The paper is devoted to the outstanding Russian scientist Vladimir I. Vernadsky, who is one of the founders of ecology. As a student of V.V. Dokuchaev, he developed his teacher’s ideas of a systematic dynamic approach to the study of nature and introduced a deep scientific ecological content into the concepts of the biosphere and the noösphere. V.I. Vernadsky is the founder of a complex of modern Earth sciences (geochemistry, biogeochemistry, radiology, and hydrogeology) and the creator of many scientific schools. In his scientific work, he covered many research areas, from geology to the study of the role of living matter in geochemical cycles, from soil science to the biosphere, the increasing influence of scientific thought, human activity in the biosphere and its transformation into the noösphere. The importance of agriculture in the biosphere and the noösphere is considered. The biosphere is an area of active life on Earth (troposphere, hydrosphere and part of the lithosphere), the composition, structure and energy of which are mainly due to the activity of living organisms. The noösphere is its thinking shell. Agriculture, whose most important part are grassland ecosystems, is an important component of the biosphere, being a reproducible, autotrophic sustainable resource (energetical, environmental, food and feed). In light of the pressing environmental problems facing the world, environmental education and environmental thinking are a priority for the development of the biosphere, the noösphere and agriculture.

The paper provides a brief analysis of the process of continuous self-organization (evolution) of living matter in the flow of Primary energy. Particular attention is paid to humans (Homo sapiens), who have taken possession of special methods of energy generation, not characteristic of any other species, namely, the transformation of the continuous flow of Primary energy. Energy generation and “scientific thought” have allowed humanity to become, according to V.I. Vernadsky, a “geological force”, to involve significant resources of the planet in the process of its own continuous self-organization and socialization of individuals. The scientific formalization of the processes used to generate energy significantly has accelerated the development of society and has actually become a prerequisite for the scientific and technological revolution. It is shown that they were Russian and, to a greater extent, Soviet scientists who have made a decisive contribution to the fundamental scientific foundations of energy generation, which determines the modern process of self-organization of mankind and people socialization. Reducing the overall efficiency of energy resources below a certain threshold is a dangerous and intractable challenge for the industrial world economies and civilization as a whole, causing conflict situations. An alternative to the apocalyptic scenario of human development, the concept of distributed energy generation based on self-regulation of energy consumption by a single individual is considered. Distributed energy generation, according to the authors, could determine novel socialization phenomena and initiate, according to V.I. Vernadsky’s teaching, the transition of the biosphere into the noösphere.

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 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.

The astronomical theory of climate changes (oscillations), created more than 100 years ago by the Serbian mathematician Milutin Milanković, in its current form does not explain global fluctuations of the natural environment in the Late Pleistocene, and therefore requires further refinement and development. And this theory has been modernized. Our revision is based on the results of calculations of the Earth’s insolation, performed with a high spatiotemporal resolution. The irradiation of the entire Northern Hemisphere was taken as the basis for determining the causes of the glaciations in Late Pleistocene. Variations in incoming solar radiation, calculated within the astronomical theory of climate, were supplemented by calculations of variations in the characteristics of radiative heat transfer. Based on the improved astronomical theory, the causes of global climate changes in the Late Pleistocene were found. The effect of dividing seasonal irradiation by phases of annual irradiation of the hemispheres was determined, and on this basis 7 warm and 9 cold solar epochs are distinguished in the solar climate of the Late Pleistocene. It has been determined that the glacial epochs in the Late Pleistocene of Northern Eurasia are associated with periods of positive average anomaly of winter meridional heat and moisture transfer and negative average anomaly of summer irradiation intensity in the Northern Hemisphere. Also, positive average anomalies of radiative heat transfer from the summer Southern Hemisphere to the winter Northern Hemisphere, as well as negative average anomalies of insolation seasonality in the Northern Hemisphere, correspond to glacial periods in the Late Pleistocene.

Interglacial epochs are associated with periods of positive average anomalies of summer radiation intensity and negative average anomalies of winter meridional transfer, and interhemispheric transfer of heat and moisture from the summer Southern Hemisphere to the winter Northern Hemisphere. Also, interglacial periods in the Late Pleistocene correspond to negative average anomalies of radiative heat transfer from the summer Southern Hemisphere to the winter Northern Hemisphere, as well as positive average anomalies of insolation seasonality in the Northern Hemisphere. The difference in the intensity of summer irradiation of warm and cold climate epochs in 100-thousand-year cycles averages 4.91 W/m2 (or 1.151% of the average Late Pleistocene value of summer irradiation intensity for the Northern Hemisphere). Therefore, the change of paleoclimatic epochs is associated mainly with the dynamics of the characteristics of summer radiation, and with the winter transfer of radiative heat and moisture determined by astronomical factors.

Statistical characteristics of changes in the intensity of annual and seasonal irradiation at the upper boundary of the atmosphere of 5-degree latitude zones of the Arctic region in the Late Pleistocene were obtained. No relationship was found between the intensity of annual and seasonal irradiation of 5-degree latitude zones and the eccentricity of the Earth's orbit, but a positive noticeable relationship was found between the intensity of summer irradiation and a negative relationship between the intensity of winter irradiation and a change in the tilt of the axis and the longitude of the perihelion. The maximum range of variations in winter irradiation intensity in the Arctic with geographic latitude in the Late Pleistocene noticeably (by 10,211 W/ m2) decreases, while the maximum range of variations in summer irradiation intensity with geographic latitude slightly (by 4.3 W/m2) increases. The correlation coefficient of summer irradiation intensity and perihelion longitude in the Late Pleistocene decreases with geographic latitude, and increases with the tilt of the rotation axis. The modulus of the correlation coefficient of winter irradiation intensity with perihelion longitude decreases, and increases with the tilt of the rotation axis. The maximum range of changes in the intensity of annual and seasonal irradiation of 5-degree latitudinal zones by 1–2 orders of magnitude in the Late Pleistocene exceeds the maximum variations in the δ18 O isotope-oxygen analysis of benthic foraminifera, which shows the groundlessness of using its values to solve problems of Late Pleistocene geochronology and climatostratigraphy.

The old hypothesis by Academician V.I. Vernadsky of the biosphere being a geological force to build the surface and immediate interior of our planet is indirectly supported based on statistical data. According to occurrence data on findings of all known animal specimens and according to some characteristics of the tectonic activity of the Earth, the presence of several previously unknown cycles shortening from cycle to cycle (approx. By a factor of 1.51) over about a billion years, is substantiated. This leads to an idea of a cause-and-effect relationship between these two different categories of cycles. The influence of tectonics on biota, to one degree or another, has long been known. However, due to the mentioned cycles being rather accelerated, it is difficult to imagine that such strong acceleration in the tectonic cycles could arise due to some intra-tectonic causes, whereas the accelerated nature of biotic evolution due to some intrabiotic causes is quite possible. So, a conclusion arises of the mentioned contracting tectonic cycles being modulated by biota. Possible mechanisms of such influence are hypothesized, their clarification requiring additional research. This conclusion is revolutionary for geology and reveals biotic evolution’s previously unknown role as an active creator of global tectonic (cyclic) processes at a new, quantitative level, which is also revolutionary for evolutionary biology. But, regardless of these conclusions, the mentioned decreasing cyclicity is of interest itself, for the first time (statistically) speaking about the accelerated nature of evolution over such vast time periods.

The problem of global climate warming and attempts to solve it, including using low-carbon power engineering, are analyzed. The success of solving this problem depends on the degree of understanding of the processes which cause it. As more and more data speak about natural causes of climate fluctuations, and of anthropogenic factors the greatest contribution to the warming is made by thermal pollution rather than the anthropogenic growth of carbon dioxide in the atmosphere, low-carbon power, with all its positive qualities, is unable to solve the problem of climate warming.

The article presents some prerequisites for the formation of a new theory of relations between species groups of mammals, including humans. Key elements of the theory are considered, including the connection between quantum decoherence in complex organic molecules and Jung’s postulates of the collective unconscious, with the extension of the latter to the possibility of explaining the paradox of instincts in higher animals. Data on experimental confirmation of the mechanism of wave function collapse in relation to living organisms are presented.

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.