Determination of Location of the Concentration Initial Field of a Possible Contamination Source in the Black Sea Water Area near the Gerakleisky Peninsula Based on the Adjoint Equations Method

East coast is the most storm part of the Black Sea because extent of the water area of the Black Sea more than 800 km. In a year there are about 17 days strong storm. Almost rectilinear outlines of the coast on a site from the river Tuapse to river Psou testify to destructive force of storm at low durability of the rocks composing the coast. The wave mode in the high sea can be determined by standard fields of a wind which build with use of weather maps. For a basis of typification take the direction and gradation of speed of a wind for that part of the water area within which it is required to define elements of waves. The main lack of a method is a short row – 10 years therefore the forecast for 25, 50 and 100 years on this row is estimated. Besides, for the district of Sochi the considerable share of excitements of a ripple (50–75 %) which are formed in different areas of the sea is characteristic. Therefore for this region any settlement method for wind excitement in the high sea won't reflect the actual mode of excitement and parameters of waves at the coast. Therefore in this case it is necessary to use all available actual data on excitement at probably bigger depth of supervision and all data on impact of the maximum storm on the coast in similar to the area of research conditions. The most qualitative for the considered coast are materials of supervision in Pitsunda. For application of these data for other sites of the coast taking into account a refraction recalculation of these supervision from shallow water is made for excitement of the deep sea. These data can be used for calculation of elements of waves on the Sochi coast. For the accounting of features of a wave mode at construction of such responsible and expensive constructions as ports, creation of new wave posts for long-term supervision is necessary. Especially it is actual in the Adler district of the city of Sochi where parameters of extreme storm are estimated generally on the put damage, instead of on series of observations over excitement. Tool supervision over excitement were carried out on northern to a pier of the Sochi port after the completion of its construction and allowed to define instrumentalno wave loads of a hydraulic engineering construction during a storm. Again created constructions of Mzymta seaport on the coast of the Imeretinsky bay and created during reconstruction of the Sochi seaport a new northern pier could form base for the organization of tool supervision over excitement on rather big depths near 15–20 M that it is quite enough for supervision of the maximum waves to their collapse.

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Determination of PAH in the Black Sea Water by GC/MS Following Preconcentration with Solid-Phase Extraction

Ecological Chemistry and Engineering S ◽

10.2478/v10216-011-0029-4 ◽

2012 ◽

Vol 19 (3) ◽

pp. 393-403 ◽

Cited By ~ 2

Author(s):

Elka Kraleva ◽

Vencislav Karamfilov ◽

Georgi Hibaum

Keyword(s):

Solid Phase Extraction ◽

Black Sea ◽

Sea Water ◽

Solid Phase ◽

Chromatographic Determination ◽

The Black Sea ◽

Running Waters ◽

Phase Extraction ◽

Concentration Technique

Determination of PAH in the Black Sea Water by GC/MS Following Preconcentration with Solid-Phase Extraction Determination of PAHs in marine coastal waters has to be carried out with great care to avoid serious losses occurring during the sampling and storage stage. This is due to the hydrophobic properties of PAHs, and their tendency to be adsorbed to surfaces they are in contact with, including suspended particulate matter. The best technique to separate PAHs is gas chromatography with mass spectrometer. Because of low concentration levels to be quantified in water samples, an enrichment step is needed before chromatographic analysis. For PAHs, several preconcentration techniques have been used, but the most concentration technique is solid-phase extraction (SPE). The main objective of this work is to adapt and implement a relatively simple and rapid method for gas chromatographic determination of individual PAHs in samples of coastal and running waters. The present work analyses the yield and precision of extraction of PAHs by solid phase extraction with using different sorbents for SPE (Bond Elut: C18 and Plexa SPE discs), the two most common methods used for aqueous samples.

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Modelling the generation of dusty marine aerosol by expeditionary data and remote sensing methods over the Black Sea region

E3S Web of Conferences ◽

10.1051/e3sconf/202022402031 ◽

2020 ◽

Vol 224 ◽

pp. 02031

Author(s):

A Papkova ◽

S Papkov ◽

D Shukalo

Keyword(s):

Black Sea ◽

Sea Water ◽

Atmospheric Correction ◽

Water Area ◽

The Black Sea ◽

Marine Aerosol ◽

Reliable Determination ◽

Black Sea Region ◽

Dust Transport ◽

Remote Sensing Methods

During a long-range transport, Sahara dust is naturally mixed with other aerosols, including maritime. At present, the mixing of these types of marine and dust aerosols is of particular interest, since it is important to correctly estimate the ionic and mass balance of aerosol particles. This problem is caused by the need for a reliable determination of the aerosol source and for correct atmospheric correction of satellite data. An analysis was made of the correlation between the change in the AOT parameter and the dates of dust transport from the Sahara to the Black Sea region. The analysis results confirmed the fact that the presence of dust aerosol over the Black Sea water area has a strong effect on the AOT indicator at all wavelengths, increasing the parameter almost by 2 times. This fact is correspondent to the generation of a secondary type of aerosol, namely, dusty marine aerosol. Analysis of CALIPSO aerosol subtype maps also revealed the presence of dusty marine aerosol with corresponding depolarization coefficients.

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Analysis of the conditions for the occurrence of "the voice of the sea" using infrasound observations in marine waters

Известия Российской академии наук Физика атмосферы и океана ◽

10.31857/s0002-351555183-97 ◽

2019 ◽

Vol 55 (1) ◽

pp. 83-97

Author(s):

V. G. Perepelkin ◽

I. P. Chunchuzov ◽

S. N. Kulichkov ◽

O. E. Popov ◽

I. A. Repina

Keyword(s):

Wind Speed ◽

Wind Velocity ◽

Black Sea ◽

Acoustic Waves ◽

Sea Water ◽

Simultaneous Detection ◽

Water Area ◽

The Black Sea ◽

Atmospheric Vortices ◽

The Voice

We study the conditions for the occurrence of "the voice of the sea" in the infrasound range can occur and determine its parameters from infrasound measurements in the Black Sea water area conducted in 2011 and 2016 and in the water area of the Sea of Okhotsk in 2017. To this end, we compared the observations of different parameters (mean correlation, spectra of acoustic arrivals, direction and phase velocity) of the high-frequency infrasound (1–10 Hz), recorded in Katsiveli (Crimea) in 2011 and 2016. We performed a detailed study of the wind conditions in the Black Sea water area during the measurement period, as well as the conditions for the propagation of acoustic waves along the direction of their arrivals. In both cases the atmospheric vortices in the direction of the arrival of infrasound were detected, which caused changes in wind velocity vector above the sea surface. The infrasound recorded in 2011 was caused by the interaction of two differently rotating atmospheric vortices over the sea. In 2016, a vortex was observed to the West from the registration point. The possibility of generating "the voice of the sea" due to the rotation of the wind velocity, which causes a nonlinear interaction of surface waves propagating in opposite directions to each other, and the formation of their 2nd harmonic in the form of a standing surface wave is discussed. From the analysis of the wind speed and wind direction profiles along the infrasound arrival path, as well as the acoustic pressure fields calculated by the parabolic equation method for the effective sound speed profiles in the direction of infrasound propagation, the most probable areas of infrasound generation were determined. In both cases these areas coincided with the zones in which the wind speed drops to zero, and the direction of the wind changes to the opposite. An example of simultaneous detection from one direction of the microbaroms with frequencies 0.2–0.3 Hz and "the voice of the sea" with a higher frequency of 5.5 Hz is given.

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The chemical-microbiological characteristics of sea water and bottom sediments of the Kerch Strait and adjacent water areas

Marine Biological Journal ◽

10.21072/mbj.2017.02.3.07 ◽

2017 ◽

Vol 2 (3) ◽

pp. 75-85

Author(s):

E. A. Tikhonova ◽

N. V. Burdiyan ◽

O. V. Soloveva

Keyword(s):

Surface Layer ◽

Black Sea ◽

Bottom Sediments ◽

Heterotrophic Bacteria ◽

Sea Water ◽

Water Area ◽

The Black Sea ◽

Azov Sea ◽

Sea Bottom ◽

Oil Hydrocarbons

This paper presents the results of contamination level of sea bottom sediments and seawater in the water areas by the strait of the Black Sea and the Azov Sea by oil hydrocarbons and chloroform-extractable substances studies (spring, autumn 2016). Comparison of marine environment pollution levels with the results of previous studies (2007–2010) and sanitary norms is given. The quantitative characteristics of heterotrophic and oil-oxidizing microbiota in the designated areas are presented. It was determined that the concentration of oil hydrocarbons in the water surface layer in the water area by the strait of the Azov Sea did not exceed the current norm (0.05 mg·l-1). The single cases of the maximum permissible concentration exceeding were registered in the water area by the strait of the Black Sea (autumn 2016). In the surface layer of Azov Sea water, the number of heterotrophic bacteria ranged from 104 to 105 cells·ml-1, and the oil-oxidizing bacteria were isolated in single quantities. In the water area of the Black Sea region of the strait the number of heterotrophic bacteria was 106, the number of oil-oxidizing bacteria did not exceed 10 cells·ml-1. In comparison with the previous years’ data, there was an increase in quantitative indicators of chloroform-extractable substances and oil hydrocarbons in the sea bottom sediments. The overall level of pollution did not exceed the average values determined for the region. The number of heterotrophic bacteria in the sea bottom sediments varied in the Strait of Azov water area from 2,5·104 to 4,5·104 cells·g-1, while that of oil-oxidizing bacteria varied from 2,5·10 to 4,5·102 cells·g-1. In the sea bottom sediments of the Black Sea, the number of heterotrophic bacteria was 4,5·103 cells·g-1, the number of oil oxidizing bacteria was 10 cells·g-1.

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HYDROGEN FROM HYDROGEN SULPHIDE IN BLACK SEA

Alternative Energy and Ecology (ISJAEE) ◽

10.15518/isjaee.2019.01-03.049-055 ◽

2019 ◽

pp. 49-55

Author(s):

S. Z. Baykara ◽

E. H. Figen ◽

A. Kale ◽

T. N. Veziroglu

Keyword(s):

Hydrogen Production ◽

Black Sea ◽

Hydrogen Sulphide ◽

Sea Water ◽

Economic Value ◽

Environmental Pollutant ◽

The Black Sea ◽

Fuel Processing ◽

Acid Gas ◽

Reducing Bacteria

Hydrogen sulphide, an acid gas, is generally considered an environmental pollutant. As an industrial byproduct, it is produced mostly during fuel processing. Hydrogen sulphide occurs naturally in many gas wells and also in gas hydrates and gas-saturated sediments especially at the bottom of the Black Sea where 90% of the sea water is anaerobic.The anoxic conditions exist in the deepest parts of the basin since nearly 7300 years, caused by the density stratification following the significant influx of the Mediterranean water through the Bosphorous nearly 9000 years ago. Here, H2S is believed to be produced by sulphur reducing bacteria at an approximate rate of 10 000 tons per day, and it poses a serious threat since it keeps reducing the life in the Black Sea. An oxygen–hydrogen sulphide interface is established at 150–200 m below the surface after which H2S concentration starts increasing regularly until 1000 m, and finally reaches a nearly constant value of 9.5 mg/l around 1500 m depth.Hydrogen sulphide potentially has economic value if both sulphur and hydrogen can be recovered. Several methods are studied for H2S decomposition, including thermal, thermochemical, electrochemical, photochemical and plasmochemical methods.In the present work, H2S potential in the Black Sea is investigated as a source of hydrogen, an evaluation of the developing prominent techniques for hydrogen production from H2S is made, and an engineering assessment is carried out regarding hydrogen production from H2S in the Black Sea using a process design based on the catalytic solar thermolysis approach. Possibility of a modular plant is considered for production at larger scale.

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DISTRIBUTION OF DISSOLVED METHANE IN SURFACE COASTAL WATERS OF THE NORTHEASTERN PART OF THE BLACK SEA

Proceedings of International Conference "Managinag risks to coastal regions and communities in a changinag world" (EMECS'11 - SeaCoasts XXVI) ◽

10.31519/conferencearticle_5b1b93b237aa68.28587089 ◽

2017 ◽

Author(s):

Elena Kovaleva ◽

Alexander Izhitskiy ◽

Alexander Egorov ◽

...

Keyword(s):

Black Sea ◽

Natural Waters ◽

Sea Water ◽

The Black Sea ◽

Methane Formation ◽

Anthropogenic Pressure ◽

Russian Science ◽

Southeastern Part ◽

Dissolved Methane ◽

Continental Runoff

Studying of methane formation and distribution in natural waters is important for understanding of biogeochemical processes of carbon cycle, searching for oil and gas sections and evaluation of CH4 emissions for investigations of greenhouse effect. The Black Sea is the largest methane water body on our planet. However, relatively low values of methane concentration (closed to equilibrium with the atmospheric air) are typical of the upper aerobic layer. At the same time, the distribution pattern of CH4 in surface waters of coastal areas is complicated by the influence of coastal biological productivity, continental runoff, bottom sources, hydrodynamic processes and anthropogenic effect. The investigation is focused on the spatial variability of dissolved methane in the surface layer of the sea in coastal regions affected by the continental runoff and anthropogenic pressure. Unique in situ data on methane concentrations were collected along the ship track on 2 sections between Sochi and Gelendzhik (2013, 2014) and 2 sections between Gelendzhik and Feodosia (2015). Overall 170 samples were obtained. Gas-chromatographic analysis of the samples revealed increase of CH4 saturation in the southeastern part of the Crimean shelf and the Kerch Strait area. Such a pattern was apparently caused by the influence of the Azov Sea water spread westward along the Crimean shore from the strait. This work was supported by the Russian Science Foundation, Project 14-50-00095 and the Russian Foundation for Basic Research, Project 16-35-00156 mol_a.

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LUMINESCENCE OF THE BLACK SEA MICROSCOPIC FUNGI CULTURES

Proceedings of International Conference "Managinag risks to coastal regions and communities in a changinag world" (EMECS'11 - SeaCoasts XXVI) ◽

10.31519/conferencearticle_5b1b946ac0fc74.55415483 ◽

2017 ◽

Author(s):

Olga Mashukova ◽

Yuriy Tokarev ◽

Nadejda Kopytina ◽

...

Keyword(s):

Fresh Water ◽

Black Sea ◽

Ethyl Alcohol ◽

Light Emission ◽

Sea Water ◽

Control Culture ◽

Chemical Stimulation ◽

The Black Sea ◽

The Given ◽

First Time

We studied for the first time luminescence characteristics of the some micromycetes, isolated from the bottom sediments of the Black sea from the 27 m depth. Luminescence parameters were registered at laboratory complex “Svet” using mechanical and chemical stimulations. Fungi cultures of genera Acremonium, Aspergillus, Penicillium were isolated on ChDA medium which served as control. Culture of Penicillium commune gave no light emission with any kind of stimulation. Culture of Acremonium sp. has shown luminescence in the blue – green field of spectrum. Using chemical stimulation by fresh water we registered signals with luminescence energy (to 3.24 ± 0.11)•108 quantum•cm2 and duration up to 4.42 s, which 3 times exceeded analogous magnitudes in a group, stimulated by sea water (p < 0.05). Under chemical stimulation by ethyl alcohol fungi culture luminescence was not observed. Culture of Aspergillus fumigatus possessed the most expressed properties of luminescence. Stimulation by fresh water culture emission with energy of (3.35 ± 0.11)•108 quantum•cm2 and duration up to 4.96 s. Action of ethyl alcohol to culture also stimulated signals, but intensity of light emission was 3–4 times lower than under mechanical stimulation. For sure the given studies will permit not only to evaluate contribution of marine fungi into general bioluminescence of the sea, but as well to determine places of accumulation of opportunistic species in the sea.

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