Energy balance and time-scales of mixing and stratification in the Jaboatão estuary, NE-Brazil

Estuarine systems undergo different physical processes that simultaneously control their stratification and mixing dynamics. This energy balance determines both, the estuarine hydrodynamics and the dynamics of water. This article presents a quantitative and comparative analyses between the forces maintaining stratification (surface heating; rainfall precipitation; and differential advection of the longitudinal density gradient due to the vertical velocity field) and those responsible for the vertical mixing (mechanical stirring of bottom tidal stress; mechanical stirring ofsurface wind stress; and surface evaporation) in the lower estuary ofthe Jaboatão River (JE), Pemambuco, NE-Brazil. The energy available to mix the water column at the' lower Jaboatão was 2.2 and 2.0-fold greater than that available to promote stratification, during the dry and rainy seasons, respectively. The bottom shear turbulence caused by the tides was the major source of energy for the vertical mixing. A theoretical analyses revealed that the turbulence decay time-scale io both seasons was much greater (dry=29min; rainy=25 min) than the stratification time-scale (dry=8 mio; rainy=7 min) and than the slack water time-scale (15 min). Thus the estuary was vertically well-mixed even during slack water periods during both, dry and rainy seasons. Theoretical results were confirmed by field data and are in agreement with earlier numerical simulations.Sistemas estuarinos estão sujeitos à influência simultânea de processos fisicos que controlam tanto sua dinâmica de estratificação quanto de mistura. Este balanço energético determina seu comportamento hidrodinâmico e a dinâmica das propriedades da água. O presente artigo apresenta uma análise quantitativa e comparativa das forças de manutenção da estratificação (aquecimento superficial; precipitação pluviométrica e advecção diferencial do gradiente longitudinal da densidade devida ao campo vertical da velocidade), e daquelas responsáveis pela mistura vertical (turbulência de fimdo devido às marés; turbulência de superficie devida à ação dos ventos e evaporação superficial) no baixo estuário do Rio Jaboatão (JE), Pemambuco, NE-Brasil. A quantidade de energia disponível para misturar a coluna d'água foi 2,2 e 2 vezes maior que aquela disponível para manter a estratificação durante as estações seca e chuvosa, respectivamente. O atrito turbulento de fimdo pelas marés foi a principal fonte de energia do sistema para a mistura da coluna d'água. Uma análise teórica revelou que a escala de tempo para o decaimento turbulento nas duas estações sazonais foi superior (seca=29 min; chuvosa=25min) que a escala de tempo para estratificação (seca=8min; chuvosa=7 min) e que a escala de tempo dos estofos de maré (15 min). Assim, o estuário apresentou-se verticalmente bem misturado mesmo durante os estofos de preamar e baixa-mar tanto na estação seca quanto chuvosa. Os resultados teóricos foram confirmados pelos dados de campo e estão em concordância com aqueles obtidos em estudos prévios de simulação numériCa

Seasonal changes in the mixed and barrier layers in the western Equatorial Atlantic

O clima está fortemente relacionado com a dinâmica da camada superficial do Atlântico tropical e com as trocas entre esta e a atmosfera, e a previsão do tempo melhorará à medida em que ganhemos um melhor entendimento dos processos que governam a distribuição relativa das propriedades termodinâmicas na coluna d'água. O presente trabalho focaliza o isolamento das águas quentes superficiais das águas frias profundas pela camada de barreira (CB) induzida pela salinidade no Atlântico Equatorial Oeste (3ºS-7ºN; 40º-52ºW), com base em 487 perfis de CTD (REVIZEE - 1995-2001). O principal processo que contribue para a formação sazonal da CB é a descarga fluvial de águas doces do rio Amazonas. Durante o final do inverno/primavera boreal (Mar-Mai; alta descarga), prevalecem camadas isotérmica (Z T) e de mistura (Z M) mais profundas e a formação de uma CB com 16m de espessura foi governada pelo estabelecimento de uma forte picnoclina induzida pela salinidade, no interior da camada isotérmica. Entretanto, durante o outono boreal (Out-Dez; baixa descarga), estratificações em densidade foram principalmente controladas pela distribuição de temperatura (Z M m Z T; ECB = Z M - Z T m 0). Embora não tenha registrado uma CB sobre a plataforma Amazônica, uma CB máxima (40m) foi formada próxima à quebra da plataforma a 45°W.Climate is closely related to the dynamics of the surface layer of the tropical Atlantic and the exchange between this latter and the atmosphere, and wearther forecasting will improve with increasing understanding of the processes that govern the relative distribution of thermodynamic properties of the water column. This paper focuses on the isolation of warm surface waters from the cold ones of the deep ocean by a salinity induced barrier layer (BL) in the western equatorial Atlantic (3ºS-7ºN; 40º-52ºW), based on 487 CTD profiles (REVIZEE - 1995-2001). The main process contributing to the seasonal BL formation is the discharge of low salinity waters from the Amazon river. During boreal late winter/spring (Mar-May; high river discharge), deeper isothermal (Z T) and mixed layers (Z M) prevail and the formation of a 16m-thick BL was clearly determined the formation of a salt-induced marked pycnocline within a deeper isothermal layer. However, during the boreal autumn (Oct-Dec; low river discharge), density stratification was mainly determined by temperature distribution (Z M m Z T; BLT = Z M - Z T m 0). There was no clear register of a BL on the Amazon shelf, but a maximum BL (40 m) formed near the shelf break at 45°W

Revisiting the tropical Atlantic western boundary circulation from a 25-year time series of satellite altimetry data

Geostrophic currents derived from altimetry are used to investigate the surface circulation in the Western Tropical Atlantic over the 1998&ndash;2017 period. Using six horizontal sections defined to capture the current branches of the study area, we investigate their respective variations at both seasonal and interannual time-scales as well as the spatial distribution of these variations. Our results show that the central branch of the South Equatorial Current, the North Brazil Current component located south of the equator, the Guyana Current and the northern branch of the South Equatorial Current at 42&deg; W have similar annual cycles, with maxima/minima during boreal winter-spring/October&ndash;November. In contrast, the seasonal cycles of the North Brazil Current branch located between the equator and 7&ndash;8&deg; N, the North Brazil Current retroflected branch and the North Equatorial Countercurrent show maxima/minima during boreal fall/May. West of 42&deg; W, an eastward current is observed between 0&deg;&ndash;2&deg; N, identified as the equatorial extension of the retroflected branch of the North Brazil Current. It is part of a large cyclonic circulation observed between 0&deg;&ndash;6&deg; N and 35&deg;&ndash;45&deg; W during boreal spring. The North Equatorial Countercurrent shows a two-core structure during the second half of the year, when we also observe the two regions where the North Brazil Current retroflects. The latter can be related to the wind stress curl seasonal changes. At interannual scales, depending on which side of the equator, the North Brazil Current exhibits two opposite scenarios related to the tropical Atlantic Meridional Mode phases. The interannual variability of the North Equatorial Countercurrent and of the northern branch of the South Equatorial Current (in terms of both strength and/or latitudinal shift) at 42&deg; W are also associated to the Atlantic Meridional Mode, while they are associated to the zonal mode phases at 32&deg; W.</p

Vertical Turbulent Cooling of the Mixed Layer in the Atlantic ITCZ and Trade Wind Regions

The causes of the seasonal cycle of vertical turbulent cooling at the base of the mixed layer are assessed using observations from moored buoys in the tropical Atlantic Intertropical Convergence Zone (ITCZ) (4°N, 23°W) and trade wind (15°N, 38°W) regions together with mixing parameterizations and a one-dimensional model. At 4°N the parameterized turbulent cooling rates during 2017–2018 and 2019 agree with indirect estimates from the climatological mooring heat budget residual: both show mean cooling of 25–30 W m (Formula presented.) during November–July, when winds are weakest and the mixed layer is thinnest, and 0–10 W m (Formula presented.) during August–October. Mixing during November–July is driven by variability on multiple time scales, including subdiurnal, near-inertial, and intraseasonal. Shear associated with tropical instability waves (TIWs) is found to generate mixing and monthly mean cooling of 15–30 W m (Formula presented.) during May–July in 2017 and 2019. At 15°N the seasonal cycle of turbulent cooling is out of phase compared to 4°N, with largest cooling of up to 60 W m (Formula presented.) during boreal fall. However, the relationships between wind speed, mixed layer depth, and turbulent mixing are similar: weaker mean winds and a thinner mixed layer in the fall are associated with stronger mixing and turbulent cooling of SST. These results emphasize the importance of seasonal modulations of mixed layer depth at both locations and shear from TIWs at 4°N

Interannual to decadal changes in the western boundary circulation in the Atlantic at 11°S

The western boundary current system off Brazil is a key region for diagnosing variations of the Atlantic meridional overturning circulation (AMOC) and the southern subtropical cell. In July 2013 a mooring array was installed off the coast at 11°S similar to an array installed between 2000 and 2004 at the same location. Here we present results from two research cruises and the first 10.5 months of moored observations in comparison to the observations a decade ago. Average transports of the North Brazil Undercurrent and the Deep Western Boundary Current (DWBC) have not changed between the observational periods. DWBC eddies that are predicted to disappear with a weakening AMOC are still present. Upper layer changes in salinity and oxygen within the last decade are consistent with an increased Agulhas leakage, while at depths water mass changes are likely related to changes in the North Atlantic as well as tropical circulation changes

INFLUÊNCIA DA HIDROGINÁSTICA SOBRE ASPECTOS HEMODINÂMICOS

As doenças cardiovasculares são a principal causa de morte no mundo, e a hipertensão arterial é a mais prevalente entre elas. A atividade física é um importante componente de um estilo de vida saudável, com evidências de que o exercício realizado em meio aquático reduz a pressão arterial (PA), embora ainda não haja consenso. Objetivo: avaliar o impacto da hidroginástica sobre a PA de normotensos (CON) e hipertensos (HIP). Métodos: 84 adultos e idosos foram convidados a participar de um programa de hidroginástica, 2 vezes/semana, 50 minutos/sessão, por 16 semanas. Os participantes foram divididos em dois grupos: HIP (n = 30) e CON (n = 54) e submetidos à avaliação antropométrica, hemodinâmica e de capacidade física. Resultados: CON e HIP não diferiram, inicialmente, quanto à antropometria, entretanto, os HIP exibiam maior proporção de internações (30% versus 5%), dores (42% versus 21%) e formigamentos (28% versus 10%) nos membros inferiores. Após o programa de hidroginástica, ambos os grupos aumentaram o VO2 máximo (CON: 12,4 para 13,0 ml/kg/min e HIP: 12,4 para 13,2 ml/kg/min), associados a significativas reduções da PA sistólica (deitados: 7,6 e 12,9 mmHg e sentados: 6,8 e 12,0 mmHg) e diastólica (deitados: 2,2 e 4,8 mmHg e sentados: 3,9 e 5,6 mmHg) de repouso. A PAS de exercício dos HIP foi reduzida em 10 mmHg e a FC de CON e HIP sofreu significativa redução de 6 e 9 bpm, respectivamente. A saturação sanguínea de oxigênio não mudou com o programa de hidroginástica. Conclusão: a hidroginástica reduziu a PA sistólica e diastólica de indivíduos HIP e aumentou a aptidão cardiorrespiratória