Abstract
Abstract. There has been increased salinization of fresh water over decades due to the use of road salt deicers, wastewater discharges, saltwater intrusion, human-accelerated weathering, and groundwater irrigation. Salinization can mobilize bioreactive elements (carbon, nitrogen, phosphorus, sulfur) chemically via ion exchange and/or biologically via influencing of microbial activity. However, the effects of salinization on coupled biogeochemical cycles are still not well understood. We investigated potential impacts of increased salinization on fluxes of bioreactive elements from stream ecosystems (sediments and riparian soils) to overlying stream water and evaluated the implications of percent urban land use on salinization effects. Two-day incubations of sediments and soils with stream and deionized water across three salt levels were conducted at eight routine monitoring stations across a land-use gradient at the Baltimore Ecosystem Study Long-Term Ecological Research (LTER) site in the Chesapeake Bay watershed. Results indicated (1) salinization typically increased sediment releases of labile dissolved organic carbon (DOC), dissolved inorganic carbon (DIC), total dissolved Kjeldahl nitrogen (TKN) (ammonium + ammonia + dissolved organic nitrogen), and sediment transformations of nitrate; (2) salinization generally decreased DOC aromaticity and fluxes of soluble reactive phosphorus from both sediments and soils; (3) the effects of increased salinization on sediment releases of DOC and TKN and DOC quality increased with percentage watershed urbanization. Biogeochemical responses to salinization varied between sediments and riparian soils in releases of DOC and DIC, and nitrate transformations. The differential responses of riparian soils and sediments to increased salinization were likely due to differences in organic matter sources and composition. Our results suggest that short-term increases in salinization can cause releases of significant amounts of labile organic carbon and nitrogen from stream substrates and organic transformations of nitrogen and phosphorus in urban watersheds. Given that salinization of fresh water will increase in the future due to human activities, significant impacts on carbon and nutrient mobilization and water quality should be anticipated.
Highlights
Concentrations of chloride ion (Cl−), sulfateS (SO24−-S) and dissolved organic carbon (DOC), and protein-like to humic-like fluorophore (P / H) ratios of DOC in stream water increased with watershed impervious surface cover (ISC) (r2 = 0.77–0.83, p < 0.05, n = 8)
Our results suggest that the effects of increased salinization on sediment releases of DOC, proteinlike fluorophore, total dissolved Kjeldahl nitrogen (TKN), and dissolved inorganic carbon (DIC) increased with ISC (Fig. 4; linear regressions, all p < 0.05)
As shown in this figure, releases of labile DOC and TKN from sediments can potentially increase during episodic stream salinization, due to “salting-in” effects of proteinaceous organic matter and NH+4 mobilization
Summary
Salt concentrations in freshwaters are rapidly increasing at a regional scale in the USA and worldwide (e.g., Nielsen et al, 2003; Kaushal et al, 2005, 2014a; Rengasamy, 2006; Findlay and Kelly, 2011; Steele and Aitkenhead-Peterson, 2011; Corsi et al, 2015). Most of the increased salinization can typically be attributed to road salt deicers and other industrial uses, wastewater discharges, groundwater irrigation, saltwater inundation caused by sea-level rise, and human-accelerated weathering (e.g., Findlay and Kelly, 2011; Aitkenhead-Peterson et al, 2009; Ardón et al, 2013; Kaushal et al, 2013). Kaushal: Salinization alters fluxes of bioreactive elements from stream ecosystems
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