Water masses and the thermohaline circulation at the entrance to the Gulf of California

Spearman, Monty Graham.

January 1900

Thesis (M.S.)--Naval Postgraduate School, 1993. / "NPS-OC-93-007." "September 1993." "Prepared for Dean of Research (Code 08), Naval Postgraduate School." Includes bibliographical references (p. 185-187).

Neuro-symbolic model for real-time forecasting problems

Corchado Rodríguez, Juan Manuel

January 2000

No description available.

621.3994

A complex distribution of water masses and related circulation off northern California in July 1981

Olivera, Ricardo Martin

17 December 1982

Graduation date: 1983

Mesoscale spatial and temporal variations of water mass characteristics in the California Current region off Monterey Bay in 1973-1974

Blumberg, Richard Edward.

January 1975

Thesis (M.S.)--Naval Postgraduate School, 1975. / Includes bibliographical references (leaf 140).

Analise Termohalina de Massas de Agua da Regiao Oestedo Oceano Atlantico Sul Tropical (Lat. 07S -20s. Log.032W - 036W). / Termohaline analysis of water masses located in the Western part of the Tropical South Atlantic (lat. 07ºs-20ºs; long. 32ºw-36ºw

Castro Filho, Belmiro Mendes de

15 February 1977

O objetivo deste trabalho é apresentar a teoria fundamental da análise de massas de água baseada nas características temperatura e salinidade, e a sua aplicação, em grande escala, às águas que circulam na troposfera oceânica e na camada intermediária da região oeste do Oceano Atlântico Sul Tropical, ao longo da costa brasileira. A região estudada está delimitada pelas latitudes de 7°S e de 20°S. Determinouse que a área de geração da camada de salinidade máxima, encontrada a 100 m de profundidade nessa região, está situada ao sul de 15°S, extendendose até as proximidades de 20°S. A partir de modelos estacionários para o estudo da mistura de massas de água foi possível avaliar o coeficiente vertical de difusão turbulenta, para o núcleo da Água Intermediária Antártica, que está compreendido entre 5 cm2 .s-1 e 15 cm2 .s-1 Na Água Central do Atlântico Sul encontraramse os valores: 20 cm2 .s-1 e 13 cm2 .s-1, para os coeficientes verticais de condutividade térmica turbulenta e de difusão turbulenta de sal, respectivamente. O triângulo de contração do volume específico na mistura vertical, permitiu estudar a influência desse fenômeno na mistura da Água Intermediária Antártica com as massas de água que a envolvem. O valor máximo desse parâmetro foi encontrado na interface entre essa última massa de água e a Água Central do Atlântico Sul ( - 3,2.10-4 cm3 .g-1). / The purpose of this work is to present the fundanental theory of water masses analysis, based on the teraperature and salinity properties, and its utilization in great scale to waters of the oceanic troposphere and of the intermediate layer of the west region of the South Tropical Atlantic Ocean along the Brazilian coast. The region under study is limited by latitude 7°S and 20°S. It was deterinined that the source area of hi salinity layer, which is found at 100 m in depth in this region, is located to the south of 15°S, extending as far as 20°S. Based on stationary models for the study of water nesses mixture, it was possible to estimate the vertical coefficient of turbulent diffusion, for the core of Antarctic Intermediate Water, which is between 5 cm2 .s-1 and 15 cm2 .s-1. In the South Atlantic Certral Water values of 20 cm2 .s-1 and 13 cm2 .s-1 are found for the vertical coefficients of turbulent heat conduction and turbulent salinity diffusion, respectively. The triangle of the specific volume contraction in the vertical mixing permitted the study of the influence of this phenomenon on the mixture of the Antarctic Intermediate Water and the water masses that envolves it. The greatest value of this parameter was found in the interface of the latter and the South Atlantic Central Water ( - 3,2.10-4 cm3 .g-1).

Atlântico Sul

massas da água

Massas de água

South Atlantic

water masses

Analise Termohalina de Massas de Agua da Regiao Oestedo Oceano Atlantico Sul Tropical (Lat. 07S -20s. Log.032W - 036W). / Termohaline analysis of water masses located in the Western part of the Tropical South Atlantic (lat. 07ºs-20ºs; long. 32ºw-36ºw

Belmiro Mendes de Castro Filho

15 February 1977

O objetivo deste trabalho é apresentar a teoria fundamental da análise de massas de água baseada nas características temperatura e salinidade, e a sua aplicação, em grande escala, às águas que circulam na troposfera oceânica e na camada intermediária da região oeste do Oceano Atlântico Sul Tropical, ao longo da costa brasileira. A região estudada está delimitada pelas latitudes de 7°S e de 20°S. Determinouse que a área de geração da camada de salinidade máxima, encontrada a 100 m de profundidade nessa região, está situada ao sul de 15°S, extendendose até as proximidades de 20°S. A partir de modelos estacionários para o estudo da mistura de massas de água foi possível avaliar o coeficiente vertical de difusão turbulenta, para o núcleo da Água Intermediária Antártica, que está compreendido entre 5 cm2 .s-1 e 15 cm2 .s-1 Na Água Central do Atlântico Sul encontraramse os valores: 20 cm2 .s-1 e 13 cm2 .s-1, para os coeficientes verticais de condutividade térmica turbulenta e de difusão turbulenta de sal, respectivamente. O triângulo de contração do volume específico na mistura vertical, permitiu estudar a influência desse fenômeno na mistura da Água Intermediária Antártica com as massas de água que a envolvem. O valor máximo desse parâmetro foi encontrado na interface entre essa última massa de água e a Água Central do Atlântico Sul ( - 3,2.10-4 cm3 .g-1). / The purpose of this work is to present the fundanental theory of water masses analysis, based on the teraperature and salinity properties, and its utilization in great scale to waters of the oceanic troposphere and of the intermediate layer of the west region of the South Tropical Atlantic Ocean along the Brazilian coast. The region under study is limited by latitude 7°S and 20°S. It was deterinined that the source area of hi salinity layer, which is found at 100 m in depth in this region, is located to the south of 15°S, extending as far as 20°S. Based on stationary models for the study of water nesses mixture, it was possible to estimate the vertical coefficient of turbulent diffusion, for the core of Antarctic Intermediate Water, which is between 5 cm2 .s-1 and 15 cm2 .s-1. In the South Atlantic Certral Water values of 20 cm2 .s-1 and 13 cm2 .s-1 are found for the vertical coefficients of turbulent heat conduction and turbulent salinity diffusion, respectively. The triangle of the specific volume contraction in the vertical mixing permitted the study of the influence of this phenomenon on the mixture of the Antarctic Intermediate Water and the water masses that envolves it. The greatest value of this parameter was found in the interface of the latter and the South Atlantic Central Water ( - 3,2.10-4 cm3 .g-1).

Atlântico Sul

massas da água

Massas de água

South Atlantic

water masses

Zooplankton indicators of water masses in the northeastern Gulf of St. Lawrence

Walsh, Anna Kay B.

January 1983

No description available.

Water masses -- Saint Lawrence, Gulf of.

Multidisciplinary oceanographic studies of a small island in the Southern California Bight

Caldeira, Rui Miguel Andrade,

January 2002

Thesis (Ph. D.)--University of California, Los Angeles, 2002. / Vita. Includes bibliographical references.

Circulation and Water Mass Formation in the Northern Red Sea Response to Wind and Thermohaline Forcing

Eyouni, Lina

11 1900

Numerical simulation and remote sensing have indicated that the northern half of the Red Sea has a significant role in the thermohaline circulation within the basin. However, very few studies with in situ observation have been performed in a region where the formation of Red Sea Outflow Water (RSOW) and occasionally of Red Sea Deep Water (RSDW) take place during the winter in the northern Red Sea (NRS). This study provides new insights into the seasonal variability and the mechanisms that drive the thermohaline circulation of the north half Red Sea using high-resolution glider observations combined with reanalysis and satellite datasets. The study describes the water masses characteristics, the mesoscale activity, and the forcing mechanisms. In addition, we examine the biogeochemical responses to the physical drivers in the northern half of the Red Sea and how these processes alter the marine ecosystem. During winter, the mesoscale eddy activity and heat fluxes create the necessary conditions for the formation of RSOW in the NRS. The cyclonic circulation elevates relatively denser water in the surface, which is exposed to the atmosphere exchange. Thus, it leads to subduction of the surface layer forming of RSOW. The subducted water has been characterized by high oxygen as it has recently been ventilated. In addition, chlorophyll fluorescence has subducted along the isopycnals, contributing to exporting material below the sunlit layer. After the formation of RSOW, a period of strong anticyclonic circulation was observed In late February, which stirred and mixed the advected waters from the south in the northern region. It is accompanied by heat flux transition, and at the periphery of the observed Anticyclonic Eddy, an uplifting of the densest water to the surface occurred. The presence of the anticyclonic circulation enables the water advection from the south and extends the time of the surface water for atmospheric exposure. In April, the warmer intrusion of fresher waters from the south dominated the eastern part of the NRS, reestablishing the cyclonic circulation. To the best of our knowledge, this is the first in situ observation in the NRS that captured the seasonal progression of the transition of heat flux in wintertime and water advection that terminates the formation of RSOW. A continuous supply of northward warmer, lower salinity near the coast from the south is observed throughout the summertime period. Strong stratification with surface mixed layers no deeper than 25-30 meters due to the advection of lower salinity surface water and local heating. Another change that occurred during the summer period is that the source of low salinity inflow into the region transitioned from Gulf of Aden Surface Water (GASW) to Gulf of Aden Intermediate Water (GAIW)—assuming that the inflow of GAIW began with the onset of the Southwest Monsoonal winds in the south. The summertime heating and along basin evaporation set up the system for the wintertime cooling and additional evaporation that contributes to the formation of RSOW and RSDW. The mixed layer Price-Weller-Pinkel (PWP) model (Price et al., 1986) is implemented to quantify the influence of local heat fluxes compared with horizontal advection of the Gulf of Aden Water on the upper layer. Simulation of the mixed layer showed that advection was the major contributor to the seasonally integrated heat content and mixed layer simulation in summer. In contrast to winter, the timing of the mesoscale eddy activity, significant cooling, and advection add complexity to the region. The difference in the heat content was significant, and the PWP predicted an increasing mixed layer depth, while the observed mixed layer depth remained relatively constant. The differences between the calculated and simulated heat content were minimum during the absence of the mesoscale eddy and advection from the south. Overall, the quantification suggests a complex relationship between atmospheric forcing and advection on the heat content and the mixed layer depth.

Circulation

Water Masses Transformation

Atmospheric forcing

horizontal advection

Zooplankton indicators of water masses in the northeastern Gulf of St. Lawrence

Walsh, Anna Kay B.

January 1983

No description available.

Water masses -- Saint Lawrence, Gulf of.