Your search keyword '"Oruba, Ludivine"' showing total 8 results

1. On the role of thermal boundary conditions in dynamo scaling laws

Author

Oruba, Ludivine

Subjects

Physics - Fluid Dynamics

Abstract

In dynamo power-based scaling laws, the power $P$ injected by buoyancy forces is measured by a so-called flux-based Rayleigh number, denoted as ${\rm Ra}_Q^*$ (see Christensen and Aubert, 2006). Whereas it is widely accepted that this parameter is measured (as opposite to controlled) in dynamos driven by differential heating, the literature is much less clear concerning its nature in the case of imposed heat flux. We clarify this issue by highlighting that in that case, the ${\rm Ra}_{Q}^*$ parameter becomes controlled only in the limit of large Nusselt numbers (${\rm Nu} \gg 1$). We then address the issue of the robustness of the original relation between $P$ and ${\rm Ra}_Q^*$ with the geometry and the thermal boundary conditions. We show that in the cartesian geometry, as in the spherical geometry with a central mass distribution, this relation is purely linear, in both differential and fixed-flux heating. However, we show that in the geometry commonly studied by geophysicists (spherical with uniform mass distribution), its validity places an upper-bound on the strength of the driving which can be envisaged in a fixed Ekman number simulation. An increase of the Rayleigh number indeed yields deviations (in terms of absolute correction) from the linear relation between $P$ and ${\rm Ra}_Q^*$. We conclude that in such configurations, the parameter range for which $P$ is controlled is limited., Comment: 14 pages, 3 figures

Published

2016

2. Eye Formation and Energetics in a Dry Model of Hurricane-Like Vortices.

Author

Dormy, Emmanuel, Oruba, Ludivine, and Emanuel, Kerry

Subjects

*WHIRLWINDS, *BUOYANCY, *HEAT engines, *BOUNDARY layer (Aerodynamics), *HEAT flux, *TROPICAL cyclones

Abstract

We investigate the mechanism for eye formation in hurricane-like vortices, using a formulation adapted from Oruba, Davidson, and Dormy. Numerical simulations are performed using an axisymmetric model of dry rotating Rayleigh–Bénard convection under the Boussinesq approximation. The fluxes of heat and momentum at the sea surface are described using the bulk aerodynamic formula. A simplified model for radiative cooling is also implemented. We find that the mechanism for eye formation introduced in Oruba et al., relying on vorticity stripping from the boundary layer, is robust in dry hurricane-like vortices. Furthermore, with these boundary conditions, the structure of the flow is closer to the flow of actual tropical cyclones. The applicability of this mechanism to the moist case however remains uncertain and deserves further study. Finally, energy budgets, obtained either by a heat engine approach or by a direct estimation of the work of buoyancy forces, are investigated. They provide estimations of the surface wind speed as a function of the controlling parameters. Significance Statement: Tropical cyclones (also known as hurricanes or typhoons, depending on their location) are life-threatening and devastating atmospheric vortices. Their impact worsens with sea level rise and increasing coastal population. Here, we explore, using idealized models, the physics behind the formation of an eye (the quiet and typically clear region at the center of these storms). We then investigate the controlling parameters for the amplitude of the strongest winds in the model, using energy constraints, and compare them to what is observed in actual tropical cyclones. [ABSTRACT FROM AUTHOR]

Published

2024

3. Impact of the Sea Surface Temperature in the North‐Eastern Tropical Atlantic on Precipitation Over Senegal.

Author

Thiam, Mamadou, Oruba, Ludivine, de Coetlogon, Gaelle, Wade, Malick, Diop, Bouya, and Farota, Abdou Karim

Subjects

OCEAN temperature, MESOSCALE convective complexes, INTERTROPICAL convergence zone, ATMOSPHERIC temperature, ATMOSPHERIC pressure

Abstract

This study examines 40 years of monthly precipitation data in Senegal (1979–2018) using Climatic Research Unit observations and ERA5 reanalyzes, aiming to understand the influence of oceanic and atmospheric factors on Senegal's precipitation in July, August and September (JAS). The variability of Senegal's precipitation is first compared with that of the broader Sahel region: although they share a significant portion of their variance, Senegal appears more closely related to the Northeastern Tropical Atlantic (NETA) Sea Surface Temperature (SST). A detailed examination of this region reveals that Senegal's increased precipitation is linked to the northward shift of the InterTropical Convergence Zone, consistent with numerous previous studies. Over the continent, this shift corresponds to a northward shift of the African Easterly Jet (AEJ) and, consequently, the mesoscale convective systems (MCSs) responsible for most precipitation. It seems primarily driven by the northward shift of the Heat Low. Over the ocean just west of Senegal, there is a comparable shift of the AEJ, accompanied by an increase in low‐level moisture transport convergence within the West African Westerly Jet (WAWJ) which explains the majority of the increase in JAS precipitation in Senegal. This phenomenon is triggered by a negative pressure anomaly in the NETA, located above a positive SST anomaly: we suggest that the latter is the origin of the former, forming a feedback mechanism that potentially significantly influences Senegal's precipitation. The mechanism involves a geostrophic adjustment of the WAWJ to the southern gradients of the SST anomaly. Plain Language Summary: This study, spanning 40 years of monthly precipitation data in Senegal, explores the intricate relationship between oceanic and atmospheric factors shaping precipitation patterns from July to September. The increased summertime precipitation in the Western Sahel is primarily of continental origin, associated with the northward shift of mesoscale convective systems linked to lower pressure in the Sahara. However, over the ocean west of Senegal, there is also an increase in inland moisture transport that explains a significant part of the intensified precipitation from July to September in Senegal. This transport is reinforced by a low‐pressure system over the ocean, potentially caused by warmer sea surface temperatures between 10°N and 20°N off West Africa. This close connection between Senegal's precipitation and ocean surface temperature in the Northeastern Tropical Atlantic could help enhance crucial seasonal forecasts for agricultural planning, the economy, and food security in West Africa. Key Points: Wet summers in Senegal are preceded by La Niña events and warming in the Mediterranean but also by warming in the Northeastern Tropical AtlanticMoisture transport convergence within a stronger West African Westerly Jet (WAWJ) explains this increase in precipitationFeedback between the North Tropical Atlantic surface temperature and atmospheric pressure is proposed to explain this WAWJ acceleration [ABSTRACT FROM AUTHOR]

Published

2024

4. Equatorial symmetry breaking and the loss of dipolarity in rapidly rotating dynamos.

Author

Garcia, Ferran, Oruba, Ludivine, and Dormy, Emmanuel

Subjects

*ELECTRIC generators, *SYMMETRY breaking, *HYDRODYNAMICS

Abstract

Numerical studies of convection driven dynamos in rotating spherical shells exhibit a transition from steady dipolar to reversing multipolar dynamos as the forcing is increased. The dipolar-multipolar transition has so far been characterized using purely hydrodynamic parameters (Christensen and Aubert, Geophys. J. Int. 2006, 166, 97-114, Soderlund et al., Earth Planet. Sci. Lett. 2012, 333-334, 9-20, Oruba and Dormy, Geophys. Res. Lett. 2014, 41, 7115-7120). Motivated by these earlier descriptions, we investigate the hydrodynamic transitions occurring at the critical parameters. We show that the loss of dipolarity in dynamos is associated with a purely hydrodynamic transition, characterized by a breaking of the flow equatorial symmetry. Contrary to earlier expectations, we show by varying the Prandtl number that the transition is not necessarily associated with a degradation of the flow helicity. [ABSTRACT FROM AUTHOR]

Published

2017

5. Transition between viscous dipolar and inertial multipolar dynamos.

Author

Oruba, Ludivine and Dormy, Emmanuel

Published

2014

6. Understanding the Regeneration Stage Undergone by Surface Cyclones Crossing a Midlatitude Jet in a Two-Layer Model.

Author

Rivière, Gwendal, Gilet, Jean-Baptiste, and Oruba, Ludivine

Subjects

CYCLONES, BAROCLINICITY, KINETIC energy, SHEAR flow, POTENTIAL energy

Abstract

The present paper provides a rationale for the regeneration stage undergone by surface cyclones when they cross a baroclinic jet from its anticyclonic-shear (warm) side to its cyclonic-shear (cold) side in a two-layer quasigeostrophic model. To do so, the evolution of finite-amplitude synoptic cyclones in various baroclinic zonal flows is analyzed. Baroclinic zonal flows with uniform horizontal shears are first considered. While the anticyclonic shear allows a much more efficient and sustainable extraction of potential energy than the cyclonic shear, the growth of the lower-layer eddy kinetic energy (EKE) is shown to be highly dependent on the choice of the parameter values. An increased vertical shear leads to a more rapid EKE increase in the anticyclonic shear than in the cyclonic shear whereas increasing the vertically averaged potential vorticity gradient or the barotropic shear stabilizes the EKE more in the former shear than in the latter. Finally, vertical velocities arising from the nonlinear interaction between synoptic cyclones are shown to favor EKE growth in the cyclonic shear rather than in the anticyclonic one. The evolution of cyclones initialized on the warm side of a meridionally confined baroclinic jet is then investigated. The lower-layer cyclone crosses the jet axis and undergoes two distinct growth stages. The first growth stage results from the classical baroclinic interaction and is mainly driven by linear interaction between the cyclones and the jet. The second growth stage is mainly a nonlinear process. It is triggered by the vertical velocities created by the three-dimensional structure of the cyclonic disturbances when they reach the cyclonic side of the jet. [ABSTRACT FROM AUTHOR]

Published

2013

7. On the Poleward Motion of Midlatitude Cyclones in a Baroclinic Meandering Jet.

Author

Oruba, Ludivine, Lapeyre, Guillaume, and Rivière, Gwendal

Subjects

*CYCLONES, *BAROCLINICITY, *METEOROLOGICAL research, *STORMS, *ANTICYCLONES

Abstract

The motion of surface depressions evolving in a background meandering baroclinic jet is investigated using a two-layer quasigeostrophic model on a beta plane. Synoptic-scale finite-amplitude cyclones are initialized in the lower and upper layer to the south of the jet in a configuration favorable to their baroclinic interaction. The lower-layer cyclone is shown to move across the jet axis from its warm-air to cold-air side. It is the presence of a poleward-oriented barotropic potential vorticity (PV) gradient that makes possible the cross-jet motion through the beta-drift mechanism generalized to a baroclinic atmospheric context. The potential vorticity gradient associated with the jet is responsible for the dispersion of Rossby waves by the cyclones and the development of an anticyclonic anomaly in the upper layer. This anticyclone forms a PV dipole with the upper-layer cyclone that nonlinearly advects the lower-layer cyclone across the jet. In addition, the background deformation is shown to modulate the cross-jet advection. Cyclones evolving in a deformation-dominated environment (south of troughs) are strongly stretched while those evolving in a rotation-dominated environment (south of ridges) remain quasi isotropic. It is shown that the more stretched cyclones trigger a more efficient dispersion of energy, create a stronger upper-layer anticyclone, and move perpendicularly to the jet faster than the less stretched ones. Both the intensity and location of the upper-layer anticyclone explain the distinct cross-jet speeds. A statistical study consisting in initializing cyclones at different locations south of the jet core confirms that the cross-jet motion is faster for the more meridionally elongated cyclones evolving in areas of strongest barotropic PV gradient. [ABSTRACT FROM AUTHOR]

Published

2013

8. On the Northward Motion of Midlatitude Cyclones in a Barotropic Meandering Jet.

Author

Oruba, Ludivine, Lapeyre, Guillaume, and Rivière, Gwendal

Subjects

*CYCLONES, *ROSSBY waves, *ANTICYCLONES, *ATMOSPHERIC pressure, *DYNAMIC meteorology

Abstract

The combined effects of the deformation (horizontal stretching and shearing) and nonlinearities on the beta drift of midlatitude cyclones are studied using a barotropic quasigeostrophic model on the beta plane. It is found that, without any background flow, a cyclonic vortex moves more rapidly northward when it is initially strongly stretched along a mostly north-south direction. This meridional stretching is more efficient at forming an anticyclone to the east of the cyclone through Rossby wave radiation. The cyclone-anticyclone couple then forms a nonlinear vortex dipole that propagates mostly northward. The case of a cyclone embedded in uniformly sheared zonal flows is then studied. A cyclone evolving in an anticyclonic shear is stretched more strongly, develops a stronger anticyclone, and moves faster northward than a cyclone embedded in a cyclonic shear, which remains almost isotropic. Similar results are found in the general case of uniformly sheared nonzonal flows. The evolution of cyclones is also investigated in the case of a more realistic meandering jet whose relative vorticity gradient creates an effective beta and whose deformation field is spatially varying. A statistical study reveals a strong correlation among the cyclone's stretching, the anticyclone strength, and the velocity toward the jet center. These different observations agree with the more idealized cases. Finally, these results provide a rationale for the existence of preferential zones for the jet-crossing phase: that is, the phase when a cyclone crosses a jet from its anticyclonic to its cyclonic side. [ABSTRACT FROM AUTHOR]

Published

2012