A Strontium and Hydro-Geochemical Perspective on Human Impacted Tributary of the Mekong River Basin: Sources Identification, Fluxes, and CO2 Consumption

Zhang, Shitong; Han, Guilin; Zeng, Jie; Xiao, Xuhuan; Malem, Fairda

doi:10.3390/w13213137

Cited by 8 publications

(4 citation statements)

References 53 publications

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“…There are two sources of heavy Cu isotope enrichment in topsoil: (a) Cu deposition from the atmosphere to the soil surface (i.e., mineral dust and anthropogenic particulate matters); and (b) Cu exchange from groundwater to surface water during the dry seasons as Cu (II) is more soluble than Cu (I) and has greater leaching loss to groundwater (Vance et al., 2016; Wang et al., 2022). Given that the precipitation in the dry season of MRB is negligible compared with the weathering of element cycling (S. Zhang et al., 2021), and that the enrichment of Fe, Mn, and Cu is low in the topsoil of the S1 and S2 profiles (Figure 3), the atmospheric deposition could not result in heavy isotope pools.…”

Section: Discussionmentioning

confidence: 99%

Extreme Copper Isotope Fractionation Driven by Redox Oscillation During Gleysols Weathering in Mun River Basin, Northeast Thailand

et al. 2023

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Copper (Cu), a key nutrient for plants and humans, is ubiquitously involved in redox reactions in terrestrial ecosystems, and the biogeochemical behavior and isotope fractionation of Cu are controlled by redoximorphic conditions (Kumar et al., 2021). Gleysols that are formed in response to water-level fluctuations are recognized as redoximorphic soils, and play a crucial role in controlling the terrestrial biogeochemical behaviors of Cu (Fekiacova et al., 2015;Tabor et al., 2017). Under redox fluctuation, Fe/Mn oxyhydroxides and soil organic Abstract Copper (Cu) isotopes are utilized to track Cu geochemical cycling in weathered gleysols of tropical zones. A significant isotope fractionation of Cu in these soils is primarily redox-controlled; however, it is rarely reported how the frequency of redox fluctuations affects the soil Cu isotope signature. This study investigated the variations of Cu content and isotope fractionation in two low-humic gleysol profiles (S1 and S2) from a dry tropical savanna zone. Owing to redox oscillation during weathering, δ 65 Cu values in profile S2 showed a stronger positive correlation with the mafic index of alteration of reducing environment than S1, and isotopically light Cu is more retained in the Zone II of profile S2 than S1. As the frequency of redox fluctuation increased, the retained stable Cu(I) species and light Cu isotopes increased in the residual soils through re-adsorption or re-precipitation by iron oxyhydroxide (i.e., ferrihydrite). Importantly, an Mn-enriched zone was formed after reduction events in profile S2, and found to be enriched in light Cu isotopes. The heavier Cu fraction might be lost by adsorption on Fe oxyhydroxides in the Mn-rich zone, while the relatively light Cu might be retained through adsorption on Mn oxyhydroxides. Additionally, a significant Soil Organic Carbon (SOC) contribution to Cu was found due to the high δ 65 Cu-SOC correlation (R 2 = 0.80) in S1 (depth <1 m). Therefore, our study shows that the Cu isotope signature can respond to redox changes in the terrestrial ecosystem, and these Cu isotope signatures may have significant implications for assessing soil ecological vulnerability under future climate change scenarios.

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Section: Discussionmentioning

confidence: 99%

Extreme Copper Isotope Fractionation Driven by Redox Oscillation During Gleysols Weathering in Mun River Basin, Northeast Thailand

et al. 2023

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“…The pH in the dry season ranged from 6.1 to 7.7, with an average of 7.0 [45], and the pH in the midstream (6.6) was lower than upstream (7.1) and downstream (7.1). The pH in the wet season varied from 6.4 to 7.7, with an average of 6.9 [29], and the pH in the midstream (6.6) was lower than upstream (7.4) and downstream (6.7).…”

Section: Temporal and Spatial Variations In Ph Do And Docmentioning

confidence: 97%

“…Figure 2. (a) Dissolved oxygen (DO) and (b) Dissolved organic carbon (DOC) in the upstream, midstream and downstream of Mun River (MR) during dry and wet season; data are from[29,45].…”

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confidence: 99%

Geochemical and Seasonal Characteristics of Dissolved Iron Isotopes in the Mun River, Northeast Thailand

Xiao

Han

Zeng

et al. 2022

Water

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Dissolved iron (Fe) isotopes in river water have a pivotal role in understanding the Fe cycle in the surficial environment. A total of 13 samples of river water were collected from the Mun River to analyze the Fe isotopes and their controlling factors in river water, such as dissolved organic carbon (DOC) and different supply sources. The results showed that dissolved Fe (DFe) concentrations ranged from 21.49 μg/L to 232.34 μg/L in the dry season and ranged from 10.48 μg/L to 135.27 μg/L in the wet season, which might be ascribed to the dilution effect. The δ56Fe of the dry season (−0.34 to 0.57‰, with an average 0.09‰) was lower than that of the wet season (−0.15 to 0.48‰, with an average 0.14‰). Combined with the δ56Fe and DFe/DAl ratios, the end-members of DFe were identified, including rock weathering (high δ56Fe and low DFe/DAl ratio), anthropogenic inputs (high δ56Fe and high DFe/DAl ratio) and groundwater inputs (low δ56Fe and low DFe/DAl ratio). The relationship between δ56Fe and DOC concentrations suggested that the chelation of organic matter with heavy Fe isotopes was one of the important sources of heavy Fe isotopes in river water.

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“…The results are similar to the findings of other scholars. However, the concentrations of Na + and Cl − are underestimated in the ionic content [43][44][45], which may be related to the fact that the fraction of NaCl content was not recorded in the soil data survey. In addition, as can be seen in Figure 7C,E,H, the concentrations of Mg 2+ , K + , and HCO 3 − show an increasing trend from year to year.…”

Section: Changes In Drainage and Salt Dischargementioning

confidence: 99%

Water, Salt, and Ion Transport and Its Response to Water-Saving Irrigation in the Hetao Irrigation District Based on the SWAT-Salt Model

Ao,

Jiang,

Bailey

et al. 2024

Agronomy

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Soil salinization is one of the main hazards affecting the sustainable development of agriculture in the Hetao Irrigation District (HID) of Inner Mongolia. To grasp the water and salt transport patterns and spatial–temporal distribution characteristics of the HID at the regional scale, the improved Soil and Water Assessment Tool with a salinity module (SWAT-Salt) model was used to establish the distributed water and salt transport model for the watershed in this study. The results demonstrated that the modified model could more accurately represent the process of water and salt changes in the HID. The coefficient of determination (R2) in the simulation of streamflow and discharge salt loading was 0.83 and 0.86, respectively, and the Nash–Sutcliffe efficiency (NSE) was 0.80 and 0.74, respectively. Based on this, different hydrological processes (surface runoff, lateral flow, groundwater, soil seepage) as well as spatial–temporal distribution characteristics of water salinity in groundwater and soil were analyzed in the HID. Differences in groundwater and soil salinity in different land uses and soil types were also compared. Of these, surface runoff and lateral flow salt discharge loading are concentrated in the southwestern portion of the basin, while groundwater salt discharge loading is concentrated in the eastern as well as southwestern portions of the basin. The salt discharge loading from groundwater accounts for about 98.7% of the total salt discharge loading from all hydrological pathways and is the major contributing part of salt discharge from the irrigation area. Soil salinity increases gradually from west to east. Groundwater salinity (2946 mg/L) and soil water electrical conductivity (0.309 dS/m) were minimized in the cropland. Meanwhile, rational allocation of irrigation water can appropriately increase the amount of salt discharge loading. In conclusion, the model could provide a reference for the investigation of soil salinization and water–salt management measures in irrigation areas.

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A Strontium and Hydro-Geochemical Perspective on Human Impacted Tributary of the Mekong River Basin: Sources Identification, Fluxes, and CO2 Consumption

Cited by 8 publications

References 53 publications

Extreme Copper Isotope Fractionation Driven by Redox Oscillation During Gleysols Weathering in Mun River Basin, Northeast Thailand

Extreme Copper Isotope Fractionation Driven by Redox Oscillation During Gleysols Weathering in Mun River Basin, Northeast Thailand

Geochemical and Seasonal Characteristics of Dissolved Iron Isotopes in the Mun River, Northeast Thailand

Water, Salt, and Ion Transport and Its Response to Water-Saving Irrigation in the Hetao Irrigation District Based on the SWAT-Salt Model

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