The article examines the collaboration between the Earth Science Museum and professors from the Faculty of Biology and the Faculty of Soil Science at Lomonosov Moscow State University (Faculty of Biology and Soil Science until 1973) from the museum’s founding to the present day. In the early 1950s, university professors collaborated with the museum staff to create biology-themed exhibits at the Museum. In particular, they helped preparing the exhibits on the 26th floor (Marine Hall) and the 25th floor (Natural Zonation). A brief overview of the current course offerings in biological disciplines at the Earth Science Museum is presented, including courses for students from the Faculty of Biology, the Faculty of Geology, and the Faculty of Philology at Moscow State University. The disciplines covered include “Ecology”, “Marine Communities and Ecosystems”, “Ecology with Fundamentals of Biogeography”, and “Modern Natural Sciences”. The museum’s exhibition serves as a unique educational environment for such classes, particularly when incorporating modern pedagogical approaches such as the flipped classroom model. The article presents the collaborative work of the Museum’s staff and students from the Faculty of Biology within the framework of the MSU’s Development Program “Development of the Foundations for the Establishing, Operating, and Advancing a Comprehensive University-based Scientific and Educational Youth Museum Using the Example of Lomonosov Moscow State University.” It also highlights the creation of a unique interdisciplinary open-air exhibition at the MSU Botanical Garden on Leninskie gory named “From the Arctic to Moscow: The Path of Glaciers”.

This study establishes the authorship of the geological term “eluvium” and traces its evolution in geological and soil sciences. It confirms the priority of H. Trautschold (1817–1902) as the original author of this term, supported by analysis of his works from the 1870s. The term was first introduced by him in 1872. The article demonstrates that the modern interpretation of the term “eluvium” shows a high degree of correlation with H. Trautschold’s classical definition. The development of the concept of eluvium and ideas about eluvial processes is traced through the works of prominent Russian soil scientists – N.M. Sibirtsev, V.V. Dokuchaev, V.I. Vernadsky, B.B. Polynov, V.R. Williams, and N.P. Remezov. V.V. Dokuchaev systematized the concept of eluvium into a coherent framework: definition of eluvium → eluvial processes → stages and phases of eluvial rock transformations. He emphasized that “although these products are sometimes altered beyond recognition of the parent rock which they originated from, a genetic connection between them always persists.” Particular significance lies in the incorporation of the biogeochemical aspect into the concept of eluvium through the works of N.P. Remezov, who established biological accumulation of elements exceeding their removal during eluvial processes. This allowed eluvium formation to be viewed not as a purely abiotic process but as a phenomenon involving living organisms. The article reveals the historical continuity of scientific ideas in the hypothesis of the origin of the Russian Plain: H. Trautschold → V.V. Dokuchaev → B.B. Polynov → V.A. Kovda. H. Trautschold was the first to propose that the Russian Plain formed from deposits lying on top, which were influenced for millennia by atmospheric precipitation, initiating the concept of eluvial origin of plains. This idea was later reflected in the works of V.V. Dokuchaev and B.B. Polynov, and subsequently in V.A. Kovda’s hypothesis regarding the fluvioglacial origin of the Russian Plain. Our analysis confirms that the term “eluvium” is a fundamental concept uniting geology, geomorphology, geochemistry, and soil science, and its evolution reflects the advancement of understanding regarding the genesis of surface deposits and soils.

This paper examines the hierarchical organization of principles in soil science, emphasizing their continuity with classical positions from various scientific fields and their role in integrating theory and practice. The study highlights differences in the genesis of principles, ranging from theoretical generalizations to experimentally validated propositions. Special attention is given to ideas of V.I. Vernadsky and V.V. Dokuchaev, who laid the foundations for the systemic and evolutionary-historical approaches to soil study. It is demonstrated that the scientific worldview serves as the pinnacle of this hierarchy, defining a system of generalizations, including the principles of systemicity, historicism, and the primacy of scientific approaches formulated by Academician G.V. Dobrovolsky. These principles ensure unity between theoretical and applied directions, rooted in the classical supra-conceptual ideas by V.V. Dokuchaev, whose works underpin the genetic approach to soil study. Within the hierarchy, following the scientific worldview come methodological principles neutral to specific disciplinary sections, followed by concepts, laws, and principles. For instance, N.M. Sibirtsev’s genetic principle, formulated in the 19th century, continues to define approaches to soil genesis. The paper underscores the importance of continuity, showing that Dokuchaev’s principles of systemicity and historicism remain fundamental for developing new scientific leads. The hierarchical organization of principles and their intra- and interdisciplinary continuity serve as key instruments for the progress in soil science, enabling integration of diverse knowledge into a unified scientific field. The necessity for further systematization of principles, particularly in biogeochemical cycles and interdisciplinary research, and terminology harmonization to strengthen the link between theory and practice is also emphasized.

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 fulfillment of the tasks set by the 1949-1965 State Plan for Nature Transformation became the work of the whole country. Its goal was the development of sustainable agriculture in the steppe and forest–steppe regions of the European part of the USSR. It is an example of a responsible state attitude to the use and preservation of our lands and soil fertility. The State Plan for nature transformation was bases on the integrated reclamation of agricultural landscapes using a scientific systematic approach to the objects of research and management. State authorities, Academy of Sciences of the USSR, scientists from dozens of universities and research institutes, ministries, 80 thousand collective farms, 2 thousand state farms, and 3 thousand machine tractor stations took an active part in the organization and large-scale implementation of protective afforestation and the development of a grass-field farming system. The plan provided for the creation of 8 large state forest strips with a total length of 5,320 km, located along floodplains and watersheds of the Volga, Dnieper, Don, Ural, Seversky Donets rivers etc.; protective forest plantations in the fields of collective farms and state farms; consolidation and afforestation of sands on an area of 322 thousand ha; the introduction and development of a system of field and fodder grass-field crop rotations; and the creation of over 44 thousand ponds and reservoirs. Over the 5 years of the plan's implementation, more than 2.3 million ha of forest plantations have been planted in the country; an ecological framework of agricultural landscapes has been created on agricultural lands; over 13 thousand ponds and reservoirs have been created. The prototype of the scientific basis of the State Plan for Nature Transformation was the works by V. V. Dokuchaev, V. R. Williams and V. I. Vernadsky on the conservation of land and soil fertility. The implementation of the plan stopped in 1953 and the development of virgin and fallow lands began. Currently, the state, scientists, society, regions and agricultural producers need combining their efforts in the rational usage of natural resources, the preservation of agricultural land and soil fertility for the present and future generations.

The article shows that each period of the evolutionary process of the biosphere formation on Earth corresponds to one form of soil formation, namely: underwater (“hydrozemic”), swampy (“atmozemic”), and terrestrial (“lithozemic”). The ancient swamp soil formation is considered, in addition to biomass deposition, to take part in the formation of the oxygen-containing composition of the planet’s gaseous envelope and the release of organisms from the aquatic environment to land. It has been determined that the process of paludification and swamp soils in the past and at present did and do perform the same biospheric functions and should include the entire genetic profile up to the basal rock in the concept of “peat soil”. On the example of the central part of Western Siberia, the process of paludification in the Holocene period is considered. This process is defined as a single, irreversible, progressive process of conjugated changes in their biotic and abiotic components. This ensures autonomy in the development and preservation of mires as a special type of the biogeocenotic cover of Earth. It is shown that the differences in the mire complexes of different botanico–geographical zones and subzones reveal the chronological boundaries of the transformation of swamp biogeocenoses of eutrophic types into mesotrophic and oligotrophic ones. It has been determined that the process of paludification in the taiga zone of the West Siberian Plain is of aggressive nature and the expected warming is a temporary warm period in the interval of cyclical climate.

The role of scientific mentorship is analyzed using the example of the relationship between outstanding Russian scientists N.V. Timofeyev-Ressovsky (1900–1981) and A.N. Tyuryukanov (1931–2001). The relationship between these remarkable individuals, though very different in origin, character, and habits, quickly evolved from teacher–student into genuine friendship and scientific collaboration. Two decades of fruitful interaction between them lent impetus to the development of new scientific fields, namely, radiation biogeocenology, biospheric studies (biospherology), and fundamental soil science. Their dedication to science and their attitude toward young people enabled future generations of scientists to grow and develop within the Russian school of natural science.

Of fundamental and priority applied importance are new scientific and practical results obtained at the V.R. Williams Federal Research Center of Forage Production & Agroecology for the study of natural food resources in Russia, based on modern knowledge, materials and technologies. For all 11 natural and economic regions of Russia (Northern, Northwestern, Volga-Vyatka, Central, Central Chernozem, Volga, North Caucasian, Ural, West Siberian, East Siberian, and Far Eastern), agro-landscape and ecological zoning of land and forage ecosystems has been developed. The following materials were obtained for each area: a map M 1:2,500,000, a legend, a database on land, a database on forage lands, a database on negative processes, a classification of forage lands, a classification of deer pastures (where available), recommendations for forage production and environmental management in agriculture. The research used the Map of the Soil and Ecological Zoning of Russia from the Faculty of Soil Science of Lomonosov Moscow State University, as well as other numerous sources. When creating and developing new highly productive and resistant plant varieties and nature-like technologies based on zoning, science and industry will be able to use local natural and climatic resources with the greatest efficiency and minimize the development of negative processes.

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.