Potential accumulation of contaminated sediments in a reservoir of a high‐Andean watershed: Morphodynamic connections with geochemical processes

Contreras, Marta; Müllendorff, Daniel; Pastén, Pablo; Pizarro, Gonzalo; Paola, Chris; Escauriaza, Cristián

doi:10.1002/2014wr016130

Cited by 15 publications

(10 citation statements)

References 31 publications

(55 reference statements)

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“…In recent years, we have investigated in detail the effects of legacy mining in the high-altitude environment of the Lluta River in northern Chile, focusing on the coupling of physical and biogeochemical processes in the system (Abarca et al, 2017;Arce et al, 2017;Contreras et al, 2015;Guerra, Gonzalez, et al, 2016;Guerra, Simonson, et al, 2016;Leiva et al, 2014). Acid drainage in this watershed has increased the concentration of elements and compounds such as arsenic, aluminum, iron, chlorides, and sulfates in the river.…”

Section: Introductionmentioning

confidence: 99%

Field and Numerical Investigation of Transport Mechanisms in a Surface Storage Zone

et al. 2019

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In‐stream surface storage zones (SSZs) caused by lateral recirculation areas play a significant role in the transport and fate of contaminants in rivers. Lateral recirculating areas have long residence times that favor nutrient uptake, accumulation of pollutants, and interactions with reactive sediments. In watersheds affected by acid‐mine drainage, SSZs have profound effects on biogeochemical processes, controlling the local concentration and distribution of toxic elements along the channel. Despite the importance of turbulent flow dynamics on these processes, limited work has been carried out to analyze mass transport in natural SSZs with complex geometries. In this investigation we study a SSZ in the Lluta River, located in a high‐altitude environment in northern Chile, by coupling field measurements and 3‐D numerical simulations to understand the transport mechanisms with the main channel. We measure the velocity field using an acoustic Doppler velocimeter (ADV) and large‐scale particle image velocimetry (LSPIV), extracting the bathymetry from digital image processing. Using these data, we perform detached‐eddy simulations (DES) to analyze the mean flow, turbulence statistics, and the dynamics of large‐scale coherent structures. From this detailed description of the turbulent flow, we study the mass exchange and the time evolution of the mean concentration of a passive scalar in the SSZ by testing three upscaled models: a classical linear transport model, a two‐storage formulation, and a fractional transport model. The analysis integrates temporal and spatial scales to provide a new perspective on the turbulent flow in SSZs and their effects on global mass transport in rivers.

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Section: Introductionmentioning

confidence: 99%

Field and Numerical Investigation of Transport Mechanisms in a Surface Storage Zone

et al. 2019

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“…Indeed, a better understanding of the relationship between PSDs and water quality is needed to understand the dynamics of contaminated sediments in rivers as well as in reservoirs and to optimize water infrastructure during mine closure operations. Contreras et al () coupled physical and geochemical processes to model the fate of arsenic in an Andean reservoir. They revealed an explicit connection between morphodynamics and the deposition of fine arsenic‐rich particles by modeling the progression of the coarse sediment mixture and assuming that all fine sediments accumulated over the bottomset bed of the delta.…”

Section: Introductionmentioning

confidence: 99%

Response of suspended sediment particle size distributions to changes in water chemistry at an Andean mountain stream confluence receiving arsenic rich acid drainage

Abarca

Guerra

Arce

et al. 2016

Hydrological Processes

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Acid drainage is an important water quality issue in Andean watersheds, affecting the sustainability of urban, agricultural, and industrial activities. Mixing zones receiving acid drainage are critical sites where changes in pH and chemical environment promote the formation and dissolution of iron and aluminum oxy/hydroxides. These particles can significantly change the speciation of toxic metals and metalloids throughout drainage networks via sorption, desorption, and settling processes. However, little is known about the behavior of particle size distributions (PSDs) in streams affected by acid drainage and their relationship to metal speciation. This work studied: (a) the PSDs for a wide range of mixing ratios found at a fluvial confluence affected by acid drainage, and (b) the response of PSDs and arsenic speciation to environmental changes found when the particles approach complete mixing conditions. The confluence between the Azufre River (pH ~ 2, high concentration of dissolved metals) and Caracarani River (pH = 8.6, low concentration of dissolved metals) was used as a representative model for study. Field measurements show a bimodal PSD with modal diameters of ~50 and 300 μm. At shorter distances from the junction, the smaller modes with smaller particle volumes were dominant across the stream cross‐sections. A systematic shift towards larger particle sizes and larger particle volumes occurred downstream. The analysis of laboratory PSDs for Azufre/Caracarani mixing ratios between 0.01 and 0.5 (pH from 6.2 to 2.3) showed a bimodal trend with ~15 and 50 μm characteristic diameters; larger particles formed at pH>4. When particle suspensions were transferred in laboratory experiments from very low pH to full mixing conditions (pH ~ 2.8 and mixing ratio ~ 0.25) particle sizes varied, and the dissolved arsenic concentration decreased. The observed reaction kinetics were slow compared to the time scale of advective transport, creating opportunities for engineered controls for arsenic. This work contributes to a better understanding of the chemical‐hydrodynamic interactions in watersheds affected by mining, and identifying opportunities to improve water quality at points of use.

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“…The MUSCL scheme is used to perform the extrapolation with second order accuracy in space. The model has been validated for many cases including supercritical flows and wave propagation on dry surfaces, comparing also the results with analytical solutions and experiments that include sharp density gradients [5].…”

Section: Hydrodynamic Modelingmentioning

confidence: 99%

“…The resolution of the simulations in time and space shows the evolution of the flow in the city, and the regions where the sediment concentration produces significant changes on the velocity and flow depth. We have also performed a complete analysis on the effects of hyperconcentration on the hydrograph, velocity of the wave front, evaluating also the effects of high sediment concentrations and geomorphic drivers on the propagation of floods in mountain streams [5]. Simulations with the coupled hydrological and hydrodynamic models have high computational costs, especially if many scenarios need to be evaluated.…”

Section: Hydrodynamic Modelingmentioning

confidence: 99%

Advanced numerical models for the propagation of floods with high-sediment concentrations in mountain rivers

et al. 2018

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Rapid floods induced by extreme precipitation are common events in regions near the Andes mountain range. Growing urban development, combined with the changing climate and the influence of El Niño, have increased the exposure of the population in many regions of South America. Simulations of flash floods in these watersheds are very challenging, due to the complex morphology, the insufficient hydrometeorological data, and the uncertainty posed by the variability of sediment concentration. To address these issues, we develop a high-resolution numerical model of the non-linear shallow water equations, coupled with the mass conservation of sediment, and considering the density effects and changes of rheology in the momentum equation. Based on these simulations we develop a real-time early-warning system, by creating a surrogate model or meta-model from the simulations. Using a small set of parameters, we define storms for a wide range of meteorological conditions, and utilize the high-fidelity model results to create a database of flood propagation under different conditions. Through this second model we perform a sophisticated interpolation/regression, and approximate efficiently the flow depths and velocities. This is the first application of its kind in the Andes region, which can be used to improve the prediction of flood hazard in real conditions, employing low computational resources. We also create a framework to develop early warning systems, and to help decision makers and city planners in these mountain regions.

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Potential accumulation of contaminated sediments in a reservoir of a high‐Andean watershed: Morphodynamic connections with geochemical processes

Cited by 15 publications

References 31 publications

Field and Numerical Investigation of Transport Mechanisms in a Surface Storage Zone

Field and Numerical Investigation of Transport Mechanisms in a Surface Storage Zone

Response of suspended sediment particle size distributions to changes in water chemistry at an Andean mountain stream confluence receiving arsenic rich acid drainage

Advanced numerical models for the propagation of floods with high-sediment concentrations in mountain rivers

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