Assessment of the sustainability of groundwater utilization and crop production under optimized irrigation strategies in the North China Plain under future climate change

Assessment of the sustainability of groundwater utilization and crop production under optimized irrigation strategies in the North China Plain under future climate change

Over-exploitation of groundwater due to intensive irrigation and anticipated climate change pose severe threats to the water and food security worldwide, particularly in the North China Plain (NCP). Limited irrigation has been recognized as an effective way to improve crop water productivity and slo...

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Bibliographic Details
Published in:The Science of the total environment Vol. 899; p. 165619
Main Authors: Tan, Lili, Zhang, Xueliang, Qi, Junyu, Sun, Danfeng, Marek, Gary W., Feng, Puyu, Li, Baogui, Liu, De Li, Li, Baoguo, Srinivasan, Raghavan, Chen, Yong
Format: Journal Article
Language:English
Published: Netherlands Elsevier B.V 15-11-2023
Subjects:
Climate change adaptation
Crop yield
Limited irrigation
NCP
Shallow groundwater level
SWAT-MAD-GW-CO2
SWAT-MAD-GW-CO2
Shallow groundwater level
Limited irrigation
NCP
Climate change adaptation
Crop yield
SWAT-MAD-GW-CO
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Summary:Over-exploitation of groundwater due to intensive irrigation and anticipated climate change pose severe threats to the water and food security worldwide, particularly in the North China Plain (NCP). Limited irrigation has been recognized as an effective way to improve crop water productivity and slow the rapid decline of groundwater levels. Whether optimized limited irrigation strategies could achieve a balance between groundwater pumping and grain production in the NCP under future climate change deserves further study. In this study, an improved Soil and Water Assessment Tool (SWAT) model was used to simulate climate change impacts on shallow groundwater levels and crop production under limited irrigation strategies to suggest optimal irrigation management practices under future climate conditions in the NCP. The simulations of eleven limited irrigation strategies for winter wheat with targeted irrigations at different growth stages and with irrigated or rainfed summer maize were compared with future business-as-usual management. Climate change impacts showed that mean wheat (maize) yield under adequate irrigation was expected to increase by 13.2% (4.9%) during the middle time period (2041–2070) and by 11.2% (4.6%) during the late time period (2071–2100) under three SSPs compared to the historical period (1971–2000). Mean decline rate of shallow groundwater level slowed by approximately 1 m a−1 during the entire future period (2041–2100) under three SSPs with a greater reduction for SSP5–8.5. The average contribution rate of future climate toward the balance of shallow groundwater pumping and replenishment was 62.9%. Based on the simulated crop yields and decline rate of shallow groundwater level under the future climate, the most appropriate limited irrigation was achieved by applying irrigation during the jointing stage of wheat with rainfed maize, which could achieve the groundwater recovery and sustainable food production. [Display omitted] •The SWAT was enhanced by improving auto irrigation, groundwater, and CO2 modules.•Increased future rainfall and decreased irrigation benefited groundwater conservation.•Future crop yield was stable under limited irrigation relative to historical period.•Contribution rate of future climate to groundwater use and recharge balance was 62.9%.•Irrigation during the wheat jointing stage achieved the groundwater-food system balance.
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content type line 23
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2023.165619