Spatio-temporal variations of nitrate pollution of groundwater in the intensive agricultural region: Hotspots and driving forces
[Display omitted] •Variation of nitrate and hydrochemical characteristics of groundwater was evaluated.•Over 60% of groundwater samples in canal irrigated region exceeded the WHO standard.•The hot spots of groundwater NO3− pollution occurred in the canal irrigation region.•Designating NO3− vulnerabl...
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| Published in: | Journal of hydrology (Amsterdam) Vol. 623; p. 129864 |
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| Main Authors: | , , , , , , |
| Format: | Journal Article |
| Language: | English |
| Published: |
Elsevier B.V
01-08-2023
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| Subjects: | |
| Online Access: | Get full text |
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| Summary: | [Display omitted]
•Variation of nitrate and hydrochemical characteristics of groundwater was evaluated.•Over 60% of groundwater samples in canal irrigated region exceeded the WHO standard.•The hot spots of groundwater NO3− pollution occurred in the canal irrigation region.•Designating NO3− vulnerable zones in the intensive apple-planting regions is urgent.
Nitrate (NO3−) pollution of groundwater is a persistent and widespread problem worldwide, particularly in intensive agricultural regions with high nitrogen (N) surplus. Identifying spatio-seasonal variations, drivers and sources of NO3− in groundwater is key to controlling this pollution. In this study, we monitored 175 wells in areas with different irrigation practices (dryland, well irrigation and canal irrigation) in an intensive apple-planting region over a year (September 2020–October 2021) in the southern Loess Plateau, China. The integration of hydrochemical analysis, deep soil profiles, NO3− isotopic composition and a Bayesian isotope mixing model (SIAR) was used to identify the hotspots and hot moments of groundwater NO3− pollution, and main NO3− sources. The results showed that average NO3− concentrations of three regions gradually decreased from north to south, following the order of dryland region (9 mg NO3 L−1) < well irrigation region (23 mg NO3 L−1) < canal irrigation region (94 mg NO3 L−1), and orchard > residential area ≈ cereal land. In the study region, 44% of groundwater exceeded the drinking standard of the World Health Organization (50 mg NO3 L−1). The intensive apple planting in the canal irrigation regions has caused groundwater NO3− pollution, and changed hydrochemical types from HCO3−Ca‧Mg to SO4‧Cl‧NO3-Ca‧Mg. In the canal irrigation region, NO3− in the vadose zone has migrated to groundwater. The hotspots of groundwater NO3− pollution (NO3− vulnerable zones) were identified at low-altitude loess tableland and alluvial plains with canal irrigation. Irrigation and precipitation accelerated soil NO3− deep migration. The hot moments of NO3− pollution in the irrigated region was the period from the wet season to the dry season; and the “hidden reactive N pool” in the deep vadose zone (>2 m) caused a time lag of NO3− reaching into groundwater. Chemical N fertilizer and manure N applied in apple orchards were the main contributing sources of groundwater NO3− pollution in the apple-planting region. Our study highlights the significant effect of apple-planting industry development on groundwater quality. |
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| ISSN: | 0022-1694 1879-2707 |
| DOI: | 10.1016/j.jhydrol.2023.129864 |