ID:
publications-2169
Type:
Peer reviewed articles
Year:
2022
Authors:
Busschaert, L; De Roos, S; Thiery, W; Raes, D; De Lannoy, GJM
Title:
Net irrigation requirement under different climate scenarios using AquaCrop over Europe
Venue/Journal:
Hydrology and Earth System Sciences
DOI:
10.5194/hess-26-3731-2022
Research type:
Data Management & Analytics
Water System:
Uncategorized
Technical Focus:
Abstract:
Abstract. Global soil water availability is challenged by the effects of climate change and a growing population. On average, 70β% of freshwater extraction is attributed to agriculture, and the demand is increasing. In this study, the effects of climate change on the evolution of the irrigation water requirement to sustain current crop productivity are assessed by using the Food and Agriculture Organization (FAO) crop growth model AquaCrop version 6.1. The model is run at 0.5βlatΓ0.5βlong resolution over the European mainland, assuming a general C3-type of crop, and forced by climate input data from the Inter-Sectoral Impact Model Intercomparison Project phase three (ISIMIP3). First, the AquaCrop surface soil moisture (SSM) forced with two types of ISIMIP3 historical meteorological datasets is evaluated with satellite-based SSM estimates in two ways. When driven by ISIMIP3a reanalysis meteorology, daily simulated SSM values have an unbiased root mean square difference of 0.08 and 0.06βm3βmβ3, with SSM retrievals from the Soil Moisture Ocean Salinity (SMOS) and Soil Moisture Active Passive (SMAP) missions, respectively, for the years 2015β2016 (2016 is the end year of the reanalysis data). When forced with ISIMIP3b meteorology from five global climate models (GCMs) for the years 2015β2020, the historical simulated SSM climatology closely agrees with the satellite-based SSM climatologies. Second, the evaluated AquaCrop model is run to quantify the future irrigation requirement, for an ensemble of five GCMs and three different emission scenarios. The simulated net irrigation requirement (Inet) of the three summer months for a near and far future climate period (2031β2060 and 2071β2100) is compared to the baseline period of 1985β2014 to assess changes in the mean and interannual variability of the irrigation demand. Averaged over the continent and the model ensemble, the far future Inet is expected to increase by 22βmm per month (+30β%) under a high-emission scenario Shared Socioeconomic Pathway (SSP) 3β7.0. Central and southern Europe are the most impacted, with larger Inet increases. The interannual variability in Inet is likely to increase in northern and central Europe, whereas the variability is expected to decrease in southern regions. Under a high mitigation scenario (SSP1β2.6), the increase in Inet will stabilize at around 13βmm per month towards the end of the century, and interannual variability will still increase but to a smaller extent. The results emphasize a large uncertainty in the Inet projected by various GCMs.
Link with Projects:
773903
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