A New Upwelling Index for the Moroccan Atlantic Coast for the Period between 1982–2021
Abstract
:1. Introduction
2. Data and Area of Interest
3. Materials and Methods
3.1. Upwelling Extraction
3.1.1. Ekman Preprocessing
3.1.2. Segmentation
3.2. New Upwelling Index
3.2.1. Setup
3.2.2. New Upwelling Index Calculation
3.2.3. , Identification
3.2.4. Ekman Transport Index
3.2.5. Anomalies
- Spatial anomalies are calculated as the difference between the new upwelling index values and its corresponding mean values for each image. A positive spatial anomaly suggests an anomalous increase in upwelling activity for that period. Conversely, a negative spatial anomaly indicates an anomalous decrease in upwelling activity (Figure 7a).
- The temporal anomalies are determined as the difference between the new upwelling index value and its corresponding mean value for each latitude. A positive temporal anomaly suggests an anomalous increase in upwelling activity at a latitude. Conversely, a negative temporal anomaly indicates an anomalous decrease in upwelling activity. This could indicate weaker upwelling or deviations from typical seasonal patterns (Figure 8a).
4. Discussion
4.1. SST Upwelling Index
- The northern area, bounded by N and N, shows the lowest temperatures along the coast throughout the 40-year time series in contrast to what was observed in Figure 5b. These low values are due to the weaker winds and unfavorable coastline orientation in this region (winds are not parallel to the coastline) [2] (Figure 5a and Figure 6).
- Central part between N and N: The giant filament around Cape Ghir is primarily responsible for the increased upwelling index in this zone. In Figure 5b, we notice an absence of upwelling in winter. Our new index (Figure 6) reveals distinct patterns. It indicates the absence of upwelling during winter, and there are also intermittent periods in spring and summer when no upwelling is observed. Notable periods where upwelling is absent are 1989–1997, 2005, 2010–2011, as well as 2013 and 2017.Globally, the in the central part has significant upwelling all year round. In fact, the areas with the greatest intensity values (3 C to 5 C) are noted at N, N, N, and N, respectively, where considerable upwelling filaments have occurred [33]. The focus shifts to the to analyze the interannual and seasonal fluctuation of upwelling intensity (Figure 5a). Globally, the patterns of and show a good relationship. In fact, between April and November of most years, the primary wind pattern favorable to upwelling in the central zone was primarily between latitudes N and N.
- Southern part between N and N: The interannual and seasonal thermal variability of the upwelling indicates that upwelling in this area is generally strong, according to Figure 5b, and remains so throughout the year. However, our analysis reveals that while upwelling is generally stronger in this region, it is not as consistent or intense during all seasons. Indeed, upwelling activity is strong and continuous between N and N throughout the years, with maximum values of , especially from summer to autumn (Figure 6). In contrast, it is absent or average in all winters. The intensity in is greatest from spring to autumn, with temperatures in the south between 3 and 6 degrees Celsius, which corresponds to the strong trade winds that blow near the shore (Figure 5a). The presence of upwelling revealed several intriguing discontinuities, especially near N. Indeed, it is not present every year from June to September (Figure 6). A decrease in the new upwelling index was observed in the years 1990–1996 and 2010–2011, and this can be attributed to the extremely negative values of the North Atlantic Oscillation. Overall, the and models are similar, indicating the effectiveness of assessing upwelling intensity as the radial thermal difference between the minimum and maximum of coastal temperatures.
4.2. Interannual Variability of the Upwelling Dynamics from SST Images
4.3. Interannual Variability of the and Anomalies
5. Conclusions
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Belmajdoub, H.; Minaoui, K.; El Aouni, A.; Hilmi, K.; Saadane, R.; Chehri, A. A New Upwelling Index for the Moroccan Atlantic Coast for the Period between 1982–2021. Remote Sens. 2023, 15, 3459. https://doi.org/10.3390/rs15143459
Belmajdoub H, Minaoui K, El Aouni A, Hilmi K, Saadane R, Chehri A. A New Upwelling Index for the Moroccan Atlantic Coast for the Period between 1982–2021. Remote Sensing. 2023; 15(14):3459. https://doi.org/10.3390/rs15143459
Chicago/Turabian StyleBelmajdoub, Hanae, Khalid Minaoui, Anass El Aouni, Karim Hilmi, Rachid Saadane, and Abdellah Chehri. 2023. "A New Upwelling Index for the Moroccan Atlantic Coast for the Period between 1982–2021" Remote Sensing 15, no. 14: 3459. https://doi.org/10.3390/rs15143459
APA StyleBelmajdoub, H., Minaoui, K., El Aouni, A., Hilmi, K., Saadane, R., & Chehri, A. (2023). A New Upwelling Index for the Moroccan Atlantic Coast for the Period between 1982–2021. Remote Sensing, 15(14), 3459. https://doi.org/10.3390/rs15143459