Seasonal evolution of the Yellow Sea Cold Water Mass and its interactions with ambient hydrodynamic system

Li, Jianchao; Li, Guangxue; Xu, Jishang; Dong, Ping; Qiao, Lulu; Liu, Shidong; Sun, Pingkuo; Zhong, Fan

doi:10.1002/2016jc012186

Cited by 54 publications

(45 citation statements)

References 39 publications

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“…As Cold Pool presence in the SMAB can be broadly represented by large differences between surface and bottom water temperatures [17,18], we utilized the difference between satellite-derived sea surface temperature and in-situ receiver-recorded bottom water temperature as an index of temperature strati cation associated with the Cold Pool. In addition to the SMAB, this metric, ΔT, has previously been used as an index of thermal strati cation in other systems [2,48]. Multi-scale Ultra-high Resolution Sea…”

Section: Methodsmentioning

confidence: 99%

Influence of thermal stratification and storms on acoustic telemetry detection efficiency: a year-long test in the US Southern Mid-Atlantic Bight

O’Brien

Secor

2020

Preprint

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Background: The detection efficiency of ultrasonic transmitters is seasonally variable, requiring long-term studies to evaluate key environmental features that mask, alter speed, bend, or reflect transmissions. The US Southern Mid-Atlantic Bight shelf is characterized by a strong summer thermocline capping remnant winter water, known as the Cold Pool, and a well-mixed water column in other seasons. To investigate the effects of interactions between temperature stratification and storm-induced noise on transmission detectability, we conducted a year-long range test in the bottom waters of the US Southern Mid-Atlantic Bight. We used generalized additive models and cross-validation to develop and evaluate a predictive model of detection efficiency and visualize variability in detection distance throughout the year of deployment.Results: The most-predictive model utilized the interaction between temperature stratification and ambient noise, predicting that stratification results in a 54% increase in detectability and 56% increase in detection distance. The model had an overall error rate of 16.3% and an 18.7% error at a distance of 800 m, predicting 9% detectability when the water column was not stratified and 63% when the difference between surface and bottom temperatures was greater than 4.6 °C. The distance at 50% detectability increased with the formation of the Cold Pool during spring, shifting from 559 ± 149 m to 872 ± 81 m over 3 days. All seasons were associated with storm-induced reductions in overall detectability and distance at 50% detectability.Conclusion: Thermal stratification within the Southern Mid-Atlantic Bight increases bottom water ultrasonic transmitter detection distance and reduces the impact of surface noise associated with large storms. This effect leads to a seasonal increase in detection distance from the late-spring through the summer. To our knowledge, this study is the first to report and quantify an increase in detection range as a result of temperature stratification, likely due to placing transmitters and receivers on the same side of a strong thermocline.

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Section: Methodsmentioning

confidence: 99%

Influence of thermal stratification and storms on acoustic telemetry detection efficiency: a year-long test in the US Southern Mid-Atlantic Bight

O’Brien

Secor

2020

Preprint

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“…Nitric oxide (NO) is a short-lived intermediate of the oceanic nitrogen cycle (Bange, 2008). It received limited attention so far because its determination in seawater is challenging (Zafiriou and McFarland, 1980;Lutterbeck and Bange, 2015;Liu et al, 2017). NO in surface seawater can be produced via the photolysis of nitrite (NO − 2 ) (Zafiriou and McFarland, 1981;Olasehinde et al, 2009Olasehinde et al, , 2010Liu et al, 2017):…”

Section: Introductionmentioning

confidence: 99%

“…The current understanding of the oceanic NO distribution is mainly limited to the ocean surface (Zafiriou and McFarland, 1981;Olasehinde at al., 2009Olasehinde at al., , 2010Liu et al, 2017) and oxygen minimum zones (OMZs; Ward and Zafiriou, 1988;Lutterbeck et al, 2018). Only recently have the distribution of NO as well as its seasonal variation in the Jiaozhou Bay and adjacent waters been studied (Feng et al, 2011;Xue et al, 2012;Tian et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Nitric oxide (NO) in the Bohai Sea and the Yellow Sea

et al. 2019

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Abstract. Nitric oxide (NO) is a short-lived compound of the marine nitrogen cycle; however, our knowledge about its oceanic distribution and turnover is rudimentary. Here we present the measurements of dissolved NO in the surface and bottom layers at 75 stations in the Bohai Sea (BS) and the Yellow Sea (YS) in June 2011. Moreover, NO photoproduction rates were determined at 27 stations in both seas. The NO concentrations in the surface and bottom layers were highly variable and ranged from below the limit of detection (i.e., 32 pmol L−1) to 616 pmol L−1 in the surface layer and 482 pmol L−1 in the bottom layer. There was no significant difference (p>0.05) between the mean NO concentrations in the surface (186±108 pmol L−1) and bottom (174±123 pmol L−1) layers. A decreasing trend of NO in bottom-layer concentrations with salinity indicates a NO input by submarine groundwater discharge. NO in the surface layer was supersaturated at all stations during both day and night and therefore the BS and YS were a persistent source of NO to the atmosphere at the time of our measurements. The average flux was about 4.5×10-16 mol cm−2 s−1 and the flux showed significant positive relationship with the wind speed. The accumulation of NO during daytime was a result of photochemical production, and photoproduction rates were correlated to illuminance. The persistent nighttime NO supersaturation pointed to an unidentified NO dark production. NO sea-to-air flux densities were much lower than the NO photoproduction rates. Therefore, we conclude that the bulk of the NO produced in the mixed layer was rapidly consumed before its release to the atmosphere.

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“…A comparison of the Diurnal and Daily Cases shows that a large deviation occurs in the summertime bottom temperature (Figure k) in the central Yellow Sea that overlaps with the area of the YSCWM. The YSCWM is a bottom water mass with relatively low temperature below the strong thermocline in the central Yellow Sea from May to November and is usually bordered by a 10

° C

isotherm (Fei et al, ; Li et al, ; Zhang et al, ). The mean temperature of the YSCWM from May to November was 8.9

° C

in the Diurnal Case but was 8.5

° C

in the Daily Case (Table ).…”

Section: Model Resultsmentioning

confidence: 99%

Diurnal Forcing Induces Variations in Seasonal Temperature and Its Rectification Mechanism in the Eastern Shelf Seas of China

Gao

Shi

et al. 2017

JGR Oceans

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This study investigates the seasonal variation in temperature induced by diurnal forcing in the eastern shelf seas of China (ESSC) using a high‐resolution Regional Ocean Modeling System model forced by the National Center for Environmental Prediction and the National Center for Atmospheric Research re‐analysis data for surface fluxes with both 6 h and daily frequencies, respectively. The comparison between two experiments revealed a ±0.4°normalC modification of the variation in seasonal temperature by diurnal forcing, which also increases the mixed‐layer depth (MLD) in August by 26% and reduces the volume of the Yellow Sea Cold Water Mass (YSCWM) by 25%. Sensitivity experiments using different forcing variables indicated that diurnal wind can explain over 80% of the variability in seasonal temperature induced by diurnal forcing. Diurnal wind led to an increase in the net heat flux into the ocean by about 13 normalW/normalm2 in summer and a decrease by about 15 normalW/normalm2 in winter. Diurnal wind also generated an additional downward heat transport of 21 normalW/normalm2 over the ESSC that contributed to variability in the mean MLD and YSCWM in August. Experiments changing the temporal interval of wind forcing suggested that the increase in the forcing temporal interval gradually enhanced the reproduction of the variability in seasonal temperature generated by diurnal wind; a 6 h wind forcing can capture 70% of this type of variability given by 1 h wind forcing, while a 3 h or shorter wind forcing can capture 90%.

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Seasonal evolution of the Yellow Sea Cold Water Mass and its interactions with ambient hydrodynamic system

Cited by 54 publications

References 39 publications

Influence of thermal stratification and storms on acoustic telemetry detection efficiency: a year-long test in the US Southern Mid-Atlantic Bight

Influence of thermal stratification and storms on acoustic telemetry detection efficiency: a year-long test in the US Southern Mid-Atlantic Bight

Nitric oxide (NO) in the Bohai Sea and the Yellow Sea

Diurnal Forcing Induces Variations in Seasonal Temperature and Its Rectification Mechanism in the Eastern Shelf Seas of China

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