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9Original Russian Text © D. A. Kremenchutskii, K. I. Gurov, 2021, published in MORSKOY GIDROFIZICHESKIY ZHURNAL, Vol. 37, Iss. 2 (2021)
Distribution of 137Cs and 40K in the Bottom Sediments of the Balaklava Bay (the Black Sea)
D. A. Kremenchutskii, K. I. Gurov 0
Marine Hydrophysical Institute of RAS, Sevastopol, Russian Federation 0 gurovki@gmail.com
Purpose. The aim of the work is to study spatial variability of the 137Cs and 40K concentrations in the bottom sediments of the Balaklava Bay, and to estimate the sedimentation rate and relative content of the biogenic fraction.
Methods and Results. The results of the 137Cs and 40K concentration measurements in 5 columns of the bottom sediments sampled in various parts of the Balaklava Bay are represented. Activity of 137Cs and 40K in the samples was determined by the gamma spectrometric analysis. Based on the measurement data, spatial variability of the 137Cs and 40K concentration fields in the bottom sediments was studied, and the sedimentation rate was quantitatively estimated. Application of the balance equation provided quantitative estimates of the relative biogenic fraction content; its spatial variability was described. Quantitative estimates of the relationship between the biogenic fraction estimates resulted from use of the direct and indirect methods are represented.
Conclusions. According to the obtained results, the 137Cs and 40K concentrations in the upper 5 cm layer of bottom sediments varied in space from 11 to 62 and from 155 to 562 Bq/kg, respectively. The maximum radionuclide concentrations were characteristic of the northern part of the bay, the minimum ones - of its southern part. The sedimentation average rate was 0.51 ± 0.06 cm/year. Relative biogenic fraction content in the sediments varied in space from 30 to 89% and averaged 46 ± 25%. The maximum values were observed in the southern part of the bay, the minimum ones -in the northern part.
Keywords: Black Sea, Balaklava Bay, bottom sediments, cesium-137 (137Cs), potassium-40 (40K), sedimentation rate, biogenic fraction
Acknowledgements: the investigation was carried out within the framework of the state task on theme No. 0555-2021-0005 "Complex interdisciplinary investigations of the oceanologic processes conditioning functioning and evolution of the Black and Azov seas' ecosystems of the coastal zones" with support of the RFBR project No. 18-45-920007 "Geochemistry of bottom sediments pollutants of the Balaklava Bay (the Black Sea)".
For citation: Kremenchutskii, D.A. and Gurov, K.I., 2021. Distribution of 137Cs and 40K in the Bottom Sediments of the Balaklava Bay (the Black Sea). Physical Oceanography, [e-journal] 28(2), pp. 191-204. doi:10.22449/1573-160X-2021-2-191-204
DOI: 10.22449/1573-160X-2021-2-191-204
© D. A. Kremenchutskii, K. I. Gurov, 2021
© Physical Oceanography, 2021
Introduction
It is known that coastal areas are a place of active anthropogenic activity, which leads to the variation in the natural rates of geochemical processes and contributes to an increase in the pollution level of bottom sediments. Radionuclide contamination is a relatively new, but nevertheless sufficiently studied, type of environmental contamination. The intensification of industrial activity in the 19th century led to an increase in the input of individual microelements to aquatic systems as a result of their direct discharge (local pollution) and washout by
atmospheric precipitation (global distribution) and caused a complication of their geochemical balance and general state.
Due to its unique natural and climatic conditions and morphometric characteristics, the Balaklava Bay occupies a special place among the Sevastopol region bays. Back at the end of the 19 th century it was used as a mud treatment area. Active anthropogenic development in the second half of the 20th century caused a change in its morphometric parameters, the intake and accumulation of a large amount of pollutants and, as a result, led to deterioration in its ecological state. As a result, medicinal clay was replaced by technogenic one. At present, the active bay use as a yacht marina maintains a high level of anthropogenic pressure on its ecosystem and may lead to deterioration in its ecological state. At the same time, the preservation of such a unique natural site is an important task for the development of the resort and recreational complex of the entire region.
The study of the Balaklava Bay bottom sediments is of an episodic nature. Modern studies of the features of spatial distribution and quantitative characteristics of the accumulation of individual fractions, organic matter, and microelements in the Balaklava Bay water area are presented in the works of Marine Hydrophysical Institute employees [1-5]. At present, much attention is paid to the pollution of bottom sediments with organic substances [2, 3] and trace metals [3, 4]. In [2], for the first time for the Balaklava Bay water area, voltammetric profiling of the bottom sediments was carried out and the geochemical characteristics of pore waters were studied. In [5], numerical estimates of the bay water area pollution with the excessive total suspended matter, dissolved organic matter of artificial origin (an indicator of biological pollution), and petroleum hydrocarbons were obtained. According to the data of works [1, 4], the granulometric composition of bottom sediments is constantly changing. First of all, this is due to an increase in the proportion of finely dispersed pelitic silts, a decrease in the proportion of sandy and coarse shell material. The discharge of untreated domestic wastewater, industrial wastewaters, storm sewers, leaks of petroleum products from vessels based and being repaired in the bay, washout from the fields and the flow of fertilizers and pesticides with the Balaklavka River waters are the main alleged sources of pollution of the Balaklava Bay bottom sediments.
Cesium-137 (137Cs) is an artificial radionuclide of technogenic origin with a half-life of 30.05 years. Its input into the Black Sea is due to atmospheric fallout and river runoff [6]. A number of works [6-13] are devoted to the study of the spatiotemporal variability of its content in the Black Sea region water and bottom sediments. This radionuclide is widely used to obtain the sedimentation rate quantitative estimates [12, 14-15].
Potassium-40 (40K) is a radionuclide of natural origin with a half-life of 1.25-109 years. Much attention is also paid to the study of this radionuclide [11, 12, 16, 17]. The concentration of 40K in the sinking particles of lithogenic origin is approximately one order of magnitude higher than that of biogenic particles [18-22]. This feature can be used to obtain quantitative estimates of the of the biogenic component share in bottom sediments [12, 16, 17]. According to [17, 23, 24], the biogenic component of bottom sediments is a mixture of organic carbon particles, carbonate or siliceous remains of shells and skeletons of
planktonic microorganisms. Assessment of biogenic fraction accumulation is important due to its particular sensitivity to climate change and anthropogenic impacts, and is of great importance for studying carbon cycles and various pollutants.
Based on the literature data available to the authors, it should be noted that the data on 137Cs and 40K content in the Balaklava Bay bottom sediments are absent.
The purpose of this work is to study 137Cs and 40K content in the bottom sediments of the Balaklava Bay, as well as to assess the sedimentation rate and the relative content of biogenic fraction.
Materials and methods
The selection and preparation of the bottom sediment samples were carried out in accordance with the regulatory documents (GOST 17.1.5.01-80; ISO 566719:2004).
The column sampling was carried out using an acrylic soil tube with an inner diameter of 60 mm and a vacuum seal. On board, the columns were sealed with a cork from below and transported to the laboratory. In the laboratory the columns were separated into layers of 1-2 cm thickness using a hand extruder and an acrylic ring. Further, sample preparation was carried out in accordance with the normative documents for other analyzes.
The natural moisture content was determined by the gravimetric method according to the standard method (GOST R ISO 11465-2011; introduced from 01.01.2013). After drying, the sample was crushed and homogenized. A portion of this sample with a known mass was packed into 20 ml plastic vials for subsequent gamma spectrometric analysis.
Measurements of 137Cs and 40K activity in the bottom sediment samples were carried out on a low-background gamma-spectrometer with a well-type NaI(Tl) scintillation detector. The crystal diameter is 100 mm and its height is 100 mm. The diameter of the well is 40 mm, its depth is 60 mm. The resolution is 9% along the 137Cs line with 661 keV energy. The detector was located in a two-layer protection, the outer layer of which was formed by bricks of low-background lead (14 cm), the inner layer was made of old cast iron rings (15 cm). The measurement time of a single sample was determined based on its activity and varied within 24-48 h range.
The calibration of the detection efficiency of gamma quanta with different energies was carried out using certified sources supplied by the IAEA (IAEA-326, IAEA-CU-2006-03), which have a shape and size similar to the samples we studied.
The concentration of 137Cs (C137Cs) and 40K (C40K) in the bottom sediment samples was calculated using the following formula:
c-_N_
tms(E)y(E)k '
where C is a radionuclide concentration (Bq/kg); N is a radionuclide photopeak area (pulses); t is a spectrum accumulation time (s); m is a sample mass (kg); s(E) is a registration efficiency of gamma quanta with energy E; y(E) is a yield of
gamma quanta with energy E during the decay of the corresponding radionuclide; K is a coefficient that takes into account the decay of a radionuclide over a period of time (At) from the sampling to the beginning of its activity registration.
The estimates of K were obtained by the formula
K = exp(- lAt),
where l is a decay constant equal to 7.31-10 -10/s and 1.741-10 -17/s for 137Cs and 40K, respectively.
The estimates of the minimum detectable activity were obtained according to [25]. The lower detection limit for 137Cs is 4 Bq/kg, for 40K - 30 Bq/kg.
The error in determining the activity of radionuclides is due to the statistical error of their counting in the sample (1a), taking into account the static error in the background counting and efficiency calibration. In most cases, the total error did not exceed 15%.
The carbonate content (CaCO3) in the sample was determined using the weight-volume method after the decomposition of carbonates with hydrochloric acid, taking into account the methodological recommendations of the UNEP guidelines. Reanalysis of samples with a mean of 6.84% CaCO3 yielded a standard deviation of ± 0.18% (variation coefficient 2.6%) (UNEP/IOC/IAEA - 1995).
The organic carbon (Corg) concentration in the sample was determined by the spectrophotometric method after the organic matter oxidation with a sulfochromic mixture (GOST 26213-91; introduced from June 30, 1993).
Results and discussion
The layout of the stations is given in Fig. 1. In total, 5 columns of bottom sediments were selected: two columns in June 2015 (stations 1 and 2) and three columns in September 2019 (stations 3-5).
Columns 1 and 3-5, sampled in the northern basin of the bay at 6-9 m depths, reflect the sedimentation conditions in a semi-enclosed water area experiencing the maximum anthropogenic load. In this part of the bay, hydrodynamic processes are weakly expressed; the flux of material is determined by storm and municipal runoff. Column 2 was sampled in the southern basin at 13 m depth. This area is characterized by the increased hydrodynamic activity due to its proximity to the open sea. The main sources of material input are the local beach and storm runoff. According to the lithological description, the cores sampled in the northern basin are similar to each other (Fig. 2). The upper layer of 0-1 cm is a light-brown liquid fluff with inclusions of plant residues and shells. Below (1-11 cm layer), the sediment is represented by light-gray, gray silts, inclusions of broken shells and sand are noted unevenly, an oil smell is characteristic. Below (layer 11-19 cm), the sediment is dense, the color changes from dark gray to black, and inclusions of shell detritus are minimal. For column 2, in the surface layer (0-5 cm), an increased content of sandy material, individual shells, and shell detritus was noted, oil smell was absent. The content of gravel-sandy material slightly decreases with depth, and the proportion of dark gray silt increases.
F i g. 1. Layout of the bottom sediment sampling stations
F i g. 2 Lithological scheme of sedimentary sections of the bottom sediment columns
The average moisture content varied from 58% in 0-5 cm layer to 41% in 15-20 cm layer. It was noted that the values decrease with depth by almost one and a half times. An exception is column 4, in which the moisture content increases with depth, reaching a maximum in 5-7 cm layer, and then decreases. This may indicate gravitational sediment sliding along the slope.
F i g. 3. Vertical distribution, (Bq/kg), of the 137Cs and 40K concentrations in bottom sediments: a -at station 1; b - at station 2; c - at station 3; d - at station 4; e - at station 5
The concentration values of 137Cs and 40K in the bottom sediments varied within 8.4-132.0 and 125-742 Bq/kg ranges, respectively. The average concentration values of 137Cs and 40K were 46.5 ± 26.2 and 528 ± 158 Bq/kg, respectively.
The profiles of 137Cs and 40K vertical distribution concentration are complex (Fig. 3); local maxima or minima in the concentration of radionuclides, the nature of which is not obvious, are observed. Such a distribution of 137Cs and 40K may indicate the presence of spatial-temporal variability in the sedimentation rate and active redistribution of bottom sediments in the water area under study.
Estimation of the sedimentation rate
The profile of 137Cs concentration vertical distribution in the bottom sediments has two characteristic areas (concentration maxima) corresponding to 1963 and
1986 [12, 26]. The columns analyzed in this work are not long enough to identify the position of the nearest maximum corresponding to 1986. At the same time, the vertical profiles of 137Cs clearly indicate the areas where the concentration of this radionuclide varies within an error relative to its concentration in the upper sediment layers or reveals a tendency to monotonous growth. As an example: the lower boundary of such a section in Fig. 3, a corresponds to 14-16 cm layer; in Fig. 2, c - to 13-15 cm layer. Based on these data, it seems possible to estimate the minimum sedimentation rate, assuming that the lower boundary of the allocated areas corresponds to 1986. The results of the estimates are presented in Fig. 4. According to the obtained estimates, the sedimentation rate varies in space within 0.45-0.55 cm/year range and makes up, on average, 0.50 ± 0.06 cm/year. This result is in good agreement with the estimates obtained from the data on 90Sr vertical distribution in 2008-2012. [12]. According to the data of this work, the sedimentation rate in the Balaklava Bay varies in space within 0.52-0.55 cm/year range.
Spatial distribution of 137Cs and 40K
The averaged characteristics of 137Cs and 40K concentrations spatial distribution in bottom sediments were obtained for four intervals: 0-5, 6-10, 1115, 16-20 cm. It was taken into account that the first two columns were sampled four years earlier than the next three columns. For this purpose, based on the estimates of the sedimentation rates obtained in this work and presented in [12], it was assumed that the difference between the layers of the first two columns and
yz -1-1-1-1-
33.593° 33.595° 33.597° 33.599° 33.601 °E
Fig. 4. Spatial distribution of sedimentation rates
the next three is 2 cm (0.5 cm/year * 4 years). In other words, 0-2 cm layer of the first two columns roughly corresponds to 2-4 cm layer of the next three columns.
F i g. 5. Spatial distribution of 137Cs concentration in the layers 0-5 cm (a), 6-10 cm (b), 11-15 cm (c) and 16-20 cm (d)
According to the results obtained (Fig. 5, a), 137Cs concentration in the upper layer of bottom sediments spatially varied within 11-62 Bq/kg range and averaged 43 ± 20 Bq/kg. In the lower layers of bottom sediments (Fig. 5, b - d), an increase in the radionuclide concentration value, reaching 114 Bq/kg at a separate station, was observed. The maximum 137Cs concentration values are observed in the northern part of the bay in the entire studied range of bottom sediments, the minimum - in the southern part. Note that 137Cs content in the northern part of 198 PHYSICAL OCEANOGRAPHY VOL. 28 ISS. 2 (2021)
the bay is about 5 times higher than in the southern one. The concentration of 137Cs in bottom sediments and its spatial distribution depend on the levels of its activity in water and the suspended matter content [7, 15, 27]. The nature of the latter can also affect the value of the radionuclide relative content on the suspended matter
and, accordingly, on its flux into the bottom sediments [7, 15, 28]. According to the data of [5], the most polluted areas of the Balaklava Bay are its innermost part and the area near the wastewater outlet at the bay exit. According to the data of optical measurements, the turbidity values, which are tens of times higher than the natural norm, as well as increased concentrations of total suspended matter and dissolved organic matter, are recorded here. The paper [29] describes the features of the in the Balaklava Bay, identified on the basis of numerical modeling results. It is noted that the presence of local eddy structures in the field of currents can lead to the emergence of areas of maximum pollution
concentrations at the boundary between the central and northern parts of the bay.
The concentration of 40K in the upper layer of bottom sediments varied in space within 155-562 Bq/kg range, made up, on average, 450 ± 172 Bq/kg, and had a tendency to increase with depth (Fig. 6). The maximum values of 40K concentration were characteristic for the northern part of the bay, the minimum - for the southern part. As noted earlier, the concentration of 40K in bottom sediments and its spatial distribution depend on the sedimentating matter origin [16, 17]. The increased values of 40K concentration in the northern part of the bay indicate a relatively increased proportion of the lithogenic component in the sedimentating suspension.
The similarity in the spatial distribution of the radionuclide concentration (correlation coefficient 0.51, p = 0.027) can be due to the fact that 137Cs sedimentates mainly with the particulate matter of lithogenic origin [30, 31].
F i g. 6. Spatial distribution of 40K concentration in the layers 0-5 cm (a), 6-10 cm (b), 11-15 cm (c), 16-20 cm
The obtained values of the radionuclide concentration do not contradict the literature data. According to [12], 137Cs and 40K concentration levels in the Sevastopol Bay bottom sediments sampled in 2008-2012 varied in space within 70-80 and 281-702 Bq/kg range, respectively.
Estimation of the biogenic fraction proportion
In [16, 17], it was proposed a method that allows, based on data on 40K concentration in the bottom sediment samples, to determine the proportion of biogenic fraction (BF, %) in them using the balance equation
Clk - C BF = L Ck 100, ClkL K - ClkB K
where ClkLK and ClkBK are the values of potassium clarkes in lithogenic and biogenic fractions, equal to 24-26 and 2-3 gK/kg [18-22], respectively; CKis a potassium concentration (stable and radioactive) in the bottom sediments (in gK/kg).
It is known that the activity of 1 g of natural potassium is equal to 30.65 Bq [21]. Thus, the total potassium content in the bottom sediment samples can be obtained from the data on its concentration using the following formula:
CK = C40K 100.
K 30.65
When making estimates, the values of ClkLK and ClkBK were assumed to be
25 and 2.5 gK/kg, respectively.
According to the calculations (Fig. 7, a), the share of biogenic fraction in the upper layers of bottom sediments varied in space within 30-89% and was, on average, 46 ± 25%. The maximum values were observed in the southern part of the bay, the minimum - in the northern one. Note that the relative biogenic fraction content in the southern part of the bay was 2-3 times higher than in the northern one. There was a tendency towards a decrease in the biogenic fraction proportion in the lower sediment layers (Fig. 7, b - d).
The proportion of biogenic fraction in the bottom sediments can also be defined as the sum of the relative values of the content of organic carbon, carbonates (CaCO3) and silicates (SiO2) [17]. For individual layers of the column selected at station 2 (Fig. 1), these parameters were determined and the proportion of biogenic fraction was estimated.
The analysis of the vertical distribution features of the studied parameters revealed the fact that Corg content in the surface layer is minimal (0.48%), its concentrations increase with depth and are 2.43 and 2.46% at 7 and 11 cm horizons, respectively. Conversely, the carbonate content decreases with depth from 79% in 0-2 cm layer to 48% in 10-12 cm layer. SiO2 concentrations increase with depth from 14 to 21% (Fig. 8, a).
F i g. 7. Spatial distribution of the biogenic fraction in bottom sediments in the layers 0-5 cm (a), 610 cm (b), 11-15 cm (c), 16-20 cm (d)
F i g. 8. Vertical distribution of the biogenic fraction (%) in bottom sediments calculated by the direct and indirect methods
According to the obtained results (Fig. 8, b), there is a qualitative and quantitative correspondence between the values of the biogenic fraction of bottom sediments obtained by direct (Corg + CaCO3 + SiO2) and indirect (according to 40K data) methods for the upper layers of sediments. In the lower layers of bottom sediments, the estimates obtained by the indirect method differ from the results of direct measurements by, on average, 18 ± 8%.
Conclusions
According to the obtained results, 137Cs and 40K concentration in the upper 5-cm layer of bottom sediments varied in space within 11-62 and 155-562 Bq/kg ranges, respectively. The average concentration values were 43 ± 20 and 450 ± 172 Bq/kg for 137Cs and 40K, respectively. The maximum values of the radionuclide concentration were characteristic for the northern part of the bay, the minimum - for the southern part. Such a spatial distribution of the radionuclide concentration may be due to the features of water circulation in the bay, as well as variability in the field of suspended matter concentration. There was a tendency towards an increase in the values of the radionuclide concentration with depth.
Based on the data on 137Cs vertical distribution, quantitative estimates of the minimum sedimentation rate in the area under study, which were, on average,
0.50.± 0.06 cm/year, were obtained.
Quantitative estimates of the biogenic fraction proportion in the bottom sediments of the area under study were also obtained, and it was shown that it varied in space within 30-89% range and was, on average, 46 ± 25%. The maximum values were noted in the southern part of the bay, the minimum - in the northern one. A comparison of the biogenic fraction values obtained by direct and indirect methods has been carried out, and their qualitative and quantitative correspondence in the upper layers of bottom sediments has been demonstrated.
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About the authors:
Dmitry A. Kremenchutskii, Research Associate, Marine Hydrophysical Institute of RAS (2 Kapitanskaya str., 299011, Sevastopol, Russian Federation), ORCID ID: 0000-0002-8747-6612, d.kremenchutsky@gmail.com
Konstantin I. Gurov, Junior Research Associate, Marine Hydrophysical Institute of RAS (2 Kapitanskaya str., 299011, Sevastopol, Russian Federation), ORCID ID: 0000-0003-3460-9650, ResearcherID: L-7895-2017, gurovki@gmail.com
Contribution of the co-authors:
Dmitry A. Kremenchutskii - formulation of purposes and objectives of the study; analysis of literature data; determination of the 137Cs and 40K concentration in bottom sediments; qualitative analysis of the results and their interpretation; discussion and analysis of the obtained results; preparation of the text of the paper
Konstantin I. Gurov - formulation of purposes and objectives of the study; analysis of literature data; determination of the concentration of organic carbon, carbonate content and silicates in bottom sediments; participation in the discussion of the paper materials; analysis and preparation of initial conclusions
All the authors have read and approved the final manuscript.
The authors declare that they have no conflict of interest.
