Abstract
In marked contrast to alluvial rivers, few studies have examined the physical and geochemical controls on the spatial distribution of toxic trace metals along bedrock channels. This study examined the factors controlling the geographical pattern of selected trace metal (Cu, Cr, and Zn) concentrations along the bedrock-dominated channel of the South Fork New River (SFNR). The SFNR is located in the Blue Ridge Physiographic Province of North Carolina, and is representative of many rivers in mountainous terrains that are often subjected to the influx of toxic trace metals from historic and contemporary mining operations. The topography of the SFNR’s channel bed is highly variable and can be subdivided into pool and shallow bedrock reaches. The latter contained localized cascades characterized by topographically higher bedrock ribs that are separated by topographic lows, both of which are oriented oblique to flow. Accumulations of bed sediments are predominantly associated with the traverse bedrock ribs that generate high hydraulic roughness. Except for a few localized zones of enrichment, sediment-associated trace metal concentrations tended to vary within a narrow range of background values over the 36 km study reach. Elevated trace metal concentrations were closely linked to zones of high Fe and Mn concentrations, and were associated with pools located within or immediately downstream of bedrock cascades. The elevated concentrations of the metals appear to be derived from the erosion of lithologic units within the cascades that contain sulfidic layers or zones of mafic mineral enrichment, and which are known to occur in the underlying bedrock. Once eroded, these minerals and/or rock fragments were deposited within low-velocity zones created by the transverse ribs or within downstream pools. The enrichment of trace metals downstream of the cascades may also be due to the formation of Fe and Mn oxyhydroxides as turbulent flows aerate river waters as they traverse the cascades. Chemically reactive fine-grained (<63 µm) sediments had a relatively limited influence on the downstream variations in metal concentrations, presumably because the channel bed sediments are composed primarily of sand-sized and larger particles. Although a principal component analysis (PCA) suggested that reach-scale variations in channel and valley morphology may have partly influenced downstream variations in trace metal concentrations, the geographical patterns were primarily controlled by local geological and geomorphic factors associated with the bedrock cascades. The design of future sampling programs along such coarse-grained, bedrock rivers should consider the significance of these local controls on trace metal storage to effectively characterize and interpret downstream patterns in metal concentrations.
Highlights
Anthropogenic activities, during and following the industrial revolution, have led to the widespread contamination of river channels and floodplains by toxic trace metals
Variations in concentration along alluvial rivers have generally been attributed to five factors, including (1) the proximity to, and magnitude of inputs from point and diffuse metal sources, (2) geochemical processes that promote metal precipitation or dissolution, including redox sensitivity scavenger elements such as Fe and Mn, (3) the partitioning of sediment-associated metals into discrete geomorphic features and deposits by hydraulic processes, (4) metal dilution by relatively “clean” or non-reactive sediments, and (5) biological uptake [29]
We examine some of the possible controls on the observed variations in sediment composition and trace metal concentrations
Summary
Anthropogenic activities, during and following the industrial revolution, have led to the widespread contamination of river channels and floodplains by toxic trace metals (which have historically been referred to as heavy metals consisting of metallic elements with a density >~6 g/cm ). During the past four decades, the potential impacts of mining operations on aquatic ecosystems has been extensively documented, both from an academic perspective and from the perspective of remediating a contaminated site [1,2,3,4,5,6,7] Such studies have shown that 90–95% of the trace metal load in rivers characterized by natural Eh and pH conditions occurs in association with particulate matter [8,9]. Outlier concentrations consistently occurred at sites NR 9 (Cu, Cr), NR 21
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