Peculiarities of the formation of marginal plateaus in the early period of the opening of the North Atlantic Ocean are considered. The oceanic opening between Greenland and Europe (formation of the North Atlantic Ocean) began approx. 50–55 Mya after a long period of rifting, followed by the formation of the Aegir spreading ridge and the formation of the basin of the Norwegian Deep. Since that moment, the formation of a series of specific structures (marginal plateaus) began. The article considers conditions for their formation, using the physical modeling method. Three groups of structures were distinguished and typified according to the formation mechanism. A series of experiments was performed to each type of structures. Experimental results are compared with our proposed model for the formation and evolution of marginal plateaux.

Professor N.E. Zhukovsky placed strong emphasis on visual clarity in writing and explaining his scientific works, repeatedly addressing the importance of geometric representation in theoretical mechanics. Drawing on archival materials from the Museum of Bauman Moscow State Technical University, the authors demonstrate that the “Russian Method of Craft Training” was built on the accumulated theoretical scientific foundation of the mid 19th century, gradually enriched by systematic collections of tools and teaching aids for each subject, and further developed through the practical work of students and their teachers. Examples of mechanisms created by Professor N.E. Zhukovsky can be found in the writings of his students and followers, in the works of Soviet scientists, and in museums of foreign universities–all of which hold high cultural value as part of our society’s scientific and pedagogical heritage. Through the case study of creating the museum replica “Hess’ Loxodromic Pendulum” based on Zhukovsky’s calculations, the article illustrates the substantial cultural potential embedded in the papers and designs of the Russian scholar. It shows how much inspiration and new scientific ideas contemporary educators and students can still draw from the now classic works of Professor Zhukovsky and his disciples. The reader will become acquainted with the principles of this scholar’s scientific and pedagogical activity—vivid examples of genuine scientific dedication by a scholar and patriot of our country.

The article examines the applicability and functioning of artificial soils, whose creation is based both on research into modeling moisture and salt transfer in soils and on the development of nature-like biogeochemical technologies for recreating natural biogeochemical cyclicity. Two main technological approaches for constructing artificial soils are demonstrated, namely: modeling soil processes and applying the modeling results to technologies for creating functional horizons of artificial soils. It is noted that artificial soils are essentially biophysical models, our consideration of which allows for the design of such soils for a wide variety of functional uses.

A comprehensive study of the territory using a number of methods has allowed us to build a geodynamic and geokinematic models of the northwestern part of the East European Platform. Their interpretation allows us to assess the geodynamic environment of the Kalinin Nuclear Power Plant, as well as the overall geokinematic environment of the studied territory.

At present, it is possible to identify a number of new directions for the development of biogeochemical research, at the junction of fundamental and applied studies. A novel field of research is being formed, namely, engineering biogeochemistry, within the framework of which innovative biogeochemical technologies and technological processes based on modeling and management of ecosystematic biogeochemical cycles are being developed. The application of these innovative technologies for the restoration of disturbed and polluted impact ecosystems, in particular, polar ecosystems in the zones of operation of gas-producing enterprises, is considered. Technological examples of calculations of geoecological risks, as well as microbial contamination risks are given. A pool of the developed biogeochemical technologies and their connection with other innovative technologies within the framework of gas-producing companies is shown.

The open-air exhibition “Glaciers from the Arctic to Moscow” aims to present the interdisciplinary issues of complex cosmoglobal aspects and mechanisms of interaction between the geospheres, which are the product of climate change spanning the entire history of the planet and continuously affecting ecosystems. The exhibition is organized at the Botanical Garden of Moscow State University in collaboration with the Earth Science Museum of Moscow State University as a cluster of the Youth Museum. A synthetic version of the distribution of glacial covers in the territory of the East European Plain and a version of the most commonly accepted scale of glaciations and interglaciations of the Quaternary period with the main astrochronological reference points have been specially developed and designed to be easily understood by a wide range of visitors to the exhibition. Special attention is paid to Milanković’s cycles, and original information stands have been created to reflect their work. The natural basis of the exhibition is formed by a group of different-sized erratic boulders, arranged according to the reconstructed location of the rocks that form them in their parent locations, modeling the “glacier route” on the East European Plain. By analyzing the “travel notes” in the form of systems of characteristic grooves and “tan crusts,” as well as the composition of the rocks, together with each visitor, it is possible to reconstruct the path of a particular boulder, and, with the help of information boards, to try to understand the scenario of the glacier’s development, the history of the region, and the planet as a whole. The created exhibition can be positioned as a universal conceptual and design solution for the space of a university science museum.

Wastewater treatment plants (WWTPs) serve as hubs for the redistribution of biogenic element flows, since they generate three output streams (liquid, solid and gaseous), where the proportional content of biogenic elements depends on the wastewater treatment technology. The circular economy principles require accounting for these flows to develop a strategy for utilizing biogenic elements to meet the needs of the growing urban population. Identifying sewerage basins within a river basin serves as a tool for calculating these flows. The maximum possible amount of biogenic elements (carbon, nitrogen, phosphorus) redirected by treatment plants to local water bodies, to the atmosphere, and to sewage sludge is estimated for each sewerage basin. Such calculations enable an assessment of the maximum biogenic load downstream of the treatment plant discharge point (in the event of a plant shutdown) and the design of potential technological chains for utilizing sewage sludge. The author proposes to use a GIS-based method to identify sewerage basins within a river basin. This approach allows for the calculation of maximum biogenic element flows based on the population within each sewerage basin, providing insights into the environmental load on each individual basin and the entire river basin as a whole. Additionally, this method identifies zones with the highest load on watercourses within the river basin and assesses the risks of watercourse pollution due to urban development and the emergence of new residential areas. The article presents a methodology for identifying sewerage basins within the Moscow River basin, calculating the population within their boundaries, and estimating the daily load of two indicators, namely: total nitrogen and phosphate phosphorus. Using geoinformation tools, a map of sewerage basins was plotted, identifying areas within the Moscow River basin with the highest and lowest coverage of wastewater treatment plants.

In this paper, we discuss questions of the common origin of the disciplines of soil science and landscape geochemistry. Their closeness lies in their common objects of study — soils and landscapes — and a common methodological approach based on systemic analysis, the evolutionary-historical principle, and the priority of the scientific approach in solving practical problems, as laid down by V.V. Dokuchaev. The prominent naturalists A.E. Fersman and V.I. Vernadsky emphasized the genetic connection and mutual enrichment of these sciences through theoretical concepts and experimental data. When considering common problems of these two disciplines, particular importance is given to the biological cycle as a fundamental law governing the functioning of ecosystems. In the classification of soils and soil-geochemical catenae, their position within the system of geographic landscapes is especially significant. Currently, priority issues include anthropogenic impacts and environmental monitoring, which involve studies of element migration over the biosphere, as well as efforts towards mathematical modeling.

The considered part of the Mid-Atlantic Ridge extends from the Agulhas-Falkland fracture zone to the Bouvet triple junction. This segment has a contrasting topography. In its southern part, it has the morphology of an axial rise, while in its middle part it has the morphology typical for a slow-spreading rift valley. In the northern part, an area with transitional morphology can be distinguished. Three morphostructural complexes of transverse faults are distinguished, approximately corresponding to areas with various morphology. Such a different structure and segmentation of the spreading ridge became possible owing to the thermal influence of the Shona and Bouvet mantle plumes in the southern part of the considered segment and the Discovery mantle plume in its northern part. To reconstruct the morphostructure formation conditions in the ridge axial zone, physical modeling was implemented. In our experiments, we obtained various relief types and transverse discontinuities complexes depending on the distance from the thermal anomaly. They match the natural morphostructures. The modeling results suppose that the main formation conditions of the contemporary Mid-Atlantic Ridge terrain are spreading obliquity, thermal anomaly intensity, and the plume center position relatively to the spreading axis.

Nuclear power plants are sources of a large amount of electrical energy. Therefore, ensuring their safety is a priority for the successful development of nuclear energy engineering. When studying the relief using structural and geomorphological analysis, alignment surfaces and weak zones were revealed, some of which have been transferred to the rank of low-amplitude faults. These faults and the surfaces of the foundation and relief make the framework of a 3D model created using the Roxar RMS 2013 software. The model is given a certain geodynamic setting. As a result, parameters were obtained to make it possible to determine that the Novovoronezh nuclear power plant is located in an unsafe area from the viewpoint of neogeodynamics, unlike the Kursk and Smolensk ones. The geodynamic conditions within a radius of 150 km around the plants are also interpreted using modeling, and the kinematics of faults are described.

Brief information about the author’s course dedicated to crystal growth is provided. The education program gives general information of the mechanisms of crystal growth, the main growing methods, crystal formation in nature and under home conditions. Issues of the origin of the first group gemstones, the specifics of their formation in the laboratory, methods of treatment and application are considered. A large amount of information is given, that’s why the course is divided into four sections and clearly structured within each of them. This helps to make it easier to perceive. Online course design allows the lecturer to effectively interact with the audience.

New data on potential fields are presented, compared with previous ideas about the regional structure and rift genesis of the Yenisei-Khatanga regional depression basement. Our 2D modeling based on geophysical data confirms the results of previous works regarding the identification of two types of the basement, and is consistent with the gravity-geodynamic concept of the formation of the Yenisei-Khatanga regional trough and the tectonic structures that complicate it, such as the Rassokhinsky and Balakhna megaridges. Also, as a result of our study of potential fields, the presence of a large volume of magmatic masses of ultrabasic and basic composition in the axial part of the Yenisei-Khatanga regional trough, Permian-Triassic age, was established, which confirms the rift mode of the region's development.

Relief is one of the sources of information about neotectonic activity. Using structural-geomorphological analysis, it is possible to identify weak zones, which often reflect hidden low-amplitude faults and fracture zones under the surface of Quaternary deposits. Using structural-geomorphological analysis, planation surfaces were identified, displacement amplitudes along faults and the magnitude of neotectonic movements were determined for certain periods of time. The results obtained were compared with seismicity and the degree of inheritance was revealed. 3D computer geological modeling of the stress state also helps in identifying zones of increased neotectonic activity, as the most dangerous zones in terms of seismicity. The stress state and directions of the compression axes in the horizontal plane were calculated using the RMS Roxar software. Also, for a more detailed study of the latest geodynamics of the Abinsk segment, the frequencies of earthquakes and the amount of seismic energy released were analyzed, and frequency graphs were plotted. When comparing the growth deformations of neotectonic uplift structures and the values of the latest stress state with seismicity, their significant correlation was revealed.

The thermal evolution of the permafrost in the sedimentary section of the Tyumen superdeep SG-6 well has been numerically reconstructed using the ICE2020 software package, which is part of the GALO flat basin modeling system. The thermal evolution of the sedimentary strata in the last 3.5 My is considered as the final stage of the basin modeling, whose formation began with continental rifting in the Late Permian. Abrupt climate changes in the late Pliocene–Holocene led to a decrease in the rock temperature by 15–20°C in the upper 1–1.5 km of the SG-6 sedimentary section. The maximum thickness of the permafrost in the study area was about 711 m, reached 2.6 Mya. The maximum thickness of the permafrost for the last ice age (23–18 thous and years ago) was 412 m, reached about 14.5 thousand years ago. According to our modeling, the modern base of the permafrost is at the depth of 311 m and is degrading with the rate about 13 m/1000 y. The results of our calculations with a database of climatic data limited to the last 50 and 100 thousand years differ markedly from the modeling results with the complete database for the last 3.5 My.

A new three-stage method for assessing the CO₂ balance in plant communities was formulated. The methodology includes not only taking into account the absorption of C-CO₂ during plantation vegetation, but also the processes occuring when using wood. In managed forests, when calculating the carbon balance, it is necessary to take into account the release of CO₂ not only at direct, but also at indirect consumption of technical energy for laying plantations, caring for them, and felling for final use. As a model, the consumption of technical energy in cultivating natural and genetically modified forms of aspen Populus tremula L. was calculated. The large role of indirect expenditure of technical energy in the C-CO₂ balance in forest plantations is shown. The use of a genetically modified clone of aspen significantly increases the productivity of plantations and CO₂ absorption from the atmosphere compared to its natural form. On a long time scale the final amount of CO₂ runoff from the atmosphere depends not only on the area of forests and their productivity, but also on the way of using wood. There is a highly effective way of using forest plantations to regulate the carbon dioxide content in the atmosphere, which is currently little paid attention, namely, the so-called substitution effect. Replacing energy-intensive materials (reinforced concrete, plastic, metal, and brick) with wood may be one of the main ways for the positive impact of forests on the CO₂ content in the atmosphere. The use of wood biomass from thinning, wood processing wastes, short-rotation forests for heat and power generation is a great reserve for replacing fossil hydrocarbons. The forest area needs to be expanded to increase wood production to replace energy-intensive building materials and generate biofuels.

A scheme of formation of the sedimentary blanket of the South Kara basin is considered, which can further be used for numerical reconstruction of its thermal history. The scheme is based on our analysis of the literature information on the structure and geological history of the Barents-Kara region. This information included an interpreted seismic profile crossing the studied area, drilling data from four wells located along the profile (the University, Rusanov, Leningrad and Kharasavey ones), measurements of the heat flow and deep temperatures in the basin. The proposed scheme considers the formation of the basin as a series of sedimentation stages with various combinations of clay shales, siltstones and sandstones and sedimentation in the Cretaceous and Paleogene with their subsequent erosion in the Miocene. The erosion amplitude is estimated by the observed change in the porosity of sedimentary rocks with depth. The initial heat flow in such a model should correspond to the flow of modern axial zones of continental rifting or be lower for the areas remote from the corresponding segments of the Late Permian-Early Triassic continental rifting system.