mining District (TSMD)–specific Sediment Quality Guidelines (SQGs). MDR additions may serve as stable long-term P sinks to prevent P release from dead biomass, decrease internal P cycling rates, and mitigate eutrophication, with limited concern for trace metal release.Graphical
Highlights
Excess nutrient inputs into aquatic ecosystems have raised concerns about eutrophication and resulting harmful algal blooms (Sibrell et al 2009; Ho et al 2019)
The Premoval mechanism for Fe/Al Phosphorus-sorbing materials (PSMs) is ligand exchange reactions on sorption sites provided by amorphous Fe/ Al oxide flocs
Dobbie et al (2009) report on a follow-up study which involved two long-term field tests (a 3-year experiment at Leitholm in Scotland and a 9-month experiment at Windlestone in England) and concluded that mine drainage residuals (MDRs)-based treatment systems had considerable potential to remove P with a lifetime estimated to be ten times longer than other tested substrates, with no observed toxic metal releases. These results demonstrate potential utility, most MDR P-removal studies are based on treating wastewater with much higher levels than eutrophic lake waters
Summary
Excess nutrient inputs into aquatic ecosystems have raised concerns about eutrophication and resulting harmful algal blooms (Sibrell et al 2009; Ho et al 2019). Phosphorus (P), a common limiting nutrient in freshwater systems, often enters lakes and reservoirs via both external and internal loading sources (Perkins and Underwood 2001; Chen et al 2018). The Premoval mechanism for Fe/Al PSMs is ligand exchange reactions on sorption sites provided by amorphous Fe/ Al oxide flocs This mechanism is rapid, but P may be released upon changes in the oxidation-reduction profile (Penn et al 2007; Sibrell et al 2009; Chen et al 2015; Penn et al 2017; Qin et al 2018).
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