Russian Rivers Research Articles

Genetic Variation and Phylogenetic Relationships of Northern Pike (Esox lucius L.) Populations from Some Rivers of Russia

Genetic Variation and Phylogenetic Relationships of Northern Pike (Esox lucius L.) Populations from Some Rivers of Russia

Spatio-Temporal Variability of Water Temperature of Arctic Rivers in Russia over the Past 60 Years

This article presents the findings of a comprehensive statistical analysis based on one of the largest and most up-to-date datasets on average monthly water temperatures at 286 hydrological stations from 1961 to 2021. Through this analysis, a detailed examination of the factors influencing temperature formation in different landscape-diverse regions in the Russian Arctic has been conducted. It has been determined that air temperature plays a crucial role in determining water temperature, although its influence is constrained by geographical factors, primarily geographical latitude. An analysis of discontinuities in uniformity and the presence of trends was carried out, along with a regression analysis of the relationships between air and water temperatures. The results of estimating changes in river water temperature were simultaneously compared both with respect to generally accepted climatic periods (1961–1990 and 1991–2020) and with respect to revealed change point years. The results of the statistical analysis indicate a relatively slow increase in water temperature in the Arctic rivers of Russia over the past 60 years, by 0.11–0.74 K/decade. These changes are mainly due to changes in air temperature (about 70% of cases), which in turn are influenced by the altitude of the location of the objects and other local factors.

Особенности длительных фаз повышенного/пониженного стока Енисея (до впадения Ангары)

The article presents the results of studying long phases of decreased and increased conditionally natural annual and seasonal water flow of the Yenisei River at Kyzyl Сity, Nikitino and Bazaikha settlements. The retrieval of long-term water flow time series (with excluded anthropogenic changes) at Nikitino and Bazaikha settlements is based on the transformation of the annual hydrograph of daily water discharges using the Kalinin–Milyukov method. Long phases of annual and seasonal water flow were revealed on the basis of cumulative deviations curves. For the entire observation period of 1936–2021, two long contrasting phases were revealed for winter flow, which are typical for many studied rivers in Russia. At the same time, long-term changes in runoff of the combined season of snowmelt flood and summer-autumn rain floods, as well as annual water flow, were characterized by a four- to five-fold change in contrasting phases. The duration of contrasting phases reached more than 50 years, and the phases of decreased water flow were significantly longer than the phases of increased flow. The difference in the water flow of contrasting phases of the Yenisei River is most significant for winter flow and is on average equal to 20–40 %, and the one for annual flow and flow in the season of snowmelt floods and summer-autumn rain floods is 9–12 %.

Развитие модели динамики снежного покрова Гидрометцентра России

Conceptual models of runoff formation used in the operational practice of hydrological forecasting by the Hydrometeorological Center of Russia include simplified parameterization of snow cover dynamics based on the use of snow cover melting coefficient, water-retaining capacity of snow and secondary freezing of meltwater in case of return of negative air temperatures. This schematization of the process is well established for the reliable calculation of the snow water equivalent for subsequent use in the calculation of meltwater inflow to the catchment surface and the calculation of streamflow characteristics. At the same time, the lack of calculation of snow density and snow height in the used schematization restricts the use of schemes for calculating of soil freezing depth in hydrological models, which seems to be extremely important for modelling runoff on mid-latitudes rivers, i.e. for the most Russian rivers. To overcome this disadvantage, the snow density and snow height parameterization was added to the calculation scheme of the model, which was verified using Roshydromet’s snow measurement routes data and shown a good and satisfactory quality of modeling of model characteristics.

Bayesian estimates for changes of the Russian river runoff in the 21st century as based on the CMIP6 model ensemble simulations

Based on ensemble calculations with the CMIP6 (Coupled Model Intercomparison Project, phase 6) climate models and using Bayesian averaging, an analysis was conducted on the changes in the 21st century runoff of several Russian rivers – the Volga, Ob, Yenisei, Lena, Amur, and Selenga. Bayesian weights considered the quality of models’ reproduction of runoff (long-term average runoff, linear runoff trend over the time interval with available runoff observations, interannual and interdecadal variability). The quality of runoff characteristics reproduction by individual models in the CMIP6 ensemble varies most significantly for the long-term average runoff, runoff trend, and, to a lesser extent, for interannual variability. In the 21st century, the ensemble average runoff increases for most of the analyzed rivers, except for the Volga. This increase is more pronounced under scenarios with larger anthropogenic impacts. It is especially significant for the SSP5-8.5 scenario (Shared Socioeconomic Pathways, 5-8.5), under which the runoff increase trend from 2015 to 2100 relative to its current long-term average is (10 ± 4)% for the Ob, (16 ± 3)% for the Yenisei, (39 ± 7)% for the Lena, (36 ± 7)% for the Amur, and (18 ± 6)% for the Selenga. The primary reason for the change in ensemble average runoff in the 21st century in models under all SSP scenarios is the change in precipitation. Accounting for differences in model quality in reproducing river runoff on average for 2015–2100 reduces inter-model deviations relative to the corresponding values with uniform weighting of model results by 6–26%, depending on the SSP scenario and river basin.

Анализ аномалий температуры воздуха и количества осадков в пределах южного и западного побережий Каспийского моря в период 1961-2023 гг

Introduction. The issue of climate change has been an important subject of many studies in recent decades because of its far - reaching negative consequences for the socio - economic development of regions, causing unfavourable phenomena and processes and affecting the transformation and restructuring of the functioning of landscapes in general. Materials and methods. This article deals with the issue of studying climate change trends by analysing the anomalies of air temperature and precipitation within the southern and western parts of the Caspian Sea watershed on the example of seven key areas of the selected river basins. The object of the study is the territory of the southern and western coast of the Caspian Sea catchment with the basins of medium and small rivers (in particular, the basins of the Gorgan and Heraz rivers in Iran, the Karachay and Atachay rivers in Azerbaijan, and the Sulak, Sunzha, and Ulluchay rivers in Russia). To identify and evaluate anomalies, several key areas were identified, within which statistical anomalies were calculated, using the Z-analysis method (standardized anomaly method). Two types of anomalies were calculated: for the entire territory of the southern and western coasts of the Caspian Sea, taking into account elevation zones, and for the key sections of river basins. Results. One of the main results of the study was the identification of three key time periods: 1961-1981, 1982-2004 and 2005-2023, which are characterised by multidirectional changes in the direction of trends, as well as the assessment of climate change in the study region over 63 years. Graphical material in the form of maps describing the zones of distribution of anomalies of mean multiyear temperature and precipitation anomalies within the southern and western parts of the Caspian Sea watershed area was prepared. Discussion. It was found that the higher the altitude, the more pronounced are the positive temperature anomalies, while negative anomalies are present only up to altitudes of 3000 m. Negative temperature anomalies are predominant in the Caucasus, and positive temperature anomalies are predominant in the area of the Elburs mountain system. Negative precipitation anomalies are detected only at altitudes of 2000 m and above. Negative precipitation anomalies are found only at altitudes above 2000 m (occurring in small patches on the southern border of the Caspian Sea catchment, closer to the northern slopes of the Elburs mountain system), while positive anomalies appear everywhere, but mainly on the northern slopes of the Caucasus Mountains and within the southern and south - western coast of the Caspian Sea. On average, the volume of long - term precipitation averages that correspond to anomalous values decreased by 18 mm for positive and 41 mm for negative anomalies during the period under consideration. Positive temperature anomalies are noted only in the Gorgan River basin, and negative ones - in the southern part of the Sulak River basin. The tendency of decreasing the zone of positive temperature anomalies in the river basins was revealed. Negative anomalies of mean multiyear precipitation are not found within the studied river basins, but positive anomalies are found within the Sunzha River basin, as well as slightly north of the Heraz River basin, closer to the coastal zone of the Caspian Sea. Conclusions. The most significant temperature increase on the southern and western coasts of the Caspian Sea was recorded over the last 19 years (2005-2023), where mean multiyear temperatures increased by an average of 1.1°C and mean multiyear precipitation decreased by an average of 35 mm. Suggestions for practical application and direction for future research. The results obtained in this article can serve as valuable information for further study of climate change in the Caspian region.

Vertical riverbed deformations due to in-stream mining

Comparison of the longitudinal profile of a number of lowland rivers in Russia, revealed their deformation due to a half-century of sediment flux and channel morphology adjustment. This problem remains relevant both in theoretical and practical aspects, especially for rivers where long-term mining of sediments from the stream beds extends from kilometers to tens of kilometers. The removal of a large amount of alluvial material from the sediments transport and changes of the riverbed morphometric characteristics triggered the process of leveling the sediment transport capacity along the river by the scour and resulted in a lowering of the bottom and water surface. The intensity of the incision reached 3–8 centimeters, and its progradation along the river 400–700 meters per year. Retrogressive erosion is pronounced, while progressive one is less pronounced, because partially replaced by mechanical removal of alluvial material. Over the past decades the shape of the longitudinal profiles changed from convex or straight to concave with no signs of recovery, despite the mining has been quite moderate for last 30 years or completed on the explored rivers.

Microplastics in Russian Freshwater Systems: a Review

Contamination of environment by plastic debris has already become a worldwide problem due to the global production of polymers and the further accumulation of waste. Microplastic particles (<5 mm) have been found almost everywhere. Despite the significant number of publications devoted to the microplastic pollution in freshwater and marine environments, in the review articles around the world freshwater systems the Russian territory is a white spot. The article provides the summary of studies investigating microplastics (MP) in Russian lakes and rivers, the determination of concentrations, type and composition of polymer particles and also possible sources of plastic contamination. The map of the MP distribution in Russian freshwater systems is presented. The concentration of microplastics in freshwater system varies greatly, e.g., in lakes from 0,27 items/m3 in Lake Baikal to (4-26)∙103 items/m3 in the Altai lakes of Western Siberia; in large Russian rivers measured polymer content varies by three orders of magnitude, from parts of items/m3 in the Volga River to hundreds of items/m3 in the Upper Ob. Significantly higher concentrations of MP are found in the bottom sediments of rivers and lakes, exceeding polymer concentrations in surface water by several orders of magnitude. Thus, bottom sediments are able to accumulate significant amounts of MP.

INVINMENTAL PROBLEMS OF REGIONAL ECONOMY OF SOME TERRITORIES OF THE RUSSIAN FEDERATION

The article discusses the most pressing problems of reducing the quality of some components of the environment (natural) in federal districts — macroregions of the Russian Federation, which require their solution. An analysis of the level of atmospheric air pollution by emissions of harmful and polluting substances from stationary sources, based on data from annual state statistical reporting, showed that over the previous 11 years, the minimum volume of emissions was noted in the North Caucasus macroregion, and the maximum in the Siberian macroregion. The next one is the problem of pollution of the seas of the Arctic Ocean with wastewater from Russian rivers flowing into these seas, containing such a substance that pollutes the water basin of the entire planet as microplastic. The largest volume of such polluted waters was noted in the Arkhangelsk region (Northwestern macroregion), Krasnoyarsk region and Tomsk region (Siberian macroregion), and the smallest in the Kostroma region (Central macroregion) and the Republic of Tyva (Siberian macroregion). The problem of preserving and restoring such a component of the natural environment as forests, including in the protected zone of Lake Baikal and the volcanoes of the Kamchatka Peninsula, is debatable. An analysis of plans for the construction of several waste processing complexes and waste processing plants in the North-Western macroregion is aimed at identifying possibilities for solving the problem of a future reduction in the volume of such a component of the natural environment as anthropogenic waste. To solve some problems, the authors propose specific measures.

Dynamic changes in the microbiota of the middle Volga: a three-year study

The Volga River is one of the largest rivers in Russia, which plays an important role in the life of many plants, animals and humans. Annual research of the river microbiota is an integral part of the work to preserve the river ecosystem and ensure its sustainable development. The work analysed the composition of the microbiota using high-throughput sequencing methods, as well as physicochemical indicators over a three-year period from 2017 to 2019. A stable microbiota community and changes in chemical oxygen consumption and microbial diversity of the Volga River community were revealed.

Содержание ртути в рыбе, выловленной ниже целлюлозно-бумажного комбината в Северной Двине

Subarctic Russian rivers tend to have swampy watersheds with a high content of hydro­gen ions and humic substances. These conditions are favourable for the formation of bioavail­able mercury. Thus, even background mercury concentrations can pose a danger to aquatic organisms. The Northern Dvina River attracts particular attention regarding mercury pollu­tion due to the presence of pulp and paper mills in the area. These mills have historically uti­lised mercury in their production processes. This study aims to analyse the mercury content in commercially important fish species living in the mouth of the Northern Dvina River. The content and distribution of mercury in tissue samples of various fish species were determined to provide insight into components of the mercury cycle in the study area. Lower mercury levels in pristine areas of the Russian subarctic showed the role of aquatic organisms as indicators of the biogeochemical cycle of mercury migration in northern freshwater areas. This study provides new scientific data on the levels of mercury found in fish from the Northern Dvina, particularly those in its estuary zone affected by the pulp and paper industry. The content and distribution of mercury were characterised using the most common fish species as an example. The difference was shown between mercury accumulation in different conditions and areas, with an analysis of relevant factors carried out.

PROBLEMS OF THE RECLAMATION AND WATER MANAGEMENT COMPLEX THE LOWER DON IN THE CURRENT CLIMATIC CONDITIONS

Long-term climatic changes have led to a decrease in the water content of a number of Russian rivers. In the pool of R. The Don phase of low water content has been going on since 2007. In addition, due to climate warming, significant fluctuations in the intra-annual hydrological regime are observed. The climatic situation and high anthropogenic pressure on water resources complicate the conditions for the development of irrigated agriculture. At the same time, there is an obvious need to increase the area of irrigated land on the Lower Don. The authors of the article propose a number of measures that contribute to the effective development of the Nizhny Don water management complex against the background of water scarcity. The possibility of replenishing the flow of the Don River is considered. In the conditions of the Azov-Don basin, a geoinformation web-based decision support system for integrated management of the reclamation and water management complex developed at the Federal Scientific Center for Hydraulic Engineering and Melioration named after A.N. Kostyakov can be used. The proposed hydrodynamic model of the Lower Don can be used in order to form optimal modes of operation of the Tsimlyansk hydroelectric complex in the interests of agricultural and fisheries water users.

Genetic Diversity of the European Perch (Perca fluviatilis Linnaeus, 1758) from Some Rivers of Russia

Genetic Diversity of the European Perch (Perca fluviatilis Linnaeus, 1758) from Some Rivers of Russia

Integral Assessment of Water Quality in the Volga River Basin According to Monitoring Data in the 21st Century

The Volga River has been the main Russian river for several centuries. The river, originating on the Valdai Hills, crosses several natural and climatic zones on its way to the Caspian Sea: from the southern taiga to the dry steppes of the Caspian Lowland. According to the latest data, 45% of industrial enterprises and 50% of agricultural production in Russia are concentrated in the river basin. The anthropogenic load on the river with its tributaries and their basins significantly exceeds the load on other large Russian rivers. The largest contaminated wastewater volumes fall on the share of Moscow, Samara, Nizhny Novgorod, Yaroslavl, Saratov, Ufa, Volgograd, Balakhna, Tolyatti, Ulyanovsk, Cherepovets, Naberezhnye Chelny and other large cities. All these negative processes occur against the background of ongoing climate change. The article analyzes the Roshydromet hydrochemical monitoring data of river waters in the Volga River basin for the 2000–2021 period by water bodies and federal subjects. Regardless of the year water content, almost 70% of hydrochemical monitoring stations in the Volga River basin correspond to the third quality class (“polluted”). An integral assessment of the water quality in the Volga River basin shows that the situation has not changed significantly since the end of the last century. To improve the ecological condition of the Volga River basin, it is necessary to implement a set of measures for the protection and reproduction of water resources in catchment areas, rationalize water use systems, and reduce the volume of freshwater intake. Reducing water consumption is a necessary condition for reducing the wastewater volume discharged and, consequently, the number of pollutants contained in it. One of the problems is that almost all types of water use harm the surface waters’ natural quality, including the Volga River basin.

Анализ вероятности метаморфизации ионного состава ультрапресных вод арк­тических рек России

For the first time, the classification of the ionic composition of ultra-fresh waters of the Arctic rivers in Russia has been carried out in a long-term aspect and in view of seasonality. The features of the ionic composition of ultra-fresh waters of the Arctic rivers have been considered, the class, group and type of river waters have been established according to the classification of O. A. Alekin. The chemical composition of the ultra-fresh rivers of the Russian Arctic zone is characterized by great diversity. These rivers vary from the most simple bicarbonate-calcium waters of the second type to sulfate or hydrocarbon-sulfate waters of a complex cationic composition. For the estuarine sections of the Virma, Kolos-Yoki, Teriberka and Ura Rivers variability manifests itself in a simplification of the chemical composition. For the Pravaya Khetta, Sede-Yakha and Nadym Rivers, changes in the ratios between cations and anions have been revealed. For the Indigirka, Yana Rivers and its tributaries, changes have been noted only in the anionic composition. It is shown that it is for these rivers that the metamorphization of river waters is possible. Most of the river sections with a high probability of metamorphization of the ionic composition of water are confined to the West Siberian part of the Russian Arctic zone. This is due to a higher anthropogenic load and a high degree of development of this area. For these sections of the rivers, the revealed metamorphization is of a technogenic nature. The metamorphization process of ultra-fresh river waters in the direction of changing the hydrocarbonate class to the sulfate or chloride class can cause the appearance of hydrochemical anomalies in the content of the main ions.

Экономические аспекты перспективного использования возобновляемых энергоресурсов традиционными технологиями

The article focuses on the analysis of world electric power production over the past decades, which is marked by the increase in the world total electricity production by more than 4 times in 1937-2019. The shares of electricity production from different sources are analyzed. Hydropower, which uses natural renewable resources and does not generate greenhouse gases and other combustion products, and also has great potential to meet the electricity needs of many countries is given a special position among the electricity generation processes. According to the analysis, hydropower accounts for around 16% of the world’s electricity production. Distribution of shares of hydroelectric power generation by the countries, including Russia, is illustrated. There has been defined a total gross hydro potential of the Russian Federation (about 2,800 billion kWh); Russia ranks second after China in supply of hydropower resources. There is considered a traditional approach for our country to produce electricity at thermal power plants. Decommissioning of hydroelectric power plants is supposed to take a large amount of state budget expenditures. The advantages of hydroelectric power plants and negative consequences of hydropower engineering are given. Distribution of the economic potential of the hydrogenation energy resources of the Russian rivers with the highest dynamics of hydropower development is illustrated, and its application is determined (the RF hydro potential is used rather poorly, its distribution across the country is uneven). The promising application of the hydro potential of the rivers in the North Caucasus has been proved, as well as of building the derivational hydroelectric power plants with artificial channel systems without flooding the territories and resettling the population. The directions of alternative hydropower engineering that use the mechanical energy of tides, currents, waves and thermal energy of the ocean have been considered.

МЕТОДИКА РАСЧЕТА СРЕДНЕСУТОЧНЫХ РАСХОДОВ ВОДЫ НА РЕКАХ РОССИИ С ИСПОЛЬЗОВАНИЕМ МОДЕЛИ ФОРМИРОВАНИЯ СТОКА HBV-96

A method for calculating the daily streamflow was developed. The methodology uses the HBV-96 conceptual hydrological model. An output adjustment method was applied to the model calculations, which made it possible to significantly improve overall accuracy. The software package was created to develop, implement, and verify the methodology. The technique was implemented for 590 river catchments located throughout Russia in various natural conditions. An archive of all necessary hydrometeorological data for the period from 2010 to 2019 was formed. The results of verification based on an independent sample indicated a fairly high accuracy of calculations for the vast majority of river catchments. The results provide a basis for the development of an automated system for generating and issuing short-term streamflow forecasts for Russian rivers based on the proposed methodology.

ВОЗМОЖНОСТИ ИСПОЛЬЗОВАНИЯ СИСТЕМЫ COSMO-RU ПРИ КРАТКОСРОЧНОМ ПРОГНОЗИРОВАНИИ СТОКА РЕК РОССИИ

An assessment of the possibilities of using the COSMO-Ru system for short-term forecasting of runoff of Russian rivers is carried out. An analysis of the forecast quality of the daily precipitation layer and average daily temperature of the surface air layer using this system is performed for 2081 weather stations. The quality characteristics of these forecasts are mapped. A forecast correction method was applied, which made it possible to increase the accuracy of forecasts on average by 20% for the precipitation layer and by 15% for air temperature. The quality of forecasting meteorological parameters averaged over the territory of 590 river basins turned out to be satisfactory for the precipitation layer and good for air temperature. The results give reason for a positive assessment of the possibilities of using the COSMO-Ru system for short-term forecasting of runoff of Russian rivers.

The Species Diversity Assessment of Azygia Looss, 1899 (Digenea: Azygiidae) from the Volga, Ob, and Artyomovka Rivers Basins (Russia), with Description of A. sibirica n. sp.

This study is devoted to the investigation of Azygia (Digenea: Azygiidae) species diversity using classical morphological, recent molecular tools (28S rRNA and cox1 mtDNA for genetic-based inference) and robust statistical techniques (Principal component analysis, PCA). The analysis revealed that the genus Azygia included four valid species: A. lucii, A. longa, A. hwangtsiyui, and A. sibirica n. sp. The distribution of the type species A. lucii was confirmed in the largest Russian rivers: the Volga and the Ob. The worms isolated from Perccottus glenii were determined as the Chinese species A. hwangtsiyui, according to the genetic data for the cox1 mtDNA gene, at 1.32–1.56%. The new species, Azygia sibirica n. sp, was described from Esox lucius in the Ob River and differentiated from the type species A. lucii by the smaller ovary, testes and prostatic sac, wider body, very narrow pharyngeal lumen and form of anterior margin of ovary. In addition, multivariate analysis and three methods for species delimitation (ABGD, GMYC, bPTP) showed the subdivision of A. lucii and A. sibirica n. sp. into two separate groups, one from the Volga River and another from the Ob River, respectively. To conclude, A. lucii infects Esox lucius in the western (European part of Russia, the Volga River basin), and northern (Western Siberia, the Ob River basin) parts of Russia; A. sibirica n. sp. has also been found to infect Esox lucius in the Ob River, while A. hwangtsiyui infects Perccottus glenii in the South of the Russian Far East (the Artymovka River basin).

ВЛИЯНИЕ ЭРОЗИОННО-РУСЛОВЫХ СИСТЕМ НА ИНФРАСТРУКТУРУ НАСЕЛЕННЫХ ПУНКТОВ ЕВРОПЕЙСКОЙ ЧАСТИ РОССИИ

The infrastructure of any settlement, whether it is a village or an urban agglomeration, ensures the functioning of the systems that serve the needs of the population. Regardless of the age of the settlement, its size and layout, the system of engineering communications depends on the features of the relief and erosion-channel processes in this area. To identify the impact of gully erosion and riverbed processes on the functioning of infrastructure, the southern megaslope of the Russian Plain was selected. There is a high degree of erosive dissection and activity of riverbed processes. Satellite images and cartographic material were used to assess the impact of erosion-channel processes. For the basins of the Volga, Oka, Don, and Dnieper rivers (within the territory of the Russian Federation), a map of the impact of erosion-channel processes on the infrastructure of settlements has been compiled. The basis for drawing up the map was a physical and geographical map of Russia on a scale of 1:8,000,000 and a map of the hazardousness of channel processes on the rivers of Russia. The resulting map shows 120 settlements: 84 – in the Volga River basin, 13 – in the Don River basin, and 24 – in the Dnieper River basin (within the Russian Federation). According to the developed methodology, each settlement was assigned a score of the impact of erosion and riverbed processes on the infrastructure. The most common are small values of such impact: 1 point – 45%, 2 points – 29.5%, 3 points – 23%, 4 points – 2.5% (only 3 settlements). The lowest (1–2 points) impact on the infrastructure corresponds to the territories within the lowlands and relicts of glacial relief. Settlements on the Central Russian and Volga Uplands are more dependent on gully erosion (3–5 points) and show a weak dependence on riverbed processes. The research results indicate an ambiguous impact of erosion and riverbed processes on the infrastructure of the settlements. Large and big cities are less dependent on erosion and riverbed processes, in contrast to small and medium-sized ones.