Insights into groundwater salinization from hydrogeochemical and isotopic evidence in an arid inland basin

Liu, Yalei; Jin, Menggui; Wang, Jianjun

doi:10.1002/hyp.13243

Cited by 35 publications

(24 citation statements)

References 56 publications

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“…In the USA, increasing efforts are now made to delineate brackish groundwater resources to strategically deploy desalination systems there to augment drinking-water supplies as freshwater sources become increasingly scarce (Chowdhury et al, 2018). Groundwater salinity is of mounting concern in many semi-arid systems globally (Boukhari et al, 2018;Liu et al, 2018), and may be increasingly exacerbated by the impacts of irrigated agriculture (Foster et al, 2018). Salinity within shallow or intermediate depth groundwater is considered high over 16% of the global land area, within which some 1.1 billion people reside (Van Weert et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Responding to salinity in a rural African alluvial valley aquifer system: To boldly go beyond the world of hand-pumped groundwater supply?

Rivett

Budimir

Mannix

et al. 2019

Science of The Total Environment

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Highlights  Effective response to developing-world groundwater salinity to safeguard water supply  Salinity problem defined via conceptual model -salinity survey -water-point mapping  Groundwater salinity response capacity constrained in Malawi by multiple factors  Need to evaluate options beyond model-supply paradigm of hand-pumped borehole supply  Feasibility study of larger groundwater or surface-water supply alternatives to boldly go beyond Responding to groundwater salinity in rural African alluvial valley aquifer systems the world of hand-pumped groundwater supply?

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Section: Introductionmentioning

confidence: 99%

Responding to salinity in a rural African alluvial valley aquifer system: To boldly go beyond the world of hand-pumped groundwater supply?

Rivett

Budimir

Mannix

et al. 2019

Science of The Total Environment

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“…water, due to strong evaporation in arid areas [33]. Furthermore, the mean isotopes of shallow groundwater (δ 18 O = −8.2‰) were lower than the values of river water but higher than those for the middle groundwater (mean δ 18 O = −9.1‰) and deep groundwater (mean δ 18 O = −9.3‰) in the study area.…”

Section: Stable Water Isotopic Compositionmentioning

confidence: 68%

“…This indicated that river discharge was dominated by precipitation during the wet season [38]. Stable isotopes of reservoir water (mean δ 18 O = −6.1‰) were higher than those of river water, due to strong evaporation in arid areas [33]. Furthermore, the mean isotopes of shallow groundwater (δ 18 O = −8.2‰) were lower than the values of river water but higher than those for the middle groundwater (mean δ 18 O = −9.1‰) and deep groundwater (mean δ 18 O = −9.3‰) in the study area.…”

Section: Stable Water Isotopic Compositionmentioning

confidence: 99%

“…Meanwhile, groundwater hydrochemistry could be controlled by the coupling of multiple mechanisms, including evaporation-condensation, leaching and dissolution, precipitation, flushing and mixing, ion exchange, and subsurface biological activity [22,26,31,32]. Additionally, researchers found that spatiotemporal patterns of ion contents in groundwater can provide an insight into the salt origin, evolution, and migration pathways within the aquifers [26,33], which is helpful to understand groundwater water-salt migration in arid areas [34,35]. Yet, alteration of groundwater water-salt circulation by land use change and its influence on groundwater hydrochemistry evolution in the long term are not well known in the oasis-desert region of the Tarim Basin, particularly under the impact of cultivated area expansion.…”

Section: Introductionmentioning

confidence: 99%

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Assessing the Influences of Land Use Change on Groundwater Hydrochemistry in an Oasis-Desert Region of Central Asia

Wang

Yang

et al. 2022

Water

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Land use change greatly affects groundwater hydrochemical cycling and thereby food and ecosystem security in arid regions. Spatiotemporal distribution of groundwater hydrochemistry is vital to understand groundwater water-salt migration processes in the context of land use change, while it is not well known in the oasis-desert region of arid inland basins. Here, to investigate the influences of land use change on groundwater hydrochemistry and suggest sustainable management, 67 water samples were obtained in the Luntai Oasis, a typical oasis desert of Central Asia. Stable isotopes and chemical components of samples were analyzed. Piper and Gibbs plots were used to elaborate the chemical type and major mechanisms controlling water chemistry, respectively. The results showed that cultivated land area has markedly expanded in the Luntai Oasis over the last 20 years (increasing by 121.8%). Groundwater seasonal dynamics and groundwater–surface water interaction were altered dramatically by farmland expansion and groundwater exploitation. Specifically, the spatial heterogeneity and seasonal variability of groundwater hydrochemistry were significant. Compared with the desert area, the δ18O and TDS of river water and shallow groundwater in the oasis cropland exhibited lower values but greater seasonal variation. Higher TDS was observed in autumn for river water, and in spring for shallow groundwater. The chemical evolution of phreatic water was mainly controlled by the evaporation-crystallization process and rock dominance, with a chemical type of Cl-SO4-Na-Mg. Significant spatiotemporal heterogeneity of groundwater hydrochemistry demonstrated the influence of climatic, hydrogeological, land use, and anthropogenic conditions. Groundwater overexploitation would cause phreatic water leakage into confined water, promoting groundwater quality deterioration due to fresh saltwater mixing. Improving agricultural drainage ditches in conjunction with restricting farmland expansion and groundwater extraction is an effective way to alleviate groundwater environment deterioration and maintain oasis-desert ecosystems in arid regions.

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“…The elevation of the basin descends from 5243 m above sea level (a.s.l.) in the mountains to 256 m in the plains (Cheng et al, 2006; Liu et al, 2018).…”

Section: Methodsmentioning

confidence: 99%

Using bromide data tracer and HYDRUS‐1D to estimate groundwater recharge and evapotranspiration under film‐mulched drip irrigation in an arid Inland Basin, Northwest China

Chen

Wang

Liu

et al. 2021

Hydrological Processes

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Accurate estimation of groundwater recharge (GR) and evapotranspiration (ET) are essential for sustainable management of groundwater resources, especially in arid and semi-arid regions. In the Manas River Basin (MRB), water shortage is the main factor restricting sustainable development of irrigated agriculture, which relies heavily on groundwater. Film-mulched drip irrigation significantly changes the pattern and dominant processes of water flow in the unsaturated zone, which increases the difficulty of GR and ET estimation. To better estimate GR and ET under filmmulched drip irrigation in the MRB, bromide tracer tests and soil lithologic investigation were conducted at 12 representative sites. A one-dimensional variably saturated flow model (HYDRUS-1D) was calibrated at each site using soil evaporation data inferred from the bromide tracer tests. The results showed that average annual soil evaporation in uncultivated lands calculated from bromide trace tests was 25.55 mm.The annual GR ranged from 5.5 to 37.0 mm under film-mulched drip irrigation. The annual ET ranged from 507.0 to 747.1 mm, with soil evaporation between 35.7 and 117.0 mm and transpiration between 460.9 and 642.3 mm. Soil evaporation represented 7% to 16% of the total ET and more than 70% of precipitation and irrigation water was used by cotton plants. Spatial variations of soil lithology, water table depth and initial soil water content led to the spatial differences of GR and ET in the MRB.Our study indicated that bromide tracer tests are useful for inferring ET in the arid and semi-arid oases. The combination of bromide tracer tests and HYDRUS-1D enhances reliability for estimation of GR and ET under film-mulched drip irrigation in the MRB and shows promise for other similar arid inland basins around the world.

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Insights into groundwater salinization from hydrogeochemical and isotopic evidence in an arid inland basin

Cited by 35 publications

References 56 publications

Responding to salinity in a rural African alluvial valley aquifer system: To boldly go beyond the world of hand-pumped groundwater supply?

Responding to salinity in a rural African alluvial valley aquifer system: To boldly go beyond the world of hand-pumped groundwater supply?

Assessing the Influences of Land Use Change on Groundwater Hydrochemistry in an Oasis-Desert Region of Central Asia

Using bromide data tracer and HYDRUS‐1D to estimate groundwater recharge and evapotranspiration under film‐mulched drip irrigation in an arid Inland Basin, Northwest China

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