The Selenga River delta: a geochemical barrier protecting Lake Baikal waters

Chalov, Sergey; Thorslund, Josefin; Касимов, Н.С.; Aybullatov, Denis; Ильичева, Е. А.; Karthe, Daniel; Kositsky, Alexey; Lychagin, Mikhail; Nittrouer, J.; Pavlov, Maxim; Pietroń, Jan; Shinkareva, Galina; Tarasov, M. K.; Гармаев, Е. Ж.; Akhtman, Yosef; Jarsjö, Jerker

doi:10.1007/s10113-016-0996-1

Cited by 63 publications

(62 citation statements)

References 43 publications

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“…The results of the various international research programs such as the Russian Geographical Society project "Expedition Selenga-Baikal", UNDP-GEF project "Integrated Natural Resource Management in the Baikal Basin Transboundary Ecosystem", and the German BMBF-funded Thematically, the manuscripts consider hydrological changes and their drivers, pollutant and sediment input, transport and deposition and their role for the aquatic ecosystem of the Selenga, its tributaries and its delta. The spatial focus of the manuscripts ranges from basinwide studies (Malsy et al 2016;Frolova et al 2017) to specific subregions such as the Selenga's headwaters (Kopp et al 2016;Kaus et al 2016;Thorslund et al 2012) or its delta (Chalov et al 2016) ( Table 1). These studies provide an important contribution for a better understanding of spatial and temporal processes regarding hydrology, sediment and pollutant fluxes and aquatic ecology in the Selenga River-Lake Baikal Basin, adding novel insights into this unique ecosystem as compared to previous reports in literature (Table 1).…”

Section: About This Special Issuementioning

confidence: 99%

“…However, north of the Buryatian capital Ulan Ude, the Selenga River branches into the largest freshwater inland delta in the world (Logachev 2003). The associated wetland constitutes a unique ecosystem (Гармаев and Христофоров 2010) and acts as the final geobiochemical barrier before the Selenga discharges into Lake Baikal (Chalov et al 2016).…”

Section: Introductionmentioning

confidence: 99%

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Environmental change in the Selenga River—Lake Baikal Basin

2017

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Section: About This Special Issuementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Environmental change in the Selenga River—Lake Baikal Basin

2017

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“…Field measurements of SSC for calibration of the SSC model were undertaken at more than 50 locations within the delta (Chalov et al, 2016) (Fig. 1).…”

Section: Suspended Sediment Concentration Model Based On Landsat Datamentioning

confidence: 99%

“…Since there is no constantly measured discharge data in each channel system, average values for water partitioning between sectors (Chalov et al, 2016) were used. Three possible ratios between sediment input and output were analysed: S 2 >S 1 , S 2 <S 1 and S 2 ≈ S 1 , which correspond to either erosional ( S>0), depositional ( S<0) or equilibrium ( S = 0) states.…”

Section: Suspended Sediment Concentration Model Based On Landsat Datamentioning

confidence: 99%

Modelling suspended sediment distribution in the Selenga River Delta using LandSat data

2017

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Abstract. The Selenga River is the largest tributary of Baikal Lake and it's delta covers around 600 km 2 . Suspended sediment concentrations (SSC) in the Selenga river delta were modelled based on LandSat images data. The seasonal variability in suspended sediment retention during the period 1989 to 2015 was calculated. The results suggest that sediment storage in the Selenga delta is observed during high discharges (> 1500 m 3 s −1 ), whereas sediment export increases under lower flow conditions (< 1500 m 3 s −1 ). The changes in seasonal SSC patterns are explained by wetland inundation during floods and channel erosion or Baikal wind surge during low flow periods.

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“…Our here estimated mass flows and parallel quantifications Chalov et al 2016) of metal transport in the Tuul River all point to mining activities as the main driver of increasing sediment loads to downstream regions. Coupled to this, geochemical processes (e.g.…”

Section: Impact Of Metal Speciation On Hydrological Transportmentioning

confidence: 66%

Speciation and hydrological transport of metals in non-acidic river systems of the Lake Baikal basin: Field data and model predictions

et al. 2016

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The speciation of metals in aqueous systems is central to understanding their mobility, bioavailability, toxicity and fate. Although several geochemical speciation models exist for metals, the equilibrium conditions assumed by many of them may not prevail in field-scale hydrological systems with flowing water. Furthermore, the dominant processes and/or process rates in non-acidic systems might differ from well-studied acidic systems. We here aim to increase knowledge on geochemical processes controlling speciation and transport of metals under nonacidic river conditions. Specifically, we evaluate the predictive capacity of a speciation model to novel measurements of multiple metals and their partitioning, under highpH conditions in mining zones within the Lake Baikal basin. The mining zones are potential hotspots for increasing metal loads to downstream river systems. Metals released from such upstream regions may be transported all the way to Lake Baikal, where increasing metal contamination of sediments and biota has been reported. Our results show clear agreement between speciation predictions and field measurements of Fe, V, Pb and Zn, suggesting that the partitioning of these metals mainly was governed by equilibrium geochemistry under the studied conditions. Systematic over-predictions of dissolved Cr, Cu and Mo by the model were observed, which might be corrected by improving the adsorption database for hydroxyapatite because that mineral likely controls the solubility of these metals. Additionally, metal complexation by dissolved organic matter is a key parameter that needs continued monitoring in the Lake Baikal basin because dependable predictions could not be made without considering its variability. Finally, our investigation indicates that further model development is needed for accurate As speciation predictions under non-acidic conditions, which is crucial for improved health risk assessments on this contaminant.

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The Selenga River delta: a geochemical barrier protecting Lake Baikal waters

Cited by 63 publications

References 43 publications

Environmental change in the Selenga River—Lake Baikal Basin

Environmental change in the Selenga River—Lake Baikal Basin

Modelling suspended sediment distribution in the Selenga River Delta using LandSat data

Speciation and hydrological transport of metals in non-acidic river systems of the Lake Baikal basin: Field data and model predictions

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