Our previous publication in “Life on the Earth” [7] was concerned with neuroactive substances in the capacity of new-generation pollutants exemplified by neurotransmitters such as acetylcholine and biogenic amines. At low concentrations, these substances exert a growth-promoting effect on microalgae. The present work deals with the mode of action of extremely low concentrations (“trace amounts”) of neurotransmitters that comprises their antioxidant effects and the influence on the dynamics and rhythms of microalgal cultures’ development, i.e. on the succession of their age-related stages. Such neurotransmitters that can enter natural ecosystems with the wastewater of food, drug, and cosmetic industry, can be grouped into (1) substances that increase the unsaturated fatty acid (UFA) content in microalgal membranes, elevate the photosynthetic pigment concentration in the cells, and prolong the “youth” of microalgal cultures; and (2) substances that decrease the UFA content, reduce the photosynthetic pigment concentration, and, accordingly, accelerate the “aging” of microalgal cultures.

The key principle of the Arctic development should be nature-saving nature management. The agro-landscape-ecological zoning of the Far North fodder ecosystems developed at the V.R. Williams Federal Research Centre for Forage Production and Agroecology is aimed at this very goal. About 90 % of Murmansk District is occupied by reindeer pastures, in some places disturbed as a result of their irrational use by reindeer herders, mining, construction, and transport; the ecological state of the territory is tense. In Yamal District, reindeer pastures occupy 65 % of the area; the ecological state of the ecosystems is tense or even critical in some places. The area of lichen tundras has decreased by 3,5–4 times, total fodder reserves in lichen-moss tundras, in those areas where they are still preserved, have decreased by 3–10 times. The total reserves of green grass fodder and shrubs has decreased by 1.5–2 and 2–8 times, respectively. Desertification of highlands (bare sands occupied about 6 %) and waterlogging of lowland areas is going on. Technogenic impact on tundra ecosystems disturbs soil and vegetation cover, hydrological regime. Waterlogging of lowlands due to thermoerosion is starting. It is necessary to find compromises between economy, ecology, social and national interests.

The article presents the results of studies of a number of sections of Lower Cretaceous (Aptian) deposits in the Saratov Right Bank region (settlements Krasnyi Oktyabr’, Doktorovka, Kurdyum and Shirokoe), confined to the Yelshano-Kurdyum uplift. Oryctocenosis combines autochthonous (ichnofossils), subautochthonous (bivalves and gastropods) and allochthonous (ammonites, wood fragments) elements. Sedimentological and mineralogical indicators (ripple marks, desiccation cracks, wedge-shaped structures, cross-bedding, glauconite, and calcite veinlets), as well as fossil remains and features of their taphonomy, allow us to diagnose the coastal ecosystem of the epicontinental sea basin. In the ecosystem format, we see a variety of physico-geographical situations: areas of the bottom which are periodically actively bioturbated and hydrodynamically transformed into mature hardground; zones of active hydrodynamics with the formation of cross-bedding; and zones of subaerial surfaces with the possible development of stick soils. Reconstruction of the paleoecosystem is complicated by the presence of a number of natural facts that have not been unambiguously interpreted, images of which are given in the article. The studied sections are of interest from the standpoint of geoheritage. Selected natural facts are actively involved in the development of a number of geoscientific university museums.

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”.

Vinogradsky’s columns are known as a model of a microbial community for experiments in laboratory conditions. The article proposes a system of integrated use of Vinogradsky’s columns in the space of the Earth Science Museum as: a) a visual dynamic “living exhibit”, b) an interactive platform of the Youth Museum, and a mobile cluster for exhibitions and the Science Festival, c) a natural educational and methodological tool, and d) a laboratory naturalistic experimental setup. Making a series of Vinogradsky’s columns from different locations of the initial pedo-soil matrix of various compositions allows for a successful combination of scientific, experimental, educational, and demonstration-interactive tasks in the space of a natural science university museum. In the Earth Science Museum at Moscow State University (Hall 21 – East European Plain), a series of Vinogradsky’s columns has been developed, based initially on the materials of bottom sediments samples of pond reservoirs, selected by a team of novice nature explorers (students of Moscow State University and schoolchildren) as part of the project “Youth Museum” of Moscow State University. Two-year monitoring has allowed to obtain new data on the development of microbial communities and to arrange an original cluster in the hall and to present a series of columns at the All-Russian Science Festival.

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.

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.

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.

The constantly extending list of humankind-produced environmentally toxic compounds currently includes pharmacological preparations. Among them, of potential relevance are neurotransmitters including such biogenic amines as norepinephrine, dopamine, serotonin, and histamine, as well as acetylcholine. These neurotransmitters were tested in the present work using such model organisms as the green microalgae Chlorella vulgaris Beijer, Scenedesmus quadricauda (Turp.) Breb. К-1149, and Haematococcus lacustris (= pluvialis) strains IPPAS H-239 and BM-1, as well as the cyanobacterium Limnospira platensis IPPAS B-256. It was established that all tested neurotransmitters significantly stimulate the growth of the cultures of microalgae at sufficiently low (micromolar) concentrations. In light of the results of this work, uncontrollable microalgal growth seems to be possible under the influence of trace amounts of neurotransmitters in natural and artificial water bodies, which might cause their eutrophication. All tested substances influenced the photosynthetic pigment content at micromolar (or submicromolar) concentrations, acetylcholine being a quasi-universal promoter of their biosynthesis that presumably stimulates the photosynthetic activity of the microalgae. The effects of the other tested substances varied depending on the microalgal species involved but predominantly resulted in promoting photosynthetic pigment biosynthesis. A biotechnological project aimed at stimulating the microalgal biomass yield by supplementing microalgal cultures with neurotransmitters seems to hold promise for producing drugs, food additives, or biofuel.

A new multi-level model for calculating the carbon footprint of agroecosystem products is proposed. The concept of “final carbon footprint” is introduced, which includes both direct CO₂ emissions from the operation of tractors, combines, oxidation of soil humus, CO₂-eq. during the transformation of nitrogen fertilizers in the soil, and indirect CO₂ emissions – carbon dioxide release into the atmosphere during the production of tractors, combines, tillage equipment, mineral fertilizers etc.
Based on the results of field experiments on gray forest soils in the Southern Moscow region, it is shown that when applying average doses of mineral fertilizers to field crops, the indirect CO₂ emissions are comparable to the CO₂ input from organic fuel oxidation when machinery is operating in the field. At higher doses of fertilizers, the indirect emissions are significantly greater than the CO₂ emissions from machinery operation. In order of increasing CO₂ emissions per 1 ha of sowing, crops on gray forest soils are arranged as follows: corn for silage > barley > winter wheat > clover.
Clover is a carbon-negative crop (−1.7 t/ha CO₂), i.e., CO₂ sequestration in the soil exceeds all CO₂ emissions from hay crop production. The final carbon footprint for grain crops, calculated using the standard method, was as follows: for winter wheat (with a fertilizer dose of N40P40K40) – 116 kg CO₂ per 1 centner of grain, for barley (with a dose of N60P40K40) – 104 kg CO₂ per 1 centner of grain. The final carbon footprint, taking into account the aftereffects of predecessors, was: for winter wheat (predecessor: two-year clover) – 48 kg CO₂ per 1 centner of grain; for barley (predecessor: silage corn) – 113 kg CO₂ per 1 centner of grain.

Distribution features of cadmium, lead, partly Ag, Bi, In, Hg and Tl in suspended solids are considered. Studies were made on the Oka River in the area of the Prioksko-Terrasny Natural Biosphere Reserve on a river section remote from the zone of formation of the technogenic scattering stream, in the period 1983–2018. To assess the general trend of changes in the concentration of the elements over the period of the experiment, it was proposed to consider the results on their prevalence in the composition of suspended matter obtained in the intermediate hydrological phase of the river between the spring flood and the summer midden. This is the main feature and essence of our proposed approach in order to eliminate the influence of significant seasonal changes in the macro- and micro-component composition of suspensions. It is shown that the 35-year time interval can be divided into two periods, namely: the first one is characterized by a decrease in the concentration of heavy metals (Cd, Pb), while the second one is characterized by the absence of any trend, relatively weak fluctuations in values. The direction of changes in the concentration of elements in the first period correlates with the literature data on the dynamics of a decrease in the intake of anthropogenic wastewater into surface waters in recent decades and with the results of our assessment of the decrease in river water pollution upstream from the experimental area.

This article examines the anthropogenic contribution to the planet’s climate system due to thermal pollution. Despite the quantitative predominance of solar and geothermal energy in the Earth’s heat balance, anthropogenic heat impacts the planet’s most sensitive shell – the biosphere. Thermal pollution in various countries has been assessed based on specific (per unit area) energy consumption, as all energy consumed by humanity is ultimately converted into heat and released into the biosphere. Specific carbon dioxide emissions also serve as an indirect indicator (marker) of thermal pollution, as fossil fuels remain the primary energy source. Calculated correlation coefficients between thermal pollution indicators (specific energy consumption and CO2 emissions) and climate warming in various regions have revealed a low positive correlation between these indicators (0.17–0.13, respectively), which indicates thermal pollution’s contribution to global warming to be still insignificant. Thus, the current contribution of anthropogenic heat to the climate system is primarily regional, which is undoubtedly important to consider in environmental policy to prevent the negative impact of this factor on the functioning of natural ecosystems. This is especially important in the context of global warming, primarily caused by natural factors.

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.

During ten field seasons, in the format of the scientific and educational expedition “Flotilla of Floating Universities”, whose concept is based on the synthesis of science and art, many researches and educational, volunteer and publishing projects and events have been implemented in the Volga region, the Caspian region, the Don region and the Urals. The research areas of the tenth field season in 2024 (Samara–Saratov Volga region) focused on: a) stratigraphic and astrochronological analysis of sections of Upper Cretaceous and Paleogene sediments, b) studying the role of living matter in the evolution of geoecosystems with special attention to biosimilar bodies (paleosoils, hardgrounds), c) analyzing the distribution of cosmic matter in natural environments in the zone of the “Saratov meteor shower” in 1918, and d) the history of the Great academic expeditions in the 18th century (the Volga routes of I.I. Lepekhin, P.S. Pallas, and I.P. Falk). The key scientific and educational projects were a field meeting of the RAS Commission for the Study of the Heritage of Outstanding Scientists (V.I. Vernadsky section) and a field session of the Moscow Society of Naturalists (MOIP) on the Volsk–Saratov section of the expedition’s main route.

Due to the large volume of coal mining in the Russian Federation and other countries, there is a serious issue of the formation of waste heaps from coal dumps, which pose a significant threat to the environment of adjacent territories. One of such areas is the Donetsk coal basin, whose area is more than 60 thousand km2. Phytoreclamation is the most common and cost-effective method recommended for the restoration of degraded coal dump soil, which reduces the removal of toxic substances with dust emissions and water runoff. However, plant growth on these soils is hindered by their phytotoxicity and unfavorable physical and physicochemical properties. The aim of this research was to develop a biogeochemical technology for the reclamation of coal dumps in Donbas based on phytoreclamation with various additives. Our experiments involved soil samples taken from the upper layer of the Ayutinskaya mine waste heap in the Donetsk coal basin, as well as zonal ordinary chernozem samples. The experiments were conducted in microfield conditions in bottomless vessels with an area of 0.1 m2 dug into the ground. The additives used were wood biochar and other sorbents, including mineral (diatomite and vermiculite) and organic (acidic and neutralized peat) ones, as well as ordinary chernozem and quarry sand – clean and with biohumus additives. The soil was seeded with a drought-resistant lawn mixture. All additives had a positive effect on the growth of green mass of drought-resistant lawn, measured during 3 cuttings ib the vegetation season of 2024. However, the best results were obtained with the addition of neutralized peat and chernozem at doses of 25 %, as well as quarry sand at doses of 25 and 50 % with the addition of biohumus; at the same time, the additional addition of 5 % biochar to all these samples gave no desired result.

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 article presents a retrospective analysis of the development of educational and enlightenment activities in the Earth Science Museum of Moscow State University named after Lomonosov from the moment of its foundation to the present. The following trends are highlighted: expansion of the forms and methods of museum pedagogy over time, introduction of interactive methods in the practice of the educational and enlightenment activities, work with various age visitor groups (from younger pupils and students to adults), as well as the use of digital methods in the educational process.

In development of fundamental ideas of the MSU professors V.I. Vernadsky, V.A. Kov­da and M.A. Glazovskaya in the field of the biosphere and its biogeochemical organization, the use of biogeochemical standards for parameterization of the technogenic impact on various ecosystems is proposed. To assess these standards quantitatively, the application of the critical loads methodology is shown. Algorithms to calculate the values of critical loads are proposed, in particular, for acid-forming and eutrophicating sulfur and nitrogen compounds emitted during the operation of various industries, including the oil and gas one. Using the example of the impact zone of the Central Asia–Center main gas pipeline planned for reconstruction, the maps of critical loads are presented and an assessment of the environmental risk in the coastal zone of the Caspian Sea is given.

Features of the prevalence of Cd and Pb dissolved forms in the water of sections of the Oka river and other rivers of the Russian Plain are considered. The influence of anthropogenic wastewater (industrial, municipal and agricultural) containing heavy metals is clearly manifested only in certain sections of the rivers of central Russia (Oka River, Volga River, and Moscow River) against the background of natural landscape and geochemical processes. An attempt is made to develop approaches to assessing the degree of anthropogenic influence on the water composition of various river sections, including those remote from pollution zones. An ecological and geochemical lead–cadmium indicator is proposed, which makes it possible to assess the anthropogenic impact and divide river sections into 3 categories (strong, medium and weak pollution, respectively). The river sections with low anthropogenic pollution have high values of this indicator corresponding to waters with the background (or close to background) concentration. A decrease in the indicator values means an increase in the role of anthropogenic effluents in the water composition, and estimates of the average concentrations of elements are technogenically dependent.

The coastal image is widely manifested in various aspects of human activity, which is expressed in terms of aesthetic perception, cognition and preservation of natural and cultural heritage. “White Coast” is the figurative name of a wide strip of the right bank of the Volga River from the village of Zolotoye to Mount Durman in the southern part of the Saratov region, a unique natural and historical landscape. Such a perception of the landscape is primarily due to the predominance of upper Cretaceous and Paleocene sediments in the section (primarily the Turonian-Coniacian rhythmic strata composed of light carbonate rocks), exposed throughout the entire length of the Volga coastal ledge. The accumulation of significant geological, paleontological, archaeological and other objects in this area makes it possible to consider the territory as an interdisciplinary scientific and educational polygon, as well as an effective geoecotouristic cluster.

The article describes two groups of facies most widely represented in the collections of Lower Frasnian invertebrates of the Main Devonian Field in the Mining Museum (hardgrounds and pelecypod banks). The presence of three types of hardgrounds has been established, differing in the nature of the original bottom and the time of exposure of each hardground, and hence structural and textural features of rocks and systematic composition of oryctocenoses. The first type is crinoidal limestone with an extensive complex of sclerobionts and traces of bioerosion by Trypanites Mägdefrau, an uneven surface and a visually almost complete absence of impregnation. In hardgrounds of this type, three generations of sclerobionts are distinguished, namely: abiogenic substrates (first), incrustators of the remains of organisms of the first generation (second), and bioerosion organisms (third). The second type is micritic limestone with a smooth glass-type surface, a small complex of sclerobionts and traces of bioerosion by Trypanites Mägdefrau. The third type is pelecypod limestones with an uneven surface, isolated sclerobionts, numerous traces of bioerosion by Trypanites Mägdefrau and strong ferruginous impregnation. For the most widespread hardgrounds of the first type, the presence of specific taphofacies has been established, characterized by good preservation of organic remains of the first generation, an almost complete absence of organic remains of the second generation, and a complete absence of bioerodible organisms. The appearance of such taphofacies is due to the short exposure time of the hardground and the beginning of a rapid process of new accumulation immediately after the appearance of the first organisms of the second generation. The presence of such taphofacies emphasizes the importance of distinguishing taphofacies in certain paleofacies and certain types of oryctocenoses. In the oryctocenoses of pelecypod shells, three morphological and ethological types of cornulitids have been established. The most representative settlements of cornulithids were characteristic of calcareous clay soils with small areas of compacted bottom.

The article examines the problem of energy efficiency in the chain from the production of fertilizers to their logistics, application, and waste production and disposal based on the huge amount of data accumulated in recent years on greenhouse gas (GHG) emissions (primarily CO₂ and methane). Carbon dioxide emissions are shown to occur primarily from fuel combustion, as well as from the use of methane and CO₂ as precursors for nitrogen fertilizers. GHG emissions can be considered as a measure of energy efficiency when assessing the life cycle of mineral fertilizers. Relevant examples are given.

The article considers an ecology course in relation to the most optimal approach for primary school children–on the example of various ecosystems of the world with consideration of individual examples of adaptation genesis and evolution of wildlife. The authors used the following teaching techniques and methods: avoiding the teacher’s adaptive speech, forming the skill of hypothesizing, and laying the foundations of biological drawing. All this helps us to make a better transition from theoretical educational programs to the practical acquaintance of children with the biodiversity of natural communities. This course can be used within the framework of museum pedagogy and on educational platforms, which can be the natural landscapes of protected areas of regional significance (nature reserves and preserves, natural monuments).

As part of MSU’s Strategic Development Programme, the Youth Museum initiative is currently under development as a mobile-network project. The project consists of a system of interacting nodes, comprising a central site on the MSU campus and a network of regional subdivisions. The proposal suggests the use of mobile field museum exhibitions as an effective mechanism of interaction. In recent years, the aforementioned system was experimentally tested within the “Flotilla of Floating Universities” scientific and educational expedition. This project comprises a set of interrelated research, educational, training, artistic, and other projects. The direct and active involvement of students and schoolchildren led to the development of creative methods for the traveling exhibitions «Ancient Lukomorye» and «Living Matter in Geospheres», as well as to the methods of joint empirical and information gathering for the development of central and regional «Youth Museum» clusters. Materials were collected to create pilot versions of exhibitions, educational collections and the launch of interactive platforms at Tambov State Technical University: «Cretaceous Beach» («Palaeoecological Sandbox»), «Page of the Stone Chronicle» («Dissecting Table of a Beginner Palaeoecologist»), and others. These exhibitions are designed to ensure that they can be used effectively in educational and outreach activities on a wide range of topics. Students and schoolchildren will have the opportunity to conduct small-scale individual and collaborative research projects of varying levels of complexity using the platform format.

The ecological status of the city of Moscow was assessed using two test kits, namely, a display based on luminescent bacteria and a lichen photobiont indicator. The toxicity of tree bark in lichen ecotops was estimated by a biotest method. Changes in the cell diameters of lichen photobionts were evaluated. Evidence has been obtained of a permanent detrimental effect of chronic contamination on the specific community of the lichen test system used and possible recent contamination by the use of our bacterial luminescence test system.

Built over five centuries ago using white stone, this unique Russian architectural monument stands as the sole surviving building from the estate of the Romanov boyars, located in the ancient part of Moscow known as “Zaryadye.” Today, it serves as the museum “Chambers of the Boyars of the Romanovs.” However, the masonry has begun to collapse under the influence of water, frost, and various technogenic loads.

The monument’s location is characterized by the presence of unfavorable engineering and geological processes, with flooding being the main issue. This has led to a rise in groundwater levels and their constant interaction with the foundation’s soil. The excess moisture content in the limestone pores, saturated with aggressive components (SO42-, NO3-,Cl-), has led to limestone dissolution and leaching, as well as salt crystallization both on the surface and inside the masonry.

To understand the weathering processes affecting the limestone, researchers conducted a study on samples taken from several parts of the monument, dividing them into several groups based on their structural stability. The results revealed that the structurally unstable, completely destroyed to a dispersed state (reminiscent of flour) samples, displayed significant changes in their physical, mechanical and chemical properties. This was due to the leaching of calcite, leading to a decrease in its content from 99 % down to 40-45 %, and an increase in porosity from 15 % up to 49 %, resulting in a density reduction from 2.29 down to 1.32 g/cm³.

The study also found that microbial components in the stone could also lead to an increase in the content of finely dispersed fractions. The walls of the monument, both inside and outside, were found to be colonized by mold fungi (9 species) and bacteria (2 species). The genera Penicillium (5 species) and Aspergillus (2 species), renowned as biodestructors of stone materials, were the most prevalent among the identified species. The content of these micromycetes varied significantly (ranging from 300 to 105 CFU/g) depending on the sampling location.

To mark the 160^th anniversary of V.I. Vernadsky's birth, Lomonosov Moscow State University has organized an exhibition based on the theme of “living matter”, which to a greater or lesser extent permeates all the geospheres of our planet, provides many mechanisms of interaction between the geospheres and links between the planet and the cosmos. Natural exhibits demonstrate peculiarities of the geochemical transformation of individual organisms and their communities during the transition from the biosphere to the lithosphere, the diversity of biocosmic bodies in the history of our planet, the possibilities of modern sciences in reconstructing geobiosystems of the past. The structure of the exhibition includes a number of special blocks containing original exhibits and information, namely: “Scientist’s Cabinet” with information about the life path, scientific directions and some students and followers of Academician V.I. Vernadsky (connected to him through Moscow University). The cluster “Co-evolution of the Biosphere and Lithosphere” with disclosure of the mechanisms of transition of living matter and integral ecosystems into the “stone record” of the Earth, the structure of the pedosphere in a broad sense, the diversity of biogeoprocesses and their products in the history of the Earth, the formation of “archives of nature” in the geospheres, the functioning of geobiodynamically active zones on the example of the East European Platform; the cluster “University’s Lukomorye”, reflecting peculiarities of coastal geo-ecosystems for the general public (on the example of the Paleocene of the Volga region). Most of the exhibits of the exhibition have been obtained during the scientific and educational expedition “Flotilla of Floating Universities” (2015–2022) from the Volga region, the Caspian Sea, the Don region and the Urals and are considered in the future as the basis for the development of a model polygon of the “MSU Youth Museum”.

A popular science film “Brotherhood of Scientific Creativity. Floating University named after Vladimir Vernadsky” was shot to the 160^th anniversary of the birth of Academician V.I. Vernadsky. Work on the film was carried out during 2022–2023 as part of the activities of the scientific and educational expedition «Floating Universities Flotilla» (the field work regions being the Middle and Lower Volga river, Don river, Caspian sea). It includes the original projects “Academician Vernadsky’s Floating University” and “Floating mobile-network museum center”. The concept of the project basically provides for interdisciplinary research on a wide range of problems of the interaction of geospheres and the evolution of geoecosystems, which is being implemented by creative teams of scientists from various fields and students with the active involvement of the local population in interactive museum practices. According to the main message of the film, it is in such an environment of “scientific creativity”, in the format of field natural sciences, that the development of the ideological heritage of V.I. Vernadsky on the principles of the “Priyutinsky Brotherhood” and maturation of the “new Vernadskies” from novice researchers. The original system of scenario and producer’s decisions included the contrast of images «academician–student», a series of episodes of actual field research (the study of geological sections, the phenomenon of lithophagy, natural and anthropogenic objects) with the implicit inclusion of the “young Vernadsky” in the process (the character is an actor) and subsequent the culminating meeting of the “two Vernadskies” (montage) against the background of the Volga river – a symbolic handover of the baton of “scientific creativity” to a new generation.

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.

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.

Vladimir Vernadsky’s scientific and philosophical legacy still holds much value for the present-day world. It is largely concerned with the potential importance of two decentralized structures which can efficiently function on our planet. These are (i) the biosphere, construed as an integral entity, and (ii) the noösphere, a planet-wide human brains-based “film”. A fascinating mystery is the mechanism of the biosphere’s coordination and stable operation; important evidence has recently been presented concerning the probable regulatory role of the biosphere-wide field of signal molecules (ecomones) which include many neurotransmitters. As for the currently developing noösphere, humankind still has to invent strategies of conscious managing its activities. It is suggested that the functioning of the decentralized global noöspheric network should be subject to regulation by social chaperones. This term refers to network structures which subtly guide and promote the activities of other decentralized network structures in society.