The Gharb plain, situated at coordinates 34°15′N 6°35′W, occupies the northwestern region of Morocco as shown in Figure 1. Encompassing approximately 6160 square kilometers, it stretches approximately 80 kilometers along the Atlantic coastline and extends inland for about 110 kilometers. This region experiences a Mediterranean climate, characterized by hot, arid summers and mild winters. However, there is notable local variation in climate, with semi-arid conditions prevailing inland and sub-humid conditions along the coast. Annual rainfall typically exceeds 400 millimeters across most of the plain, with average temperatures hovering around 18.62°C. The cooler, wetter season lasts seven months from October to April.

The boundaries of the Gharb plain are defined by natural features: the hills of Lalla Zohra to the north, the Prerifans hills to the east, the Maamora plateau to the south (which is part of the Moroccan Meseta), and the Atlantic Ocean to the west.

The hydrographic network of the region is represented by the Sebou River, one of the major rivers in the kingdom, along with its tributaries including the Ouergha, Beht, Rdom, and Tiflet Rivers.

The data processing encompasses several key components (Figure 2): Firstly, we computed vegetation indices such as NDVI (Normalized Difference Vegetation Index), NDWI (Normalized Difference Water Index), SAVI (Soil Adjusted Vegetation Index), EVI (Enhanced Vegetation Index), and GNDVI (Green Normalized Difference Vegetation Index) for Landsat images available within Google Earth Engine (GEE) Table 1. This process yielded annual maximum and minimum changes in vegetation indices from 2013 to 2023. Secondly, we leveraged growing season images from 2019 to 2022 to delineate various land cover types and crop characteristics. Finally, we determined the land cover types of crop areas by overlaying land cover classification with the distribution of vegetation types.

Leveraging GEE’s extensive library of analysis tools and computing resources, we implemented a workflow for calculating vegetation indices, and advanced image classification algorithms to identify and map different land cover classes, ensuring accuracy in our measurements. Figure 2 represents the workflow of the overall methodology of the study:

The Gharb Regional Development Office ( ORMVAG) provided data socioeconomic for 2019/2020,2020/2021, and 2021/2022, which included details about crop types, areas, and production in the Gharb plain. These datasets were integrated with remote sensing, Google Earth engine platform, and meteorological data to analyze the spatial and temporal patterns of crop water consumption in the Gharb irrigated perimeter from 2019 to 2022. Solar and meteorological data obtained through Power Data Access Viewer (DAV)(power.Iarc.nasa.gov) from NASA were used in this study. Monthly and annual observed maximum and minimum air temperature, rainfall, wind speed measured at 2m height, relative humidity and daily sunshine duration data were available (Cheikhaoui et al., 2024).

To determine the irrigation water needs of crops such as rice, citrus, and sugarcane, factors such as evapotranspiration, crop coefficients, effective rainfall, crop water requirement, and irrigation coefficients are taken into account, using relevant meteorological data from studies by (Allen, 2003), (Allen et al., 1998), and (Cammarano et al., 2016).

Our study utilized Landsat imagery, accessible through the cloud-computing platform Google Earth Engine (GEE), to analyze temporal trends in vegetation indices within the Gharb-irrigated perimeter from 2013 to 2023. The selection of vegetation indices, including the Normalized Difference Vegetation Index (NDVI), Normalized Difference Water Index (NDWI), Soil Adjusted Vegetation Index (SAVI), Enhanced Vegetation Index (EVI), and Green Normalized Difference Vegetation Index (GNDVI), reflects a comprehensive approach to understanding ecosystem dynamics. NDVI, a widely used indicator of vegetation health, assesses the presence and vigor of vegetation based on the contrast between near-infrared and red reflectance. NDWI, on the other hand, highlights water bodies by exploiting the contrast between green and near-infrared reflectance. SAVI incorporates a soil adjustment factor to better account for soil background effects in dense vegetation areas. EVI, developed to overcome some limitations of NDVI, provides enhanced sensitivity in regions with dense vegetation. GNDVI, similar to NDVI but using the green band instead of the red band, offers an alternative perspective on vegetation dynamics. By analyzing the temporal distribution of these indices, we gain insights into long-term vegetation dynamics, including seasonal variations, trends in vegetation health, and responses to environmental factors such as water availability and land management practices. The line graph illustrates the time series of various vegetation indices from 2013 to 2023 in the Gharb-irrigated perimeter. (Figure 3) The graph indicates similar trends for the Normalized Difference Vegetation Index (NDVI), Enhanced Vegetation Index (EVI), and Green Normalized Difference Vegetation Index (GNDVI) in the Gharb-irrigated perimeter during the period. The mean values for these indices peaked in March 2017, with NDVI reaching 0.657, GNDVI reaching 0.568, and EVI reaching 0.651. Regarding minimum values, the NDVI reached a mean of 0.255 in July 2022, the GNDVI reached 0.237 in November 2013, and the EVI reached 0.212 in October 2021. Conversely, the minimum mean values for these indices occurred at different times. NDVI reached a minimum of 0.255 in July 2022, GNDVI reached 0.237 in November 2013, and EVI reached 0.212 in October 2021.

In contrast, the SAVI (Soil Adjusted Vegetation Index) indices displayed different fluctuations. SAVI peaked at 0.197 in March 2017 and reached a minimum of 0.064 in November 2013.

Furthermore, the NDWI (Normalized Difference Water Index) peaked in December 2016 at -0.244 and reached a minimum of -0.372 in May 2020.

Using Google Earth Engine, we conducted a classification analysis aimed at mapping crop types across the Gharb-irrigated perimeter (Figure 4). Leveraging the capabilities of this platform, we employed a classifier trained with Landsat imagery and ground-truth data. The result was a classification map boasting an impressive 100% accuracy rate, indicative of the reliability and precision of our approach. Our observations unveiled distinct spatial patterns where various crops, including Rice, Sugarcane, Citrus, Sunflower, and Cereals, flourished, each occupying specific geographic zones dictated by environmental and agronomic factors. The concentrated cultivation of Rice in the Northwest region of the irrigated perimeter, encompassing areas along the province of Kenitra and Sidi Kacem. In contrast, Sugarcane fields dominate the expansive plain flanking both banks of the Oued Sebou River, showcasing the suitability of these areas for this particular crop. Moving further, we noted the cultivation of Citrus orchards across the plain, especially prevalent within the three provinces of the Gharb. These orchards thrive in the region's mild climate and well-drained soils, forming a distinct feature of the agricultural landscape. Sunflower fields, characterized by their vibrant yellow blooms, were found scattered across the northern reaches of the study area. The abundant sunlight and nutrient-rich soils provide optimal conditions for Sunflower cultivation, contributing to the agricultural diversity of the region. Lastly, Cereal crops, including wheat and barley, make their mark in both the northern and southern parts of the perimeter. These crops benefit from cooler temperatures and seasonal rainfall, creating favorable conditions for their growth and contributing to the agricultural mosaic of the Gharb-irrigated perimeter. In summary, our classification analysis not only provides a detailed map of crop distribution but also offers valuable insights into the complex interplay of environmental factors and agricultural practices shaping the Plain of the Gharb-irrigated perimeter.

The bar chart (Figure 5) illustrates the crop area evolution in the Gharb-irrigated perimeter from 2019 to 2022. Our analysis of this temporal crop area evolution within our study area reveals intriguing trends for Rice, Sugarcane, Citrus, Sunflower, and Cereals. Notably, Rice cultivation showed a fluctuation, increasing from 6101.38 hectares in 2019 to 6604 hectares in 2020, declining to 5827.33 hectares in 2021, then rebounding to 7349.56 hectares in 2022. Similarly, Cereals experienced fluctuations, increasing from 1011.76 hectares in 2019 to 9722 hectares in 2020, sharply decreasing in 2021, then rising again in 2022.In contrast, the Sugarcane cultivation saw a general trend of decrease, with areas of 7530.79 hectares in 2019, 6949 hectares in 2020, 5829.37 hectares in 2021, and 4082.92 hectares in 2022. Sugar beet cultivation area increased by 2677.74 hectares from 2019 to 2020 and by 1767.76 hectares from 2020 to 2021 but significantly decreased by 5309.42 hectares in 2022. Meanwhile, Sunflower cultivation area showed a gradual increase, reaching 3703.72 hectares in 2022, after fluctuations from 257.35 hectares in 2019 to 2307 hectares in 2021 and a notable decrease to 844.11 hectares in 2022. Citrus cultivation area remained relatively stable, starting at 12152.41 hectares in 2019, increasing slightly to 12192.57 hectares in 2020, decreasing to 9269 hectares in 2021, rebounding to 11707.43 hectares in 2022, then decreasing again to 8915.32 hectares.

The line graph (Figure 6) outlines Evapotranspiration (ET0), Temperature (T) and Precipitation (P) changes from 2019 to 2022 across the three provinces of the irrigated perimeter of the Gharb: Kenitra, Sidi Kacem, and Sidi Slimane. In Kenitra, precipitation started at 0.54(mm/day) in 2019 and experienced fluctuations over the years, while temperature gradually increased from 16.95°C to 18.66°C in 2022. Sidi Kacem exhibited a similar trend with a slight decrease in precipitation from 0.31 in 2019 to 0.15 in 2022, while temperature increased from 21.97°C to 23.22°C during the same period. Sidi Slimane demonstrated fluctuations as well, with precipitation decreasing from 0.45 in 2019 to 0.21 in 2022, and the temperature gradually rising from 22.07°C to 23.3°C. Evapotranspiration fluctuated, with an increase from 6.717 in 2019 to 8.390 in 2020, followed by a slight decrease to 6.970 in 2021 and a subsequent rise to 7.735 in 2022. Similarly, in Sidi Kacem, evapotranspiration decreased from 11.198 in 2019 to 10.438 in 2020, then increased slightly to 10.953 in 2021 before declining to 9.042 in 2022. In Sidi Slimane, evapotranspiration decreased from 11.554 in 2019 to 10.176 in 2020, increased slightly to 11.004 in 2021, then decreased to 9.310 in 2022. Fluctuations in evapotranspiration (ET0), temperature, and precipitation suggest diverse water demand and climatic conditions across locations. Understanding their relationship is crucial for managing water balance in ecosystems and agriculture, as temperature influences evapotranspiration rates while precipitation restores soil moisture.

9999999The bar graphs represent the crop water requirement (CWR) for different crops in the provinces of Kenitra, Sidi Kacem, and Sidi Slimane between 2019 and 2022. (Figure 7) For the CWR of rice crops in the provinces of Kenitra, Sidi Kacem, and Sidi Slimane over the four-year period. Sidi Slimane consistently shows the highest CWR, followed by Sidi Kacem and Kenitra. Additionally, there's a general decreasing trend in CWR from 2019 to 2022 across all provinces. In Kenitra, the highest CWR value was observed in 2019(3.942mm/day), while the lowest was recorded in 2021(1.828 mm/day), indicating a decrease over the years. Similarly, in Sidi Kacem, the highest CWR was noted in 2019(3.910 mm/day), with the lowest in 2022(1.489 mm/day), showing a consistent decrease over the period. Sidi Slimane exhibited the highest CWR in 2019(5.885) and the lowest in 2022(2.164), indicating a decreasing trend in CWR from 2019 to 2022 across all provinces. For cereals, in Kenitra, the Crop Water Requirement (CWR) was highest in 2019(4.306 mm/day) and lowest in 2021(1.998 mm/day), showing a decrease over the years. In Sidi Kacem, the highest CWR was observed in 2019(4.254 mm/day), while the lowest was recorded in 2022(1.622 mm/day), indicating a decrease over the period. Sidi Slimane exhibited the highest CWR in 2019(6.403 mm/day) and the lowest in 2022(2.358 mm/day), showing a decreasing trend in CWR from 2019 to 2022 across all provinces. Regarding Citrus crops, in Kenitra, the CWR decreased from 2.553 mm/day in 2019 to 1.519 mm/day in 2022. Similarly, in SidiKacem, the CWR decreased from 2.680 mm/day in 2019 to 1.010 mm/day in 2022. In Sidi Slimane, there was also a decrease in CWR from 4.046 mm/day in 2019 to 1.459 mm/day in 2022. Overall, there is a noticeable decline in the CWR for citrus crops across all three provinces over the four-year period. For sugarcane crops, the Crop Water Requirement (CWR) showed a decreasing trend across all three provinces from 2019 to 2022. In Kenitra, the CWR decreased from 4.718 mm/day in 2019 to 2.745 mm/day in 2022. Similarly, in Sidi Kacem, there was a decline in CWR from 4.712 mm/day in 2019 to 1.793 mm/day in 2022. In Sidi Slimane, the CWR also decreased from 7.096 mm/day in 2019 to 2.603 mm/day in 2022. Overall, there is a consistent reduction in the CWR for sugarcane. In summary, the analysis of CWR trends across different crop types and provinces highlights a complex interplay of factors impacting water demand in agricultural regions over time, underscoring the importance of adaptive water management strategies in response to evolving climatic and agricultural conditions.

The bar graph represent the irrigation water requirement (IWR) in cubic meters (m³) for various crops across different years shows distinct patterns (Figure 8). Specifically, for rice crops, a decrease in IWR is evident from 2019 to 2022, with the highest demand recorded in 2019(143,623,494.6 m³) and the lowest in 2021(63,155,873.24 m³) indicating a significant reduction over the period. Cereals, on the other hand, exhibit fluctuations, with a substantial increase in 2020 followed by a notable decrease in 2021, then a slight rise again in 2022, reflecting dynamic trend in water requirements for cereal cultivation. In contrast, sugarcane cultivation demonstrates a decline in IWR over the years, with the highest demand in 2019(213,268,574.7 m³) and the lowest in 2022(47,296,741.61 m³). Similarly, Citrus crops display a consistent decrease in IWR, with the highest demand in 2019(193,876,163.3 m³) and the lowest in 2022(57,674,646.93 m³) over the specified period. These observations underscore the dynamic nature of water demand across different crop types, highlighting potential shifts in agricultural practices, technological advancements, or environmental influences that may impact irrigation needs over time.

This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors / Individuals.

Not applicable.

All relevant data are included in the paper or it’s Supplementary Information.

The authors declare there is no conflict.