La salinité de la couche de surface océanique dans l'océan atlantique tropical : variabilités saisonnière à interannuelle

Pour étudier la variabilité de la salinité de surface (SSS) dans l'océan Atlantique tropical aux échelles de temps saisonnières à interannuelles, nous avons utilisé des observations in-situ et satellitaires et des résultats de la modélisation océanique. Nous avons montré que la densité et la qualité des observations disponibles permettent de calculer le bilan de sel dans la couche de mélange dans le bassin Atlantique tropical. Ce bilan de sel de la couche de mélange est beaucoup plus sensible aux courants de surface qu'aux flux d'eau douce. Les mécanismes qui modulent la variabilité de la SSS dans l'Atlantique tropical et plus spécifiquement dans la région du Golfe de Guinée ont été déterminés. Il ressort qu'à l'ouest et au nord-est du bassin tropical, la variabilité saisonnière de la SSS est pilotée par l'advection et les flux d'eau douce alors qu'au centre du bassin, c'est principalement les flux d'eau douce qui contrôlent le bilan de sel. Par contre, dans le Golfe de Guinée, les flux d'eau douce ne jouent pas un grand rôle dans le bilan de sel, le cycle saisonnier de la SSS résultant en un équilibre entre les processus verticaux (advection et diffusion) qui augmentent la SSS et l'advection horizontale qui la diminue. La variabilité interannuelle de la SSS étudiée spécifiquement dans le Golfe de Guinée révèle que, dans les régions nord et équatoriale, les changements de SSS sont dus à des changements des précipitations et d'évaporation et les changements dans les processus océaniques (advection et diffusion verticale). Au sud de ces régions, seuls les changements dans les processus océaniques peuvent expliquer les anomalies de SSS. On a observé une salinisation au nord-est du Golfe de Guinée durant la période 2002-2009 qui résulte principalement d'une diminution des pluies dans la région. Enfin, nous avons montré que les fleuves ont pour rôle d'amplifier le signal de la SSS et qu'ils ont un impact sur la profondeur de la couche de mélange, les courants de surface et la température de surface de la mer.The objective of this thesis is to study the variability of the ocean sea surface salinity (SSS) in the tropical Atlantic Ocean, at seasonal and interannual time scales. To achieve this, we used in-situ and satellite data as well as results of ocean models. We have shown that the density and the quality of the available observations allows us to approach the salinity balance in the mixed-layer in the whole tropical Atlantic basin and mixed-layer salinity balance is more sensitive to currents than to freshwater flux. We investigate the main mechanisms which modulate the variability of the SSS in the tropical Atlantic and especially in the Gulf of Guinea.In the western and north-eastern tropical Atlantic Ocean, the seasonal variability of SSS is controlled by advection and freshwater flux whereas, in the central basin, the salinity balance is mostly due to freshwater flux. In the Gulf of Guinea, freshwater flux does not play a key role as in previous regions and the seasonal cycle of SSS is a balance between the vertical processes (advection and diffusion) that increase SSS and the horizontal advection which decrease the SSS. We focus our analysis of SSS interannual variability in the Gulf of Guinea. Results indicate that in the northern region and in the equatorial region, SSS changes are due to changes in precipitations and evaporation and changes in oceanic processes (advection and vertical diffusion) while in the southern Gulf of Guinea only oceanic process changes can explain SSS anomalies. We noted an SSS increase in the northeastern Gulf of Guinea during the period 2002-2009. We argue that it is due mainly to decrease precipitation in this region. Finally, we also showed that the effect of the runoff is to amplify the signal of SSS and can impact the mixed layer depth, the surface currents and the sea surface temperature

Impact of Stratospheric Geoengineering on Sea Surface Temperature in the Northern Gulf of Guinea

Among techniques proposed to limit global warming, there is Stratospheric Aerosol Geoengineering (SAG) which is aiming to increase Earth-atmosphere albedo by injecting sulfur dioxide into the stratosphere in order to reduce the solar radiation that reaches the earth. This study aims to assess the potential impact of SAG on Sea Surface Temperature (SST) in the Northern Gulf of Guinea and its causes using GLENS (Geoengineering Large Ensemble) simulations performed under a high anthropogenic emission scenario (RCP8.5). Here, we focus on two dynamically different regions: Sassandra Upwelling in Côte d’Ivoire (SUC, located east of Cape Palmas) and Takoradi Upwelling in Ghana (TUG, located east of Cape Three Points). Results show that in the SUC region, under climate change, there is an increase in SST (referred to as the current climate) all year long (by 1.52 °C on average) mainly due to an increase in net heat flux (lead by the decrease in longwave radiation) and also in weak vertical mixing (caused by strong stratification which dominates the vertical shear). Under SAG, SST decreases all the seasonal cycle with its maximum in December (−0.4 °C) due to a reduction in the net heat flux (caused by a diminution of solar radiation) and an increase in vertical advection (due to an increase in vertical temperature gradient and vertical velocity). In the TUG region, under climate change, SST warming is a little more intense than in the SUC region and SST changes are driven by an increase in the net heat flux and strong stratification. The cooling of the SST in TUG is similar to the SUC region, but contrary to this region, the cooling under SAG is not only explained by a decrease in the net heat flux but also by the remote forcing of wind changes at the western equatorial Atlantic

Influence on electron coherence from quantum electromagnetic fields in the presence of conducting plates

The influence of electromagnetic vacuum fluctuations in the presence of the perfectly conducting plate on electrons is studied with an interference experiment. The evolution of the reduced density matrix of the electron is derived by the method of influence functional. We find that the plate boundary anisotropically modifies vacuum fluctuations that in turn affect the electron coherence. The path plane of the interference is chosen either parallel or normal to the plate. In the vicinity of the plate, we show that the coherence between electrons due to the boundary is enhanced in the parallel configuration, but reduced in the normal case. The presence of the second parallel plate is found to boost these effects. The potential relation between the amplitude change and phase shift of interference fringes is pointed out. The finite conductivity effect on electron coherence is discussed.Comment: 29 pages, 3 figure

Classical limit of the Casimir entropy for scalar massless field

We study the Casimir effect at finite temperature for a massless scalar field in the parallel plates geometry in N spatial dimensions, under various combinations of Dirichlet and Neumann boundary conditions on the plates. We show that in all these cases the entropy, in the limit where energy equipartitioning applies, is a geometrical factor whose sign determines the sign of the Casimir force.Comment: 14 page

Temperature inversion symmetry in the Casimir effect with an antiperiodic boundary condition

We present explicitly another example of a temperature inversion symmetry in the Casimir effect for a nonsymmetric boundary condition. We also give an interpretation for our result.Comment: 4 page

Horava-Lifshitz modifications of the Casimir effect

We study the modifications induced by spacetime anisotropy on the Casimir effect in the case of two parallel plates. Nonperturbative and perturbative regimes are analyzed. In the first case the Casimir force either vanishes or it reverses its direction which, in any case, makes the proposal untenable. On the other hand, the perturbative model enables us to incorporate appropriately the effects of spacetime anisotropy.Comment: 6 pages, revtex

Stochastic Lorentz forces on a point charge moving near the conducting plate

The influence of quantized electromagnetic fields on a nonrelativistic charged particle moving near a conducting plate is studied. We give a field-theoretic derivation of the nonlinear, non-Markovian Langevin equation of the particle by the method of Feynman-Vernon influence functional. This stochastic approach incorporates not only the stochastic noise manifested from electromagnetic vacuum fluctuations, but also dissipation backreaction on a charge in the form of the retarded Lorentz forces. Since the imposition of the boundary is expected to anisotropically modify the effects of the fields on the evolution of the particle, we consider the motion of a charge undergoing small-amplitude oscillations in the direction either parallel or normal to the plane boundary. Under the dipole approximation for nonrelativistic motion, velocity fluctuations of the charge are found to grow linearly with time in the early stage of the evolution at the rather different rate, revealing strong anisotropic behavior. They are then asymptotically saturated as a result of the fluctuation-dissipation relation, and the same saturated value is found for the motion in both directions. The observational consequences are discussed. plane boundary. Velocity fluctuations of the charge are found to grow linearly with time in the early stage of the evolution at the rate given by the relaxation constant, which turns out to be smaller in the parallel case than in the perpendicular one in a similar configuration. Then, they are asymptotically saturated as a result of the fluctuation-dissipation relation. For the electron, the same saturated value is obtained for motion in both directions, and is mainly determined by its oscillatory motion. Possible observational consequences are discussed.Comment: 33 pages, 2 figure

Joint observation-model mixed-layer heat and salt budgets in the eastern tropical Atlantic

In this study, we use a joint observation-model approach to investigate the mixed-layer heat and salt annual mean and seasonal budgets in the eastern tropical Atlantic. The regional PREFCLIM observational climatology provides the budget terms with a relatively low spatial and temporal resolution compared to the online NEMO model, and this later is then re-sampled as in PREFCLIM climatology. In addition, advection terms are recomputed offline from the model as PREFCLIM gridded advection computation. In Senegal, Angola and Benguela regions, the seasonal cycle of mixed-layer temperature is mainly governed by surface heat fluxes; however, it is essentially driven by vertical heat diffusion in Equatorial region. The seasonal cycle of mixed-layer salinity is largely controlled by freshwater flux in Senegal and Benguela regions; however, it follows the variability of zonal and meridional salt advection in Equatorial and Angola regions respectively. Our results show that the time-averaged spatial distribution of NEMO offline heat/salt advection terms compares much better to PREFCLIM horizontal advection terms than the online heat/salt advection terms. However, the seasonal cycle of horizontal advection in selected regions shows that NEMO offline terms do not always compare well with PREFCLIM, sometimes less than online terms. Despite this difference, these results suggest the important role of small scale variability in mixed-layer heat and salt budgets.</p

Thermofield Dynamics and Casimir Effect for Fermions

A generalization of the Bogoliubov transformation is developed to describe a space compactified fermionic field. The method is the fermionic counterpart of the formalism introduced earlier for bosons (J. C. da Silva, A. Matos Neto, F. C. Khanna and A. E. Santana, Phys. Rev. A 66 (2002) 052101), and is based on the thermofield dynamics approach. We analyse the energy-momentum tensor for the Casimir effect of a free massless fermion field in a $d$-dimensional box at finite temperature. As a particular case the Casimir energy and pressure for the field confined in a 3-dimensional parallelepiped box are calculated. It is found that the attractive or repulsive nature of the Casimir pressure on opposite faces changes depending on the relative magnitude of the edges. We also determine the temperature at which the Casimir pressure in a cubic boc changes sign and estimate its value when the edge of the cybe is of the order of confining lengths for baryons.Comment: 21 pages, 3 figures, to appear in Annals of Physic

A thick shell Casimir effect

We consider the Casimir energy of a thick dielectric-diamagnetic shell under a uniform velocity light condition, as a function of the radii and the permeabilities. We show that there is a range of parameters in which the stress on the outer shell is inward, and a range where the stress on the outer shell is outward. We examine the possibility of obtaining an energetically stable configuration of a thick shell made of a material with a fixed volume