Your search keyword '"Drifters and floats"' showing total 4 results

1. On the Structure and Kinematics of an Algerian Eddy in the Southwestern Mediterranean Sea

Author

Pierre-Marie Poulain, Luca Centurioni, Tamay Özgökmen, Daniel Tarry, Ananda Pascual, Simon Ruiz, Elena Mauri, Milena Menna, and Giulio Notarstefano

Subjects

southwestern Mediterranean Sea, Algerian eddy, satellite altimetry, drifters and floats, Science

Abstract

An Algerian Eddy, anticyclonic vortex generated by the instability of the Algerian Current in the southwestern Mediterranean Sea, is studied using data provided by drifters (surface currents), Argo floats (temperature and salinity profiles), environmental satellites (absolute dynamic topography maps and ocean color images) and operational oceanography products. The eddy was generated in May 2018 and lasted as an isolated vortex until November 2018. Its morphology and kinematics are described in June–July 2018 when drifters were trapped in its core. During that period, the eddy was slowly moving to the NE (~2 km/day), with an overall diameter of about 200 km (slowly growing with time) and maximal surface swirl velocity of ~50 cm/s at a radius of ~50 km. Geostrophic currents derived from satellite altimetry data compare well with low-pass filtered drifter velocities, with only a slight overestimation, which is expected as its maximum vorticity corresponds to a small Rossby number of ~0.6. Satellite ocean color images and some drifters show that the eddy has an elliptical spiral structure. The looping tracks of the drifters trapped in the eddy were analyzed using two statistical methods: least-squares ellipse fitting and wavelet ridge analysis, revealing a typical eccentricity of about 0.5, a wide range of inclination and a rotation period between 3 and 10 days. Clusters of drifters on the northeastern limb of the eddy were also considered to estimate divergence and vorticity. The results indicate convergence (divergence) and downwelling (upwelling) at scales of 20–50 km near the northeastern (northwestern) edge of the eddy, in agreement with the quasi-geostrophic theory. Vertically, the eddy extends mostly down to 250 m depth, with a warm, low-salinity and low-density signature and with geostrophic currents near 50 cm/s in the top layer (down to ~80 m) reducing to less than 10 cm/s near 250 m. Near the surface, colder water is advected into it.

Published

2021

2. On the structure and kinematics of an Algerian Eddy in the southwestern Mediterranean sea

Author

Office of Naval Research (US), Poulain, Pierre-Marie, Centurioni , Luca Raffaele, Özgökmen, Tamay, Tarry, Daniel R., Pascual, Ananda, Ruiz, Simón, Mauri, Elena, Menna, Milena, Notarstefano, Giulio, Office of Naval Research (US), Poulain, Pierre-Marie, Centurioni , Luca Raffaele, Özgökmen, Tamay, Tarry, Daniel R., Pascual, Ananda, Ruiz, Simón, Mauri, Elena, Menna, Milena, and Notarstefano, Giulio

Abstract

An Algerian Eddy, anticyclonic vortex generated by the instability of the Algerian Current in the southwestern Mediterranean Sea, is studied using data provided by drifters (surface currents), Argo floats (temperature and salinity profiles), environmental satellites (absolute dynamic topography maps and ocean color images) and operational oceanography products. The eddy was generated in May 2018 and lasted as an isolated vortex until November 2018. Its morphology and kinematics are described in June–July 2018 when drifters were trapped in its core. During that period, the eddy was slowly moving to the NE (~2 km/day), with an overall diameter of about 200 km (slowly growing with time) and maximal surface swirl velocity of ~50 cm/s at a radius of ~50 km. Geostrophic currents derived from satellite altimetry data compare well with low-pass filtered drifter velocities, with only a slight overestimation, which is expected as its maximum vorticity corresponds to a small Rossby number of ~0.6. Satellite ocean color images and some drifters show that the eddy has an elliptical spiral structure. The looping tracks of the drifters trapped in the eddy were analyzed using two statistical methods: least-squares ellipse fitting and wavelet ridge analysis, revealing a typical eccentricity of about 0.5, a wide range of inclination and a rotation period between 3 and 10 days. Clusters of drifters on the northeastern limb of the eddy were also considered to estimate divergence and vorticity. The results indicate convergence (divergence) and downwelling (upwelling) at scales of 20–50 km near the northeastern (northwestern) edge of the eddy, in agreement with the quasi-geostrophic theory. Vertically, the eddy extends mostly down to 250 m depth, with a warm, low-salinity and low-density signature and with geostrophic currents near 50 cm/s in the top layer (down to ~80 m) reducing to less than 10 cm/s near 250 m. Near the surface, colder water is advected into it.

Published

2021

3. On the structure and kinematics of an Algerian Eddy in the southwestern Mediterranean sea

Author

Daniel R. Tarry, Simón Ruiz, Pierre-Marie Poulain, Luca Centurioni, Milena Menna, Elena Mauri, Ananda Pascual, Giulio Notarstefano, Tamay M. Özgökmen, and Office of Naval Research (US)

Subjects

010504 meteorology & atmospheric sciences, Science, Temperature salinity diagrams, 01 natural sciences, Physics::Geophysics, Geostrophic current, Physics::Fluid Dynamics, Downwelling, Algerian eddy, Satellite altimetry, southwestern Mediterranean Sea, Argo, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, Drifters and floats, 010505 oceanography, Ocean current, Vorticity, Geodesy, satellite altimetry, Southwestern Mediterranean sea, Ocean surface topography, Drifter, General Earth and Planetary Sciences, Geology, drifters and floats

Abstract

This article belongs to the Special Issue Observing the Flow of Ocean Currents and Circulation Using Remote Sensing., An Algerian Eddy, anticyclonic vortex generated by the instability of the Algerian Current in the southwestern Mediterranean Sea, is studied using data provided by drifters (surface currents), Argo floats (temperature and salinity profiles), environmental satellites (absolute dynamic topography maps and ocean color images) and operational oceanography products. The eddy was generated in May 2018 and lasted as an isolated vortex until November 2018. Its morphology and kinematics are described in June–July 2018 when drifters were trapped in its core. During that period, the eddy was slowly moving to the NE (~2 km/day), with an overall diameter of about 200 km (slowly growing with time) and maximal surface swirl velocity of ~50 cm/s at a radius of ~50 km. Geostrophic currents derived from satellite altimetry data compare well with low-pass filtered drifter velocities, with only a slight overestimation, which is expected as its maximum vorticity corresponds to a small Rossby number of ~0.6. Satellite ocean color images and some drifters show that the eddy has an elliptical spiral structure. The looping tracks of the drifters trapped in the eddy were analyzed using two statistical methods: least-squares ellipse fitting and wavelet ridge analysis, revealing a typical eccentricity of about 0.5, a wide range of inclination and a rotation period between 3 and 10 days. Clusters of drifters on the northeastern limb of the eddy were also considered to estimate divergence and vorticity. The results indicate convergence (divergence) and downwelling (upwelling) at scales of 20–50 km near the northeastern (northwestern) edge of the eddy, in agreement with the quasi-geostrophic theory. Vertically, the eddy extends mostly down to 250 m depth, with a warm, low-salinity and low-density signature and with geostrophic currents near 50 cm/s in the top layer (down to ~80 m) reducing to less than 10 cm/s near 250 m. Near the surface, colder water is advected into it., This research was mainly funded by the US Office of Naval Research (ONR) as part of the CALYPSO Departmental Research Initiative through grants N00014-18-1-2418 and N00014-18-1-2138. LC and the SVP drifters were funded by ONR grants N00014-17-1-2517 and N00014-19-1-269. D.T., A.P. and S.R. were funded by ONR grant N00014-16-1-3130.

Published

2021

4. On the Structure and Kinematics of an Algerian Eddy in the Southwestern Mediterranean Sea.

Author

Poulain, Pierre-Marie, Centurioni, Luca, Özgökmen, Tamay, Tarry, Daniel, Pascual, Ananda, Ruiz, Simon, Mauri, Elena, Menna, Milena, and Notarstefano, Giulio

Subjects

*KINEMATICS, *GEOSTROPHIC currents, *ROSSBY number, *EDDIES, *OCEANOGRAPHIC maps, *OCEAN color, *WATER currents

Abstract

An Algerian Eddy, anticyclonic vortex generated by the instability of the Algerian Current in the southwestern Mediterranean Sea, is studied using data provided by drifters (surface currents), Argo floats (temperature and salinity profiles), environmental satellites (absolute dynamic topography maps and ocean color images) and operational oceanography products. The eddy was generated in May 2018 and lasted as an isolated vortex until November 2018. Its morphology and kinematics are described in June–July 2018 when drifters were trapped in its core. During that period, the eddy was slowly moving to the NE (~2 km/day), with an overall diameter of about 200 km (slowly growing with time) and maximal surface swirl velocity of ~50 cm/s at a radius of ~50 km. Geostrophic currents derived from satellite altimetry data compare well with low-pass filtered drifter velocities, with only a slight overestimation, which is expected as its maximum vorticity corresponds to a small Rossby number of ~0.6. Satellite ocean color images and some drifters show that the eddy has an elliptical spiral structure. The looping tracks of the drifters trapped in the eddy were analyzed using two statistical methods: least-squares ellipse fitting and wavelet ridge analysis, revealing a typical eccentricity of about 0.5, a wide range of inclination and a rotation period between 3 and 10 days. Clusters of drifters on the northeastern limb of the eddy were also considered to estimate divergence and vorticity. The results indicate convergence (divergence) and downwelling (upwelling) at scales of 20–50 km near the northeastern (northwestern) edge of the eddy, in agreement with the quasi-geostrophic theory. Vertically, the eddy extends mostly down to 250 m depth, with a warm, low-salinity and low-density signature and with geostrophic currents near 50 cm/s in the top layer (down to ~80 m) reducing to less than 10 cm/s near 250 m. Near the surface, colder water is advected into it. [ABSTRACT FROM AUTHOR]

Published

2021