Synoptic and Seasonal Variability of Small River Plumes in the Northeastern Part of the Black Sea

Korshenko, Evgeniya; Panasenkova, Irina; Osadchiev, Alexander; Belyakova, P. A.; Фомин, В. В.

doi:10.3390/w15040721

Cited by 4 publications

(4 citation statements)

References 31 publications

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“…The Patos Lagoon exhibits a microtidal regime, with a mean range of 0.5 m and diurnal dominance (Moller et al, 2001), having negligible influence on the lagoon's circulation (Moller et al, 2001;Fernandes et al, 2004). As the tidal amplitude is small, the dynamics of the lagoon and turbid plume is controlled by the combined effect Mean, standard deviation and covariance of spectral parameters for each trained class (Lihan et al, 2008), (Thomas and Weatherbee, 2006) Threshold SPM trial-and-error maximum autocorrelation (Constantin et al, 2018), (Zhang et al, 2016), (Petus et al, 2014) percentile 95 th (Longitude, Latitude, time) (Gangloff et al, 2017), (Ody et al, 2022) SPM and Digital Number* trial-and-error and region growing (Teodoro et al, 2008), (Teodoro and Goncalves, 2011) TOA Salinity and R rs (645)* maximum correlation with river discharge (Guo et al, 2017) Salinity** K-means cluster with manual adjustments (when needed) (Korshenko et al, 2023) Stratification salinity index** trial-and-error (Toublanc et al, 2023) Chlorophyll-a trial-and-error of gradient contour (Dzwonkowski and Yan, 2005) PLUMES Turbidity/SPM Similarity of pixels from control points and region growing check this study of wind and river discharge: high river discharge (Q > 2,000 m³s -1 ) overrules the dynamics promoted by winds, whereas, in dry periods, the wind effect becomes the most important forcing mechanism (Fernandes et al, 2002). Marques et al (2010a) verified the importance of the river discharge intensity to its formation and Zavialov et al (2018) identified the importance of the local wind action promoting the plume's stratification (Zavialov et al, 2018).…”

Section: Study Sitementioning

confidence: 99%

“…As we have shown in this work (e.g., Figure 8) these approaches are prone to ignore less intense plumes or smaller highly turbid coastal plumes. This drawback has been addressed by other authors with the aid of additional site-specific adjustments to achieve higher accuracy and precision; e.g., shallow-water masks (Gangloff et al, 2017); noiseremoval and region growing (Teodoro et al, 2008); manual adjustment of plume boundary (Korshenko et al, 2023).…”

Section: Challenges and Outlook Of Detecting Turbid Coastal Plumesmentioning

confidence: 99%

“…In that case, maximum likelihood approaches need to be re-trained (e.g., Thomas and Weatherbee, 2006) and thresholds must be adjusted not only for a specific site but case-by-case (e.g., Maciel et al, 2021), otherwise plumes may be overestimated, underestimated, or missed. To avoid overestimation, a few studies have further applied shallow water masks (typically< 20 m depth; e.g., Gangloff et al, 2017;Ody et al, 2022), manual adjustments (e.g., Korshenko et al, 2023), or region growing technique (e.g., Teodoro et al, 2008;Teodoro and Goncalves, 2011); although the latter is less known for coastal applications but widely applied in the medical (e.g., Tariq et al, 2019;Kroon, 2022) and in spatial planning/cartography (e.g., Goncalves, 2006). Application of shallow-water masks is intended to prevent the recurring issue that the thresholding method cannot distinguish between causes of turbid zones (i.e., turbid wakes, wave-driven coastal resuspension from the plume itself) like the human eye.…”

Section: Introductionmentioning

confidence: 99%

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Detecting turbid plumes from satellite remote sensing: State-of-art thresholds and the novel PLUMES algorithm

et al. 2023

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Turbid coastal plumes carry sediments, nutrients, and pollutants. Satellite remote sensing is an effective tool for studying water quality parameters in these turbid plumes while covering a wide range of hydrological and meteorological conditions. However, determining boundaries of turbid coastal plumes poses a challenge. Traditionally, thresholds are the approach of choice for plume detection as they are simple to implement and offer fast processing (especially important for large datasets). However, thresholds are site-specific and need to be re-adjusted for different datasets or when meteorological and hydrodynamical conditions differ. This study compares state-of-the-art threshold approaches with a novel algorithm (PLUMES) for detecting turbid coastal plumes from satellite remote sensing, tested for Patos Lagoon, Brazil. PLUMES is a semi-supervised, and spatially explicit algorithm, and does not assume a unique plume boundary. Results show that the thresholds and PLUMES approach each provide advantages and limitations. Compared with thresholds, the PLUMES algorithm can differentiate both low or high turbidity plumes from the ambient background waters and limits detection of coastal resuspension while automatically retrieving metrics of detected plumes (e.g., area, mean intensity, core location). The study highlights the potential of the PLUMES algorithm for detecting turbid coastal plumes from satellite remote sensing products, which can have significantly positive implications for coastal management. However, PLUMES, despite its demonstrated effectiveness in this study, has not yet been applied to other study sites.

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Section: Study Sitementioning

confidence: 99%

Section: Challenges and Outlook Of Detecting Turbid Coastal Plumesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Detecting turbid plumes from satellite remote sensing: State-of-art thresholds and the novel PLUMES algorithm

et al. 2023

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“…Interaction between fresh and seawaters forms local desalinated areas called plumes with a salinity up to 16 on the surface [18]. Despite the small annual river discharge in the NE sector, there is a significant seasonal and synoptic variability in the area and distribution of plumes on the surface of the Black Sea [19,20]. Seasonal variability is associated with the type of power supply of NE rivers, i.e., rain and seasonal snow.…”

Section: Introductionmentioning

confidence: 99%

Response of the Coastal Phytoplankton Community to the Runoff from Small Rivers in the Northeastern Black Sea

et al. 2023

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River runoff is an important source of nutrients as well as suspended and dissolved organic matter that in coastal zones and on the shelf are transformed due to local production cycles. River runoff affects the hydrological regime, salinity, temperature, and irradiance in river–seawater mixing zone. Our study focuses on the response of phytoplankton to the impact of small Caucasian rivers in the Northeastern (NE) Black Sea, as one of the most sensitive components of marine ecosystems with respect to the changes in abiotic factors. The leading role of marine species of diatoms, dinoflagellates, and coccolithophores in the structure and functioning when impacted by runoff from small rivers is demonstrated in comparison to the freshwater community. Variability of the taxonomic composition and quantitative and productive characteristics of marine phytoplankton communities impacted by small rivers were comparable to or exceed the seasonal and interannual variability on the NE Black Sea shelf. This indicates the significant role of runoff from small Caucasian rivers in maintaining of a high production level of phytoplankton overall and of the coccolithophore Emiliania huxleyi in particular in the coastal zone.

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Mesoscale Eddy Chain Structures in the Black Sea and Their Interaction with River Plumes: Numerical Modeling and Satellite Observations

2023

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The northeastern part of the cyclonic Rim Current, which encircles the entire basin of the Black Sea, is named as the Northeast Caucasian Current. It periodically approaches the coast, triggering the formation of topographic generated eddies, including long-living isolated anticyclonic eddies and short-living multiple anticyclonic eddies, which group and merge into eddy chain structures. Both types of eddies affect coastal dynamics and interact with multiple river plumes formed in the study area. This interaction determines cross- and along-shelf transport of fluvial water, enhancing the processes of self-cleaning of the coastal zone. In this study, we used a 3D low-dissipation model, DieCAST, coupled with a Lagrangian particle tracking model, and supported by analysis of satellite images, to study the generation and evolution of eddy chains and their interaction with river plumes along the Caucasian coast. Using Fourier and wavelet analyses of kinetic energy time series, we revealed that the occurrence of eddy chains ranges from 10 to 20 days, predominantly in spring-summer season in the area between the Pitsunda and Iskuria capes. During the period of eddy merging, the angular velocities of the orbiting eddies reach maximal values of 7 × 10−6 rad s−1, while after merging, the angular velocities of the resulting eddies decreased to 5 × 10−6 rad s−1. Numerical experiments with Lagrangian particle tracking showed that eddy chains effectively capture water from river plumes localized along the coast and then eject it to the open sea. This process provides an effective mechanism of cross-shelf transport of fluvial water, albeit less intense than the influence of isolated anticyclonic eddies, which are typical for autumn-winter season.

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Synoptic and Seasonal Variability of Small River Plumes in the Northeastern Part of the Black Sea

Cited by 4 publications

References 31 publications

Detecting turbid plumes from satellite remote sensing: State-of-art thresholds and the novel PLUMES algorithm

Detecting turbid plumes from satellite remote sensing: State-of-art thresholds and the novel PLUMES algorithm

Response of the Coastal Phytoplankton Community to the Runoff from Small Rivers in the Northeastern Black Sea

Mesoscale Eddy Chain Structures in the Black Sea and Their Interaction with River Plumes: Numerical Modeling and Satellite Observations

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