RU2758337C1 - Method for conducting environmental monitoring using aquaculture - Google Patents

Abstract

FIELD: measuring.

SUBSTANCE: invention relates to the field of ecology, environmental protection, and pertains to a method for conducting environmental monitoring of the water area of the Björkösund Strait of the Gulf of Finland. The substance of the method consists in taking samples of seawater, bottom sedimentation, phyto- and zooplankton from at least 2 different sites. The collected samples are then analysed, the results of the analysis are compared with the standard indicators of the water area, long-time archival data, and indicators of the adjacent water areas. The muscle tissue of hydrobionts in the form of zebra mussel Dreissena polymorpha, and/or rainbow trout Parasalmo mykiss, and/or Baltic whitefish Coregonus lavaretus is examined for the content of petroleum products. A conclusion is made on the ecological state of the marine ecosystem based on the results of the examination of hydrobionts, sea water, bottom sedimentation, phyto- and zooplankton. If the mass fraction of petroleum products in the muscle tissue samples of the hydrobionts is greater than 150 mg/kg, a conclusion is made that the water area of the Björkösund Strait of the Gulf of Finland could have been contaminated with petroleum and petroleum products.

EFFECT: use of the method provides a possibility of conducting environmental monitoring of the water area of the Björkösund Strait of the Gulf of Finland with high accuracy.

3 cl, 4 tbl, 3 ex

Description

The invention relates to methods for assessing the state of ecosystems of sea areas in areas of influence of sources of pollution by oil and oil products and can be used for integrated environmental monitoring of the state of the marine ecosystem of the Bjerkesund Strait of the Gulf of Finland of the Baltic Sea.

The known method of biological monitoring based on bioindication (AS RF 2357243, IPC G01N 33/00 (2006.01) G01N 33/18 (2006.01)). The method of biological monitoring based on bioindication provides for the sampling of aquatic animals, the establishment of their abundance, biomass, species diversity, distribution boundaries and registration of the functional parameters of the organism, as well as the main hydrological and hydrochemical parameters, determination on their basis of the spatial and temporal trends in the change in the indicator biological parameters in gradient of environmental factors. Biomonitoring is carried out continuously by means of multilevel bioindication, using several levels of organization of biological systems and measuring indicator parameters with different discreteness. At the same time, the results of operational bioindication according to the physiological and behavioral reactions of the body in natural conditions characterize changes in the state of the environment in the interval from 1 hour to 6 months, short-term bioindication - according to the parameters of populations of certain species - characterize the range from 0.5 to 3 years, long-term bioindication to at the community level, changes are assessed at intervals of 3 or more years. The assessment of changes in the environment is carried out by comparing with background and reference trends of indicator parameters.

One of the disadvantages of this method is the impossibility of using it to assess the ecological state of the water area.

Another disadvantage of this method is the lack of control over the physiological state of individual individuals, which is especially important in the short term (for a short - from several hours to several days - exposure to pollutants).

Also, the disadvantages include its applicability only in cases where there are stable natural settlements of species that are sensitive to pollution on the site under consideration. Otherwise, a significant decrease in the efficiency of the method is possible.

The closest in technical essence to the claimed technical solution is a method of biological monitoring of the state of ecosystems in the water area of Kozmina Bay using marine aquatic organisms as test objects (patent RU 2 670 208 C1 IPC G01N 33/18, publ. 19.10.2018). In this method, the sea scallop Mizuhopecten yessoensis, the gray sea urchin Strongylocentrotus intermedins, the black sea urchin Mesocentrotus nudus or meroplankton are used as hydrobionts. As part of the monitoring, histomorphological tissue analysis (lipofuscin content is determined) of the seaside scallop Mizuhopecten yessoensis is carried out. They also determine the size of the scallop Mizuhopecten yessoensis, cultivated on the plantation in the water area of the bay, or the seaside scallop Mizuhopecten yessoensis, inhabiting natural settlements, and compare the data obtained with the standard indicators or compare with the standard indicators, which are formed on the basis of average indicators for 3-10 years. for individuals living in natural settlements. In addition, the mass and size of the gray sea urchins Strongylocentrotus intermedius or the black sea urchins Mesocentrotus nudus are determined, or the quantitative composition of meroplankton is determined and compared with the standard indicators, which are formed on the basis of average indicators for 3-10 years. When the quantitative, size and sex-age indicators of marine aquatic organisms change in comparison with the standard indicators, a conclusion is made about the influence of pollution sources on the state of marine ecosystems and about the ecological state of the water area of Kozmina Bay.

The disadvantage of the biological monitoring method is the use of aquatic organisms as test objects capable of growing and developing normally in the sea basins of the Far Eastern region, which makes it impossible to use this method in waters characterized by a lower salinity level (including the water area of the Gulf of Finland Baltic).

The problem to be solved by the claimed invention is to increase the reliability of assessing the level of pollution of the aquatic environment with oil and oil products during environmental monitoring of marine ecosystems with a low level of salinity, namely the section of the Bjerkesund Strait of the Gulf of Finland of the Baltic Sea.

The technical result achieved during the implementation of the claimed invention is to increase the efficiency of environmental monitoring of the state of marine ecosystems for pollution by oil and oil products through the study of sea water, the study of bottom sediments, phyto- and zooplankton, control of the content of pollutants in marine aquatic organisms, namely river Dreissena Dreissena polymorpha and / or rainbow trout Parasalmo mykiss and / or Baltic whitefish Coregonus lavaretus.

The technical result is achieved due to the fact that the method of environmental monitoring of the water area of the Bjerkezund Strait of the Gulf of Finland using aquaculture facilities with the frequency of hydrobiological monitoring of aquatic organisms contained on the plantation of aquaculture facilities contains stages at which:

- sampling of seawater, bottom sediments, phyto- and zooplankton is carried out from at least 2 different points, where the first point is the place of direct placement of aquatic organisms, the second and subsequent points are a place at a distance of at least 3.5 km from the place of placement of aquatic organisms while sampling is carried out annually in June and September;

- analyze the samples taken;

- compare the results of the analysis with the normative indicators of the water area, long-term archived data and indicators of the adjacent water areas;

- examine the muscle tissue of aquatic organisms in the form of the river Dreissena Dreissena polymorpha and / or the rainbow trout Parasalmo mykiss and / or the Baltic whitefish Coregonus lavaretus for the content of oil products;

- make a conclusion about the ecological state of the marine ecosystem based on the results of the study of hydrobionts, sea water, bottom sediments, phyto- and zooplankton;

- in the presence of a mass fraction of oil products in the samples of muscle tissue of aquatic organisms of more than 150 mg / kg, it is concluded that the water area of the Bjerkesund Strait of the Gulf of Finland could be contaminated with oil and oil products.

The development and refinement of the invention is the following feature:

- Dreissena Dreissena polymorpha and / or rainbow trout Parasalmo mykiss and / or Baltic whitefish Coregonus lavaretus are placed in a submerged cage.

For the maintenance of biological test objects, a submersible cage device is used, which includes cages-aviaries (3 pcs.), Inside which rainbow trout and / or Baltic whitefish are contained in the water column. Each cage-aviary is a permeable mesh chamber that does not touch the bottom. Thus, fish are kept in the natural conditions of the water area and at the same time in the immediate vicinity of objects (port facilities for transshipment of oil / oil products) that can have a negative impact on the marine ecosystem of the Bjerkesund Strait of the Gulf of Finland.

Due to the fact that the contained groups of fish do not have the opportunity to independently obtain food (feed on bottom organisms, carry out hunting, etc.), they organize periodic (depending on the season, water temperature, current fish size, etc.) supply of specialized food intended for commercial fish farming.

River Dreissena is also located on submerged cage structures by self-settling.

Studies of seawater include such indicators as temperature, pH, BOD5, suspended solids, oil products, ammonium nitrogen, nitrate nitrogen, nitrite nitrogen, total phosphorus, dissolved oxygen.

Bottom sediment studies include indicators such as ammonium nitrogen, phosphorus and oil products.

Research of phyto- and zooplankton includes determination of species composition, total abundance and biomass, abundance and biomass of the main taxonomic groups and common species.

Comparing the results of seawater samples, studies of bottom sediments and phyto- and zooplankton with standard indicators and long-term archival data, a conclusion is made about the influence of pollution sources on the state of marine ecosystems and on the ecological state of the marine ecosystem of the Bjerkesund Strait of the Gulf of Finland in the Baltic Sea.

Sampling for the study of seawater, bottom sediments, phyto- and zooplankton is carried out at least from two points: the first - directly at the location of the submersible cage device, the second and subsequent at a distance of at least 3.5 km from the location of the submersible cage devices.

Thus, the sampling of seawater, bottom sediments and phyto- and zooplankton near the regional specially protected natural area makes it possible to reliably assess the level of pollution / state of one or another component of the marine ecosystem in the area of port facilities.

Sampling of seawater and bottom sediments is carried out twice a year (annually in June and September) simultaneously with the sampling of phyto- and zooplankton and is timed to the pronounced seasonal nature of the development of phyto- and zooplacton. The seasonal nature of the development of plankton in the Gulf of Finland is determined by the temperature regime, illumination, supply of nutrients, etc. Sampling during this period will make it possible to assess the dynamics of phyto- and zooplankton development during the growing season.

Sampling of aquatic organisms (river Dreissena Dreissena polymorpha and / or rainbow trout Parasalmo mykiss and / or Baltic whitefish Coregonus lavaretus) is carried out at the same time (in June and September) and is carried out only at one point - directly at the site of the landfill.

To assess the mass fraction of petroleum products, the muscle tissue of aquatic organisms (river zebra mussel Dreissena polymorpha and / or rainbow trout Parasalmo mykiss and / or Baltic whitefish Coregonus lavaretus) is examined for the content of petroleum products in it according to PND Φ 16.1: 2.2.22-98 the share of petroleum products in mineral, organogenic, organomineral soils and bottom sediments by IR spectrometry ”.

If there are more than 150 mg / kg of oil products in the muscle tissue samples of aquatic organisms, it is concluded that the water area of the Bjerkesund Strait of the Gulf of Finland could be contaminated with oil and oil products.

Based on the results of a comprehensive study and monitoring of various components of the environment, a conclusion is made about the ecological state of the water area of the Bjerkesund Strait of the Gulf of Finland, in particular, about the pollution of the water area with oil and oil products.

The implementation of the method is confirmed by the examples below, but is not limited to them.

Example No. 1 (research of sea water)

Water sampling was carried out in the summer and autumn of 2017, as well as in the fall of 2019 from a depth of 0.5 meters.

The obtained results of hydrochemical studies of seawater samples taken in 2017 (before the submersible cage device was placed in the Bjerkesund Strait of the Gulf of Finland) and in 2019 (after the submersible cage device was placed in the Bjerkesund Strait of the Gulf of Finland) are presented in Table 1.

The data given in Table 1 indicate that the values of the pollutants (indicators) selected for the analysis do not exceed the standards (maximum permissible concentrations) for water bodies of fishery significance of the highest and first categories established by the "Standards for the quality of water bodies of fishery significance" (approved by order of the Ministry of Agriculture of the Russian Federation No. 552 dated 13.12.2018). It is important to note that the established standards are observed both before the placement of the submersible cage device (with populated aquaculture facilities) in the water area (installation period - May - August 2019) and after. The values of the selected indicators are also comparable at the location of the submersible cage device (point 1) and at the control background (point 2) point located at a considerable distance from the oil / oil products transshipment facilities, as well as the indicators of the adjacent water areas.

Example No. 2 (research of phytoplankton)

Phytoplankton samples are taken with a bathometer in the trophogenic layer (to a depth corresponding to three times the transparency along the Secchi disk) every meter. Water taken in equal amounts from each layer is poured into one container, from which, after mixing, a sample of 500 ml is taken and fixed with Utermel's solution. Samples are concentrated by settling in accordance with the "Methodological Recommendations for the Collection and Processing of Materials in Hydrobiological Research in Freshwater Bodies." Phytoplankton and its products ”. The number of phytoplankton is counted in a 0.01 ml Najotte chamber. Biomass is determined by the counting-volumetric method according to the "Methodology for studying biogeocenoses of inland water bodies". The taxonomic (species) composition of phytoplankton is determined during the processing of quantitative samples. Individual abundance is determined in phytoplankton samples for all species. To evaluate the use of phytoplankton abundance number indicators (tys.kl. / l) and biomass (mg / ^m3) species specific taxonomic groups and phytoplankton in general.

The abundance (thousand cells / L) of phytoplankton and its systematic groups in the water area of the Bjerkesund Strait of the Gulf of Finland is presented in Table 2.

The biomass (mg / m ³ ) of phytoplankton and its systematic groups in the water area of the Bjerkesund Strait of the Gulf of Finland is presented in Table 3.

Quantitative parameters of the phytoplankton in the water area Strait Berkezund Gulf during the study period in 2017 g. ranged from 1 122 to 27 875 tys.kl / L (number) and from 132 to 2598 g / m ³ (biomass) (Table 2, 3), which was consistent with similar data from earlier studies. The abundance and biomass of phytoplankton were on average lower in June than in September - 21 times and 17 times, respectively. The maximum biomass was recorded in September in the open part of the strait. In general, the seasonal values of quantitative indicators did not differ significantly among themselves, which was also noted earlier in the summer season. The similarity of the obtained data on the abundance and biomass of phytoplankton with similar data from earlier studies and indicators of adjacent water areas indicates a stable state of the water area (including the absence of significant pollution that could negatively affect the indicators of abundance and biomass).

Example No. 3 (zooplankton research)

Zooplankton samples are taken with the Judy quantitative plankton net (inlet with a diameter of 18 cm, gas sieve No. 64) from the bottom to the surface. Samples are fixed with 4% formalin.

The material is processed by the counting-weight method with the determination of the size-age composition of the population of each species in accordance with the "Methodological recommendations for the collection and processing of materials during hydrobiological research in freshwater reservoirs. Zooplankton and its products ”.

Samples are concentrated to a volume of 100 ml and counted in a Bogorov chamber in portions of 1-2 ml, followed by recalculation for the entire sample volume. Large forms are calculated in the entire volume of the sample. Organisms are identified by species.

The biomass of individual species is determined using the individual weights of organisms, calculated using the formula for the dependence of body weight on its length or similar calculated tabular data for these species. As the basic data for evaluating the zooplankton population abundance use indicators (tys.ekz. / M ³⁾ and biomass (g / m ³⁾ species major taxonomic groups (rotifers, copepods, cladocera, etc.) and zooplankton as a whole. Cameral processing of the material is carried out using optical observation equipment (binoculars, microscopes).

Abundance (N, thousand cells / m ³ ) and biomass (B, g / m ³ ) of zooplankton in the water area of the Bjerkesund Strait of the Gulf of Finland in 2017, 2019 shown in Table 4.

Analysis of the collected data on the state of various components (water, bottom sediments, phyto- and zooplankton, hydrobionts) of the marine ecosystem of the Bjerkesund Strait of the Gulf of Finland, their comparison with standardized indicators (for studies of sea water for the content of certain pollutants) and indicators typical for a marine ecosystem not exposed to anthropogenic impact (studies of seawater, bottom sediments, phyto- and zooplankton at point 2 near a specially protected natural area) and indicators of adjacent water areas allows us to conclude that the marine ecosystem of the Bjerkesund Strait in the Gulf of Finland of the Baltic Sea is favorable.

Thus, the following factors testify to the favorable ecological state of the water area of the Bjerkezund Strait of the Gulf of Finland in the Baltic Sea in the area of the location of production facilities for transshipment of oil / oil products:

- standard indicators of the content of pollutants in seawater samples taken at the location of the landfill for aquaculture facilities;

- comparable indicators of the content of pollutants in bottom sediment samples taken directly at the site of the landfill of aquaculture facilities and at a distance;

- correspondence of the quantitative and qualitative composition of phytoplankton and zooplankton to the background indicators of the adjacent water areas and long-term statistical data;

- absence of oil products (with a mass fraction of oil products more than 150 mg / kg) in the tissues of the river Dreissena Dreissena polymorpha and / or the rainbow trout Parasalmo mykiss and / or the Baltic whitefish Coregonus lavaretus.

The proposed method for environmental monitoring using aquaculture facilities allows for effective monitoring of the state of the aquatic environment and recording the possible impact of volley or chronic pollution by oil and oil products.

Claims (8)

1. A method for environmental monitoring of the Bjerkesund Strait of the Gulf of Finland, including the following stages: - carry out sampling of seawater from at least 2 different points, where the first point is the place of direct placement of aquatic organisms, the second and subsequent points are a place at a distance of at least 3.5 km from the place of placement of aquatic organisms, while sampling is carried out annually in June and September; - analyze the samples taken; - compare the results of the analysis of seawater samples with the standard indicators for water bodies of fishery significance; - examine the muscle tissue of aquatic organisms in the form of the river Dreissena Dreissena polymorpha, and / or the rainbow trout Parasalmo mykiss, and / or the Baltic whitefish Coregonus lavaretus for the content of oil products; - in the presence of pollutants in the seawater samples, the concentrations of which exceed the standard indicators for water bodies of fishery significance, as well as in the presence of oil products with a concentration of more than 150 mg / kg in the muscle tissue samples of aquatic organisms, it is concluded that the water area of the Bjerkesund Strait of the Gulf of Finland contaminated with oil and oil products. 2. A method according to claim 1, characterized in that the river Dreissena Dreissena polymorpha and / or the rainbow trout Parasalmo mykiss and / or the Baltic whitefish Coregonus lavaretus are placed in a submersible cage device. 3. The method according to claim 1, characterized in that the study of seawater includes the determination of such indicators as temperature, hydrogen index (pH), biochemical oxygen consumption for 5 calendar days (BOD ₅ ), suspended solids, oil products, ammonium nitrogen, nitrogen nitrate, nitrite nitrogen, total phosphorus, dissolved oxygen.