Temperature versus salinity gradients below the ocean mixed layer

Helber, Robert W.; Kara, A. Birol; Richman, James G.; Carnes, Michael R.; Barron, Charlie N.; Hurlburt, Harley E.; Boyer, Timothy P.

doi:10.1029/2011jc007382

Cited by 28 publications

(20 citation statements)

References 48 publications

(76 reference statements)

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“…Mixed layer depth (MLD) is defined as the shallowest of the ITLD, IHLD or IPLD. Barrier layer thickness (BLT) is defined as the difference between the ITLD and IPLD (Helber et al, ). MLD and BLT for ARGO profiling floats (a)–(j) are given in the Table .…”

Section: Resultsmentioning

confidence: 99%

Response of oceanic cyclogenesis metrics forNARGIScyclone: a case study

Vissa

Satyanarayana

Kumar

2013

Atmospheric Science Letters

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In this study, variability of two oceanic cyclogenesis metrics, tropical cyclone heat potential (TCHP) and effective oceanic layer for cyclogenesis (EOLC) in the Bay of Bengal (BoB) during NARGIS cyclone is investigated. EOLC represents the geopotential thickness of near surface stratified layer forms because of the spread of low salinity waters due to fresh water influx from rivers and precipitation. Climatological fields of TCHP and EOLC reveal that NARGIS translated towards the region of higher EOLC as seen in the observations. A maximum daily sea surface cooling of 2• C is observed along the right and rear side of NARGIS track.

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Section: Resultsmentioning

confidence: 99%

Response of oceanic cyclogenesis metrics forNARGIScyclone: a case study

Vissa

Satyanarayana

Kumar

2013

Atmospheric Science Letters

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“…More specifically, the smaller temperature difference between the surface and bottom indicated a weaker stratification stability, which was opposite to the salinity. The greater top-to-bottom salinity difference corresponded to strong vertical mixing [31]. The spatial distributions of the differences between the surface and bottom hydrological features (the difference between the surface and bottom) are shown in Figure 2.…”

Section: Hydrographymentioning

confidence: 98%

Variability of the Suspended Particle Cross-Sectional Area in the Bohai Sea and Yellow Sea

et al. 2019

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A cross-sectional area (CSA) is a key element in the optical properties of suspended particles. The seasonal evolution of CSA has great potential for use in mapping total suspended particles, and such mapping plays an important role in water quality monitoring. In this study, the spatiotemporal variations in CSA in the Bohai Sea and the Yellow Sea were studied using temperature, salinity and chlorophyll-a data collected by four cruises. The CSA field data covered a wide range of spatiotemporal variabilities in the Bohai Sea and the Yellow Sea. The results revealed that the largest CSA (>2 m−1) was found in the coastal area, while the CSA (≤1 m−1) on the outer shelf was much smaller. Large values of CSA (>15 m−1) were observed in winter, whereas the smallest values of CSA (0~2 m−1) were observed in summer. These results suggest that vertical mixing and ocean stratification might be important physical mechanisms that influences the CSA seasonal distribution in the surface layer. The results also showed that phytoplankton played an important role in the CSA, with an R2 value of 0.601. The seasonal patterns of CSA documented in this study provide a fundamental theory for research on optical properties, mapping transparency, and photosynthetically active radiation.

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“…Another factor that affects the salinity of seawater is temperature; as the temperature decreases, concentration of dissolved salt decreases, that is, there is a drop in solubility [6,7]. This drop in solubility reduces the conductivity of the seawater, increases its electrolyte resistivity [8], and encourages the dissolution of oxygen.…”

Section: Temperaturementioning

confidence: 99%

Computatonal Analysis of System and Design Parameters of Electrodeposition for Marine Applications

Farotade¹,

Popoola²,

Popoola³

2016

Applied Studies of Coastal and Marine Environments

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The financial prudence of the global world is shaken due to the vigor induced by corrosion as the degradation of essential assets, namely, oil and gas platforms and marine machineries, appears as a red-flagged situation. The exacerbation created by chemical degradation of these assets is as a result of the presence of saltwater, and the highly dominating activity of salt in the atmosphere poses a critical influence in selecting the mode of corrosion prevention to be integrated. As the hunger for longer term service and cost effectiveness of protection increases, studies are clustered in the search of new corrosionresistant coatings while adhering to the increasing stringent environmental code of practice. Porosity is a key factor which is considered in the development of corrosion-resistant coatings, stimulating localized forms of corrosion, such as galvanic and crevice corrosion. Nevertheless, researches have been implemented to coin this challenge by acquiring full understanding of effective parameters of salt bath conditions, their interactions, and influence on the degree of uniform electrodeposition. A significant contribution is presented in the light of reviewing the possibility of computational analysis of system and design parameters in optimizing the deposition rate and quality.

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Temperature versus salinity gradients below the ocean mixed layer

Cited by 28 publications

References 48 publications

Response of oceanic cyclogenesis metrics forNARGIScyclone: a case study

Response of oceanic cyclogenesis metrics forNARGIScyclone: a case study

Variability of the Suspended Particle Cross-Sectional Area in the Bohai Sea and Yellow Sea

Computatonal Analysis of System and Design Parameters of Electrodeposition for Marine Applications

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