Figure 1
The Sergipe and Alagoas Continental Shelf with the 50, 1000 and 2000 m isobaths. The locations of the Japaratuba and Sao Francisco submarine canyons, the river discharge locations, the Sao Francisco, Vaza Barris and Sergipe rivers, and the location of the PCM-9 platform are also represented.
Figure 2
Domain of the numerical model with the local bathymetry. The dashed lines indicate the 3 sections near the Japaratuba canyon, one parallel to the coast and 2 others at the south and north borders of the canyon, in the cross-shore direction.
Figure 3
Wind rose representing the time series of the wind from March 9, 2012 until December 12, 2014, in the oil platform PCM-9. The wind velocity is in m.s-1. The wind rose was created using the original data without any filtering process.
Figure 4
The velocity vectors at the depths of 10, 100, 200 and 300 meters (panels A, B, C and D, respectively), considering Northeast wind as forcing.
Figure 5
Velocity parallel to the coast at the South (panel A) and the North (panel B) of the Japaratuba canyon (North and South sections from Figure 2), for simulations with NE winds. Positive velocity going to NE and negative velocity going to SW
Figure 6
The velocity vectors near the Japaratuba canyon (between North and South sections from Figure 2) at the depths of 10, 100, 200 and 300 meters (panels A, B, C and D, respectively) for Northeast Wind simulation and homogeneous temperature and salinity fields (experiment C1).
Figure 7
The velocity component perpendicular to the coast at the vertical section of the canyon (positive values indicate subsidence, negative values indicate upward motion) for Northeast wind simulation for homogeneous temperature and salinity fields (experiment C1).
Figure 8
The velocity vectors at the depths of 10, 100, 200 and 300 meters (panels A, B, C and D, respectively), considering Southeast winds as forcing.
Figure 9
Velocity parallel to the South (panel A) and to the North (panel B) of the Japaratuba canyon (North and South sections from Figure 2), for simulations with SE winds. Positive velocity going to NE and negative velocity going to SW.
Figure 10
Circulation around Japaratuba canyon at depths (between North and South sections from Figure 2) 10, 100, 200 and 300 meters (panels A, B, C and D, respectively), for Southeast winds simulation.
Figure 11
Velocity perpendicular to the vertical section of the canyon (positive values indicate subsidence, negative values indicate downward motion) for southeast simulation.
Figure 12
Volume flow perpendicular to the section of Japaratuba canyon (positive values indicate subsidence, negative values indicate upward motion), for NE, E, SE and S winds simulations and homogeneous temperature and salinity fields (experiments C1 to C4), integrated every 50m.
Figure 13
Velocity perpendicular to the vertical section of the canyon (positive values indicate subsidence, negative values indicate downward motion) for the simulation without wind (experiment NW).
Figure 14
Volume flow perpendicular to the section of Japaratuba canyon (positive values indicate subsidence, negative values indicate upward motion), for NE, E, SE and S winds simulations (experiments C5 to C8) and without wind (experiment NW) with stratified temperature and salinity fields, integrated every 50 m.
Figure 15
Incidence angle of average wind (a), Volume flow in the canyon section (b), intensity of average wind (c), and the wind rose (d), in the simulation for March 2014 (experiment R1).
Figure 16
Incidence angle of average wind (a), Volume flow in the canyon section (b), intensity of average wind (c), and the wind rose (d), in the simulation for July 2014 (experiment R2).
Figure 17
Incidence angle of average wind (a), Volume flow in the canyon section (b), intensity of average wind (c), and the wind rose (d), in the simulation for September 2014 (experiment R3).