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Accumulation and Transport of Nutrient and Pollutant Elements in Riparian Soils, Sediments, and River Waters Across the Thames River Watershed, Connecticut, USA

Authors:

Mark Butler

Brian Yellen

Oluyinka Oyewumi

William Ouimet

Justin Richardson

Publication Type:
Journal Article
Year of Publication:
2023
Publisher:
Elsevier BV
Secondary Title:
Science of The Total Environment
ISSN:
0048-9697
DOI:
10.1016/j.scitotenv.2023.165630
Pages:
165630
Volume:
899
Year:
2023

Abstract

Understanding drivers of nutrient and pollutant elements (NPEs) in soils, sediments, and river water is important for protecting water resources and aquatic ecosystems. The objectives of this study were to quantify accumulation and transport of NPEs (P, As, Cd, Cu, Ni, Pb, and Zn) in riparian soils, sediments, river water, and watershed-scale exports within seven post-industrial subwatersheds of the Thames River, Connecticut, USASuspended sediments and river water samples were collected from February 2019 to January 2020. Arsenic concentrations in soil (6 to 18 mg kg−1) and sediments (8 to 85 mg kg−1) generally exceeded state and federal EPA quality targets but not river water. Elevated Pb ‘hot spots’ occurred in some riparian soils (>2000 mg kg−1) and sediments (>200 mg kg−1), but the other NPEs concentrations were below toxic thresholds. Riparian soil concentrations and watershed land cover were generally weak predictors for NPE concentrations in bottom sediments, suspended sediments, and river water. DOC, Mn, and Fe concentrations were important predictors for area-normalized dissolved and sediment-bound export of NPEs across the seven watersheds. Dissolved export was greater than sediment export for Mn, P, As, Cd, Cu, and Ni but not for Fe, Pb, and Zn. Watersheds with higher farmland had higher P river water concentrations, but the larger, more urbanized watershed had the highest total and area-normalized P export. An estuarine sediment core that captures sediment from the whole watershed and spans pre-industrial conditions through present shows that export of most NPEs has decreased since its peak, but all remain above baseline throughout the Thames River watershed. Future constraints on surface soil-river exchange and erosion inputs are needed to investigate rates of NPE sourcing to the watersheds.