Низкоуглеродная энергетика полного жизненного цикла

Гадиров Амал Аллахверан Оглы

doi:10.25136/2409-8647.2023.3.43758


	Journal Menu > Issues > Rubrics > About journal > Authors > About the Journal > Requirements for publication > Editorial collegium > Peer-review process > Policy of publication. Aims & Scope. > Article retraction > Ethics > Online First Pre-Publication > Copyright & Licensing Policy > Digital archiving policy > Open Access Policy > Article Processing Charge > Article Identification Policy > Plagiarism check policy > Editorial Board


	Journals in science databases


	About the Journal

MAIN PAGE > Back to contents

Theoretical and Applied Economics

Reference:

Gadirov A.A. Low carbon full life cycle energy // Theoretical and Applied Economics. 2023. № 3. P. 17-30. DOI: 10.25136/2409-8647.2023.3.43758.2 EDN: WYQFPN URL: https://en.nbpublish.com/library_read_article.php?id=43758

Low carbon full life cycle energy

Gadirov Amal Allakhveran Ogli

Student, Faculty of International Relations, Moscow State Institute of International Relations of the Ministry of Foreign Affairs of Russia

76 Vernadsky str., Moscow, 119454, Russia

a-gadirow@bk.ru

DOI:

10.25136/2409-8647.2023.3.43758.2

EDN:

WYQFPN

Received:

10-08-2023

Published:

04-09-2023

Abstract: At the current stage of energy development, it seems that in the coming years, it is hydrocarbon energy that will form the basis of the world energy market. However, there are a number of global changes that inevitably affect the energy industry, among them are: a change in the technological chains of the energy complex, the persistence of the problems of traditional energy, an increase in energy demand, the high impact of emissions from the use of hydrocarbons on the climate, and many others. In this regard, solutions related to low-carbon energy, in particular solar, wind, hydropower and other renewable energy applications, are becoming increasingly important. A special place in this segment is occupied by low-carbon full-cycle energy, which is studied in the article. In particular, in Russia, full-cycle low-carbon energy appears to be a very important part of the development of the energy industry, as it can significantly reduce costs and negative externalities for the environment. In this regard, one of the objectives of the study is to analyze the current situation in the field of low-carbon energy in the Russian Federation, its regulation, as well as development prospects, taking into account the special role of the Russian Federation as one of the key exporters of traditional hydrocarbons.

Keywords:

green energy, decarbonization, low-carbon energy, Russian energy, international energy, energy security, energy cycle, international relations, multilateral diplomacy, ecology

Introduction

As the average standard of living of the population of the planet increases, the population of the planet itself increases, and the consumer demand of the population of the planet increases. Consequently, production capacities aimed at its satisfaction are being increased. All of the above contributes to the growth of global electricity consumption. And despite the fact that traditional sources remain the main source of energy, the world community is concerned about finding more efficient (alternative) energy sources.

So in the world economy, the main problems are identified: depletion of natural resources and uneven distribution of natural resources. They dictate the need to search for new and develop existing alternative energy sources. In this regard, it is particularly important and relevant to use the full potential of low-carbon full-cycle energy as the next step in the technological chain of the energy industry.

Within the framework of this study, the goal is to prove the importance of low-carbon full-cycle energy and its development for Russia based on the analysis of the conjuncture and current trends in the energy industry. To achieve this goal, a number of tasks have been completed:

1) The main trends in the development of the energy industry are identified, taking into account the energy transition ^[13];

2) The possibilities of the Russian Federation in the issue of increasing the production of low-carbon energy at full-cycle facilities are analyzed.

The main results of the study include proof of the prospects of this technological solution for the Russian economy, taking into account its role as the main and reliable supplier of energy to Asia.

Methodology

In the study, we will first define the terminology. Full–cycle low-carbon energy is an energy industry that strives to reduce the emission of hydrocarbons during the entire technological chain of production and transmission of electricity. Currently, most countries are pursuing a policy of decarbonizing the economy, i.e. avoiding the production and consumption of electricity produced with the help of hydrocarbons. For example, European countries have almost completely abandoned coal production and closed coal mines on their territory.

Based on the definition, energy production technologies with high CO2 emissions include (non-renewable energy sources):

Coal industry
Gas industry
Oil industry

Energy production technologies with low CO2 emissions include (renewable energy):

Solar Power Plants (SES)
Wind power plants (wind farms)
Hydroelectric power plants (HPP, GRES)
Biofuels
Hybrid systems

Research results

Despite the trends highlighted above, the availability of hydrocarbon resources remains a significant factor for the economy of each country. The availability of natural resources and a high level of development of the mining and processing industry ensures the competitiveness of the country and its political and economic potential.

Figure 1. Proven oil and gas reserves, tons

Figure 1 shows the growth of proven oil and gas reserves, but this growth has been slowing down in the last decade. According to numerous experts, there are quite a lot of reserves of hydrocarbon resources of the planet and it can be used for several more decades ^[1]. However, easily accessible (both by geographical location and geological occurrence) deposits that are already in development will be depleted over time. And the development of new, undeveloped deposits is considered to be significantly difficult from a technical and, consequently, from an economic point of view, since new undeveloped deposits are usually difficult to develop ^[14], which in turn requires large financial investments, namely geological exploration, technical calculations, supply of communications, purchase and delivery of expensive equipment, field development, laying of pipelines or railway tracks and communications, transportation of fuel to the consumer.

In addition, oil, gas and coal deposits are not geographically evenly distributed, which means that many countries do not own their reserves, and completely depend on those countries with sufficient energy reserves in terms of energy.

A derivative of the increase in demand and consumption of hydrocarbons is such a problem as emissions of carbon dioxide and harmful substances that cause a greenhouse effect and a number of environmental problems described below.

Figure 2. Carbon dioxide emissions per capita in tons

As the comparison of Figures 1 and 2 shows, the increase in atmospheric emissions from ₂ directly depends on the growth of energy consumption. So until 2020, due to the lack of economic growth, there was a decline in energy consumption and, consequently, _CO2 emissions associated with the energy industry fell. And already starting from 2022, when economic growth began to be observed, the growth of energy consumption increased and, as a result, _CO2 emissions increased.

In 2022, China, the United States, India, Russia, Japan, Germany, Saudi Arabia, South Korea, and Iran are the leaders in terms of the amount of _CO2 emissions.

According to the World Wildlife Fund, the risks of loss of various ecological systems and various representatives of the animal world are increasing. This threat to the global ecosystem, according to scientists and environmentalists from the Wildlife Fund, is caused by _CO2 emissions, and mainly, according to the Wildlife Fund, these emissions from the burning of fossil fuels ^[3].

According to the statistical yearbook of world energy for 2022, the increase in atmospheric emissions from ₂ is directly proportional to the growth of energy consumption. So until 2022, due to the lack of economic growth, there was a decline in energy consumption and, consequently, _CO2 emissions associated with the energy industry fell. And already starting in 2023, when economic growth began to be observed, the growth in energy consumption increased and, as a result, _CO2 emissions increased.

The main source of _CO2 combustion in 2022 was coal, oil in second place, and natural gas in third place ^[4].

The high dynamics of energy consumption means that the constant increase in the consumption of the total amount of energy by the population of the planet inevitably leads to the depletion of natural non-renewable resources of the planet. Thus, according to the statistical yearbook of world energy, due to the increase in global demand for energy, energy consumption in 2022 increased by 5% ^[2].

The increase in energy consumption is also associated with an increase in the population of Asian countries, which exacerbates the task of ensuring reliable energy supply and equal access to energy for consumers, especially if we take into account the problem of poverty and the inability for the poorest segments of the population to receive energy at rising prices.

The development of energy technologies largely determines the pace of economic growth and its sectoral structure in the long term, influencing the magnitude of absolute and relative production costs in the country, as well as the limit of production capabilities of the national economy. At the same time, economic growth is an important factor in the dynamics of energy demand.

It is safe to say that the crisis of 2020 will lead not only to a global decrease in energy prices, but also to a decrease in energy consumption as a result of a decrease in production capacities of all countries of the world.

Taking into account the above, it should be noted that climate risks have a significant impact not only on social development and human life, but also on the industries themselves. We will highlight such risks for each industry in Table 1.

Table 1. Risks of climate change for energy

Branch	Climate risks
Oil and gas production	1) severe climate changes and accompanying adverse weather events (heavy rains, blizzards, heavy snowfall, ice, fog) contribute to an increase in emergency situations; 2) climate warming leads to the melting of age-old frozen rocks, which causes the deformation of wells, the destruction of various production and technological structures.
TPP/NPP	1) the reliability of thermal power plants and nuclear power plants depends very much on the deviation of the ambient temperature from critical values. It affects the installed capacity utilization factor (KIUM), which characterizes the efficiency of a nuclear power plant and a thermal power plant. Thus, an increase in ambient temperature requires immediate cooling of power units; 2) for most thermal and nuclear power cooling plants, a sufficient amount of water used in cooling towers is required for the technological process of cooling power units, and water intake comes from nearby reservoirs.
Hydroelectric power station	1) floods and droughts affect the operating conditions of hydroelectric power plants, and this in turn affects the cost of electricity generation; 2) changes in the amount of bottom sediments affect the operating conditions of hydroelectric power plants, an increase in depreciation of equipment, which in turn affects a more frequent shutdown of technological processes for repair and replacement of technical equipment. Consequently, it also leads to an increase in the cost of energy production; 3) an increase or decrease in the average amount of precipitation (showers, rains, snow), as well as an increase in evaporation during climate warming, a shift in spring flood leads to a change in displacement and a change in the technological processes of a hydroelectric power plant, therefore, affects the cost of electricity generation; 4) the melting of glaciers also affects the displacement of rivers.
Downstream	1) transportation of electric energy mainly takes place through power lines. Uninterrupted trouble-free transmission of electricity is affected by the following dangerous climatic factors affecting icing and wire breakage of power lines: wind, hurricane, hail, thunderstorm, downpour, ice; 2) climate warming also leads to an increase in emergency situations, as a consequence of an increase in air temperature: the technological load on the wires of power lines increases – the wires stretch, sag, touch each other, which contributes to short circuits.

Source: compiled by the author

All of the above stimulates the increasing need to search and research the use of low-carbon energy sources for more efficient technological and less emergency use. According to many researchers, low-carbon energy sources are the main means of adapting the energy industry to the conditions of a changing climate and modern environmental requirements.

Figure 3. Low-carbon energy consumption in the world, TWh

Having considered the main trends in the global development of the energy industry, we will proceed to the analysis of the situation in the Russian Federation. Russia, despite its potential in the introduction of low-carbon energy sources, continues to lag behind, the scale of the use of alternative energy is very limited ^[15]. Recently, however, there has been an increase associated with the active introduction of new technological solutions and government support for the industry. The dynamics of the development of low-carbon electricity generation in the Russian Federation is reflected in Figure 4.

Figure 4. Low-carbon energy generation in Russia, GWh

Source: compiled by the author based on data https://rreda.ru/statistics_of_renewable_energy_in_russia

At the same time, despite the relatively low role of low-carbon energy sources in the Russian energy balance, significant technological groundwork in this industry belongs to Russian scientists:

- a new chlorine-free technology for producing solar polycrystalline silicon with low energy costs, with a service life of 40 years;

- modern technological developments in geothermal energy and equipment for small hydroelectric power plants;

- cheap and reliable small-capacity solar and wind installations, wind turbines, photovoltaic solar collectors;

- technologies for processing peat bogs into biofuels.

In addition, experimental and pilot plants were created ^[5]:

1) Kislogubskaya tidal power plant on the Kola Peninsula with a capacity of 450 kW;

2) experimental Paratunskaya two-circuit, with a capacity of 11 MW and experimental-industrial Paratunskaya single-circuit geothermal thermal power plants (GeoTES);

3) experimental solar base in Alushta with a large "solar boiler";

4) solar water heating installations in the Rostov region, the Republic of Dagestan, in the Krasnodar Territory.

Taking into account the technological groundwork, as well as significant prospects for the development of low-carbon energy, state incentive measures to support the development and introduction of alternative energy sources have been developed and introduced into the economy in Russia ^[16]. Let's characterize the Russian potential for the development of low-carbon full-cycle energy.

Russia's potential in the development of wind energy is considered very large ^[17]. In addition, Russia is a manufacturer and exporter of special equipment for wind power plants ^[6]. However, in Russian practice, it is calculated by experts according to the main indicator – a large area of the country, while it is not taken into account that the wind speed in many regions of the country is either low or average, and this speed is not enough for the cost-effective operation of wind turbines.

Russia has excellent conditions for hydropower – there are many wide and fast rivers with good water filling in the country, especially in the northern regions. That is why in Russia the main direction of development of alternative energy sources remains – hydropower. In Russia, hydropower is an order of magnitude more energy efficient than wind power and any other type of low-carbon energy ^[18,19]. That is why the most rational solution is not to invest significant forces and finances from the state budget in the introduction of wind energy. Nevertheless, in those regions where geographical, weather and climatic conditions allow the installation of energy-efficient wind turbines (mountainous regions of the Caucasus, coastal regions) they are still installed ^[20,21].

Currently, the total volume of all low-carbon energy facilities does not exceed 0.1% of Russia's energy balance. The potential of these facilities has been used by 0.5% so far. And in the all-Russian economic potential, these volumes do not exceed 10%.

The prospects of the Russian Federation in the development of solar energy are quite optimistic for the following reasons:

1) the presence of large areas in the Russian Federation;

2) the presence of significant territories with a large number of sunny days in the following regions: Stavropol; Krasnodar Krai; Areas of the Caspian Sea and the Black Sea; Volgograd; Southern Siberia; Southern Urals; Chita; Astrakhan; Kalmykia; Buryatia; Rostov; Far East; Altai.

To date, there are about 35 solar power plants operating in Russia, the total installed capacity of which is currently 850 MW, another 30 solar power plants are at various stages of construction. It is assumed that the total capacity of solar power plants under construction will be 810 MW ^[22,23].

It is estimated that the generation potential of Russian solar energy in terms of hydrocarbon fuel is from 2200 billion tons to 2500 billion tons according to various sources. Today, however, it is possible to count on the cost-effective use of solar energy equal to only 12.5 million tons of hydrocarbon fuel. This is due to seasonal fluctuations in daylight hours. So, for example, despite the sufficient intensity of solar radiation in the northern latitudes of Russia, the sunny time of day is very short.

In Russia, work is underway in various areas of solar energy, for example, various methods and methods are being developed for more cost-effective use of various alternative energy sources ^{[7],[8],[9],[10],[11]}.

From all that has been said, it follows that there are many regions in the Russian Federation in which it is possible and necessary to introduce solar energy and install both solar power stations and autonomous solar electric panels.

Today, the Russian Federation is not as actively using wind power generators as other countries. However, in Russia there are many manufacturers engaged in the production of wind power equipment and the construction of wind power plants, including the production of equipment for wind power is engaged in the military-industrial complex. It is possible to single out the five leaders of wind energy production, namely: LLC "SKB Iskra", LLC "Sapsan-Energiya", "LMV Wind Power", LLC "Vetro Svet", LLC "Energivind".

It is estimated that the potential for the construction of wind power plants in Russia is approximately 6,400 billion kilowatt hours, this number is 6 times more than the current generation of all electricity in the country. Thus, the Russian Federation has a huge potential for the construction of wind power plants for the production of electricity from free wind energy, as well as for the transportation of electricity to other countries ^[24,25].

Conclusion

Currently, hydrocarbon energy sources will remain the most demanded energy resources. However, due to the highlighted limitations of traditional energy sources, it is necessary to reconsider approaches to low-carbon energy sources.

There are technological solutions that allow you to independently supply electricity to any building, enterprise, car. But the problem of using only one type of low-carbon energy source (without additional connection of the consumer to the electrical network) lies both in the economic justification and in the reliable uninterrupted operation of this low-carbon electric current source.

In addition, those states whose economies are heavily dependent on the hydrocarbon industry, if they invest in the development, construction and launch of alternative power plants, they are not doing it actively enough.

Russia belongs to such countries, the use of low-carbon energy sources in our country is developing slowly, despite the high estimated potential. At the same time, it is impractical to focus on the development of only renewable energy sources in the Russian Federation both for economic reasons and due to the fact that it is economically more expedient to use hydrocarbons.

References

1. Zhilina, I. Yu. (2009). Resource economy and economic growth. ESPR, 1. Retrieved from https://cyberleninka.ru/article/n/syrievaya-ekonomika-i-ekonomicheskiy-rost
2. Total electricity consumption. Retrieved from https://energystats.enerdata.net/total-energy/world-consumption-statistics.html
3. Simple answers to complex climate questions. Retrieved from https://wwf.ru/what-we-do/climate-and-energy/faq/
4. Technologies for capturing, storing and using carbon (CCUS) the technological basis for the decarbonization of heavy industry in the Russian Federation. Retrieved from https://www.skoltech.ru/app/data/uploads/2022/11/CCUS-Skolteh-2022-11-10.pdf
5. Development of non-traditional energy in Russia. Retrieved from http://www.gigavat.com/netradicionnaya_energetika_v-i-e_9.php
6. World Wind Energy Association. Retrieved from https://energo.house/veter/strana-lider-ves.html
7. Shatunovsky, V.L., & Shatunovskaya, E.A. (2016). Microprocessor means in electric drives. Publishing Center of the Russian State University of Oil and Gas named after I.M. Gubkina. Part 1, p. 52. Moscow.
8. Shatunovsky V.L., & Shatunovskaya, E.A. (2019). A device for measuring the real power of the receiver in a single-phase power supply circuit based on the microcontroller board "ESP. Collection of reports of the III Regional scientific and technical conference "Gubkin University in solving problems of the oil and gas industry of Russia", dedicated to the 110th anniversary of A.I. Skoblo and the 105th anniversary of G K. Schreiber, p. 239.
9. Zinoviev, V.V., Bartenev, O.A., & Beltyukov, A.P. (2018). Modeling of solar converters with uneven illumination. Industrial Energy. Issue 7. P. 58–67. Retrieved from http://www.promen.energy-journals.ru/index.php/PROMEN/article/view/1099
10. Zinoviev, V.V., & Bartenev, O.A. (2020). Diagnostics of industrial solar modules in the areas of direct and reverse branches of the current-voltage characteristic under non-uniform illumination. Industrial Energy. Issue 1, pp. 56–62. Retrieved from http://www.promen.energy-journals.ru/index.php/PROMEN/article/view/1352
11. Bartenev, O.A., Lipaev, A.A., & Zinoviev, V.V. (2020). Solar Energy in the Technosphere of Russia Management of the technosphere. Vol. 3. No. 1. pp. 52-69. Retrieved from https://www.elibrary.ru/item.asp?id=42732272
12. Portnyagin, N.N., Shatunovsky, V.L., & Melik-Shakhnazarova, I.A. (2018). A complex for measuring electrical quantities in power supply systems based on Arduino microcontroller boards. Electrotechnical and information complexes and systems, 14(1), 81-87.
13. Hernández Serrano Pedro, Zaveri Amrapali. (2020). Venturing the Definition of Green Energy Transition: A systematic literature review.
14. Kryukov, V., Moe, Arild. (2018). Does Russian unconventional oil have a future?. Energy policy, 119, 41-50. doi:10.1016/j.enpol.2018.04.021
15. Kovtun, D., Tovmasyan, N., & Nazarov, A. (2021). Trends and conditions for the development of green energy in the Russian Federation. E3S Web of Conferences. 270.01040. doi:10.1051/e3sconf/202127001040
16. Maksimov, A. (2020). RES 2.0: New Green Energy Development Program in Russia. Retrieved from https://energypolicy.ru/a-maksimov-vie-2-0-novaya-programma-razvitiya-zelenoj-energetiki-v-rossii/energetika/2020/17/13/
17. Pestrikova, I. E., Anikina, E. V., Kirilenko, E. S., Konakbaeva, A. S., & Pestrikov, M. E. (2012). To the question of the prospects for the development of wind energy in Russia. OmGTU. No. 1. Retrieved from https://cyberleninka.ru/article/n/k-voprosu-o-perspektivah-razvitiya-vetroenergetiki-v-rossii
18. Berdyshev, I., Bitney, V., Gabdushev, D., Golokhvastov, E., Chegodaev, A., & Vanin A. (2023). Study of the prospects for the development of hydropower in Siberia, the Far East and Kamchatka. Retrieved from https://energypolicy.ru/issledovanie-perspektivyrazvitiya-gidroenergetiki-v-sibiri-na-dalnem-vostoke-i-kamchatke/energetika/2023/13/15/
19. Khaidarova, A.F., & Khuramshin, A.A. (2016). Separate aspects of the prospects for the development of the Russian hydropower. Actual problems of the humanities and natural sciences, 4-1. Retrieved from https://cyberleninka.ru/article/n/otdelnye-aspekty-perspektivy-razvitiya-rossiyskoy-gidroenergetiki
20. Goryachev, S.V., & Smolyakova, A.A. (2022). Problems and prospects of wind energy systems in russia. International Research Journal, 5(119). Retrieved from https://doi.org/10.23670/IRJ.2022.119.5.048
21. Kudelin, A., & Kutcherov, V. (2021). Wind ENERGY in Russia: The current state and development trends. Energy Strategy Reviews, 34, 100627. doi:10.1016/j.esr.2021.100627
22. Proshin, A.D. (2019). Solar energy in Russia. World science, 12(33). Retrieved from https://cyberleninka.ru/article/n/solnechnaya-energetika-v-rossii
23. Bataev, Aleksey, Potyarkin, V., Glushkova, A., & Samorukov, D. (2020). Assessment of development effectiveness of solar energy in Russia. E3S Web.
24. Renewable energy market of the Russian Federation: current status and development prospects. (2023). SOK magazine, 4, 68-78. Retrieved from https://www.c-o-k.ru/articles/rynok-vozobnovlyaemoy-energetiki-rf-tekuschiy-status-i-perspektivy-razvitiya-chast-1
25. Growing renewable energy markets: is there a potential for energy exports from Russia to Europe. (2021). Retrieved from https://www.vedomosti.ru/press_releases/2021/10/18/rastuschie-rinki-vie-est-li-potentsial-eksporta-energii-iz-rossii-v-evropu

First Peer Review

Peer reviewers' evaluations remain confidential and are not disclosed to the public. Only external reviews, authorized for publication by the article's author(s), are made public. Typically, these final reviews are conducted after the manuscript's revision. Adhering to our double-blind review policy, the reviewer's identity is kept confidential.
The list of publisher reviewers can be found here.

The subject of the study. Based on the title, it seems possible to conclude that the article should be devoted to low-carbon energy of the full life cycle. In general, the content of the article corresponds to the stated topic, but the depth of immersion in the topic is superficial (described in more detail in the relevant paragraphs of the review). The research methodology is based on the presentation of well-known facts and judgments. The author should analyze the numerical data confirming the above theses, as well as demonstrating trends in the development of low-carbon energy in Russia and the world, existing problems and justifying ways to solve them. It should be emphasized separately that there are no graphic objects (figures /tables) that allow us to study the composition/ structure of the phenomena and processes under consideration, as well as the dynamics of their development over time. The relevance of the study of issues related to the development of low-carbon energy is beyond doubt, since there is a request for them in public authorities (both in Russia and abroad), in expert circles, and in the scientific community. At the same time, the potential readership is interested in specific existing problems and recommendations justified by the author to solve them. There is no scientific novelty in the materials submitted for review. At the same time, it should be noted that within the framework of the stated topic, there are a very large number of scientific niches that would be interesting to occupy due to the potential demand from a wide range of people. Style, structure, content. The style of presentation is scientific in terms of the absence of journalistic and colloquial expressions. There are subheadings in the article, but it is difficult to call them scientific structural elements. Perhaps the author should divide the article into blocks that are traditional for scientific articles: "Introduction", "Problem statement", "Methodology and research conditions", "Research results", "Discussion of research results", "Conclusions and further research directions". The text contains a large number of judgments and theses, the appearance of which, firstly, is very confusing (without connection with the previous and subsequent text), and, secondly, is not justified in any way. For example, the author argues that today the Russian Federation is not as actively using wind power generators as other countries. "Not so active" - how is that? The text did not reveal an analysis of statistical data either in Russia or abroad. The text must be carefully proofread for typos. For example, in the text placed under the subtitle "Thermal and nuclear power plants" the following is written: "Reliability of thermal power plants and nuclear power plants" (must be stations). Bibliography. The bibliographic list formed by the author includes 12 titles. It is valuable that the list of sources contains those that contain numerical data. At the same time, attention is drawn to the absence, firstly, of publications after 2020, and, secondly, of publications in foreign periodicals. When finalizing the article, this must be eliminated, as this will allow us to study current trends in domestic and foreign thought on the development of low-carbon energy, which is of interest to the entire world community. Appeal to opponents. Despite the generated list of references and the presence of references in the text, it was not possible to identify any scientific discussion. When finalizing the article, identifying specific problems on the subject of research and forming sound recommendations for their solution, the author is recommended to discuss the results obtained with those contained in scientific publications of other domestic and foreign scientists. Conclusions, the interest of the readership. Taking into account all the above, we conclude that it is necessary to finalize the article, which should be informative and in-depth. If this is done, the reviewed material will turn into a high-quality scientific article with scientific novelty and practical significance, as well as in demand in Russia and abroad by a wide range of people.

Second Peer Review

The subject of the research in the peer-reviewed article is low-carbon energy of the full life cycle. The research methodology is based on the study of statistical data on the spread of low-carbon energy in the world and the Russian Federation, their analysis, the use of general scientific research methods, visualization of the results obtained. The authors rightly associate the relevance of the work with the search for new and development of existing alternative energy sources in the context of growing consumer demand and increasing production capacity. The scientific novelty of the peer-reviewed study consists in proving the importance of low-carbon full-cycle energy and its development for Russia based on an analysis of the conjuncture and current trends in the energy industry. Structurally, the following sections are highlighted in the article: Introduction, Methodology, Research results, Conclusion, Bibliography. The publication provides information on the dynamics of proven oil and gas reserves, a slowdown in the growth rate of this indicator in the last decade is noted, the difficulties of developing new fields are highlighted, the global dynamics of carbon dioxide emissions per capita is shown, the risks of climate change for various energy sub-sectors are summarized, low-carbon energy consumption in the world is clearly reflected, as well as an increase in its generation In Russia, energy production with low carbon dioxide emissions is considered: solar, wind power plants, hydroelectric power plants, biofuels and hybrid systems. Special attention was paid to the prospects for the development of solar energy in our country, the need for the introduction of both solar power plants and autonomous solar electric panels was noted. In the final part of the publication, it is proposed to focus on the development of not only renewable energy sources in the Russian Federation, but also the use of hydrocarbons. The bibliographic list includes 25 sources – scientific publications on the topic under consideration, Internet resources, and statistical data. The text contains targeted references to bibliographic sources, which confirms the existence of an appeal to opponents. Of the shortcomings that need to be eliminated, the following should be noted. Firstly, according to the title (title) of the publication article, the essence and object of the study are unclear: it is not clear on the example of which object the low-carbon economy is being considered (in general, in the marine economy, in some country, region, or on the example of any enterprise). Secondly, the "Methodology" section does not specify which research methods were used to convert the initial data into the results obtained, as well as the stages of the work, that is, the research methodology itself is not disclosed. Thirdly, for some reason the names of the drawings are placed before them, and not after the drawings as provided for in the design rules, it is also proposed to change the units of change on the vertical axis of Figure 1 to facilitate the perception of information by readers. The reviewed material corresponds to the direction of the journal "Theoretical and Applied Economics", reflects the results of the work carried out by the authors, contains elements of scientific novelty and practical significance, may arouse interest among readers, and is recommended for publication taking into account the comments made.

Link to this article

You can simply select and copy link from below text field.