Post-COVID-19 Revitalisation and Prospects for Climate Neutral Energy Security Technologies

• Autorzy: Borysiak Olena , Brych Vasyl

Identyfikatory

DOI

10.35784/pe.2022.2.04

Warianty tytułu

PL

Rewitalizacja po COVID-19 i perspektywy wykorzystania neutralnych dla klimatu technologii i bezpieczeństwa energetycznego

• Języki publikacji: EN

Abstrakty

EN

Dealing with the effects of COVID-19 is on the energy security agenda. Consolidation of efforts at the regional, national and international levels to exchange experience in the implementation of successful practices and the formation of institutional support of the sustainable energy development contributes to the post-COVID-19 revitalisation. With this in mind, the article is devoted to studying the peculiarities and experience of the post-COVID-19 revitalisation of the energy sector in different countries and determining the development prospects of climate-neutral technologies in the energy security sphere. A change in the behaviour of energy consumers by the secondary energy source in the context of increased quarantine restrictions has been established. In particular, a downward trend in the volume of energy consumption from traditional sources (oil, coal, etc.) has been traced. At the same time, the demand for energy consumption from renewable sources (solar energy, wind energy, etc.) has grown, which made it possible to diagnose the reduction in CO2 emissions. Based on the analysis of measures to reduce the negative impact of the COVID-19 on energy security in different countries, the integration of the foundations of climate neutrality through the development of new critical technologies in the field of renewable energy sources has been established. As a result of a survey of green energy stakeholders using PEST analysis, it was proved that the complexity of integrating the principles of climate neutrality into the energy sector is that the result is not an economic effect but primarily an environmental effect (energy decarbonization). As a result, a methodology for determining the sustainability indicators for developing climate-neutral technologies in energy security using fuzzy set methods is proposed. The prospect of developing climate-neutral technologies in energy security lies in the transition to cross-sectoral interaction based on a closed cycle of energy consumption from renewable sources and the use of Industry 4.0 technologies. The proposed methodology will be a tool for further research on the developing organizational and innovative support and justifying the economic feasibility of introducing climate-neutral technologies based on the clustering of industries and a circular economy in the energy security sphere.

Słowa kluczowe

EN

energy decarbonization; climate-neutral innovations; renewable energy; critical infrastructure; COVID-19; sustainable development; circular economy

PL

dekarbonizacja energii; innowacje neutralne dla klimatu; energia odnawialna; infrastruktura krytyczna; COVID-19; zrównoważony rozwój; gospodarka o obiegu zamkniętym

• Wydawca: Lublin University of Technology
• Czasopismo: Problemy Ekorozwoju
• Rocznik: 2022
• Tom: Vol. 17, nr 2
• Strony: 31--38
• Opis fizyczny: Bibliogr. 23 poz., tab.

Twórcy

autor

Borysiak Olena

• West Ukrainian National University, Department of Marketing, Lvivska 11, 46000, Ternopil, Ukraine

• https://orcid.org/0000-0003-4818-8068

autor

Brych Vasyl

• West Ukrainian National University, Department of International Tourism and Hospitality Business, Lvivska 11, 46000, Ternopil, Ukraine

• https://orcid.org/0000-0002-4277-5213

Bibliografia

• 1. BORYSIAK O., BRYCH V., 2021, Methodological Approach to Assessing the Management Model of Promoting Green Energy Services in the Context of Development Smart Energy Grids, Financial and credit activity: problems of theory and practice, 4(39): 302-309, DOI: 10.18371/.v4i39.241319.
• 2. BRYCH V., MANZHULA V., BORYSIAK O., BONDARCHUK M., ALIEKSIEIEV I., HALYSH N., 2021, Factor Analysis of Financial and Economic Activities of Energy Enterprises of Ukraine, Proceedings of the XI-th International Conference on Advanced Computer Information Technologies (ACIT’2021), Deggendorf, Germany: 415-419, DOI:10.1109/ACIT52158.2021.9548358.
• 3. BRYCH V., BORYSIAK O., HALYSH N., LIAKHOVYCH G., KUPCHAK V., VAKUN O., 2022, Impact of International Climate Policy on the Supply Management of Enterprises Producing Green Energy, Lecture Notes in Networks and Systems, 383.
• 4. BRYCH V., BORYSIAK O., YUSHCHENKO N., BONDARCHUK M., ALIEKSIEIEV I., HALYSH N., 2021, Factor Modeling of the Interaction of Agricultural Enterprises and Enterprises Producing Green Energy to Optimize the Biomass Supply Chain, Proceedings of the XI-th International Conference on Advanced Computer Information Technologies (ACIT’2021), Deggendorf, Germany: 425-427, DOI: 10.1109/ACIT52158.2021.9548463.
• 5. BRYCH V., MYKYTYUK P., HALYSH N., BORYSIAK O., ZHEKALO G., SOKOL M., 2021, Management Model of Energy Enterprises Innovative Development Within Physiological Working Conditions, Propósitos Y Representaciones, 9, SPE(3): e1173, DOI: 10.20511/pyr2021.v9nSPE3.1173.
• 6. BRYCH V., ZATONATSKA T., DLUHOPOLSKYI O., BORYSIAK O., VAKUN O., 2021, Estimating the Efficiency of the Green Energy Services’ Marketing Management Based on Segmentation, Marketing and Management of Innovations, 3: 188-198, DOI: 10.21272/mmi.2021.3-16.
• 7. COVID-19 can change the future of energy for many years to come – IEA forecast, 2020, https://mind.ua/news/20217013-covid-19-mozhe-zminiti-majbutne-energetiki-na-dovgi-roki-prognoz-mea (25.01.2022).
• 8. DiXi Group , 2021, Quarterly report 1, World best practices of green recovery during the COVID-19 pandemic: opportunities for Ukraine, 2021, https://dixigroup.org/wp-content/uploads/2021/04/dixi_greenrecovery_qr1-1.pdf (25.01.2022).
• 9. DLUHOPOLSKYI O., BRYCH V., BORYSIAK O., FEDIRKO M., DZIUBANOVSKA N., HALYSH N., 2021, Modeling the Environmental and Economic Effect of Value Added Created in the Energy Service Market, Polityka Energetyczna, 24(4): 153-164, DOI: 10.33223/epj/144935.
• 10. Fuzzy logic information site, Methods of fuzzy cluster analysis, FCM method, 2021, https://sites.google.com/site/ne4itkalogika/necitka-klasterizacia/metod-fcm (13.02.2022)
• 11. JIANG P., KLEMEŠ J. J., FAN Y. V., FU X., BEE Y. M., 2021, More Is Not Enough: A Deeper Understanding of the COVID-19 Impacts on Healthcare, Energy and Environment Is Crucial, International Journal of Environmental Research and Public Health, 18(2): 684. DOI: 10.3390/ijerph18020684.
• 12. ELAVARASAN R. M, PUGAZHENDHI R., SHAFIULLAH G. M., IRFAN M., ANVARI-MOGHADDAM A., 2021, A hover view over effectual approaches on pandemic management for sustainable cities – The endowment of prospective technologies with revitalization strategies, Sustainable Cities and Society, 68: 102789, DOI: 10.1016/j.scs.2021.102789.
• 13. Global Energy Review, 2020, The impacts of the Covid-19 crisis on global energy demand and CO2emissions, International Energy Agency, https://www.iea.org/reports/global-energy-review-2020 (13.06.2021).
• 14. HALYSH N., BORYSIAK O., BRYCH V., KOROL V., VAKUN O., ZABURANNA L., 2021, Technical and Economic Analysis of Implementation of Standards for Solid Fuels, Lecture Notes in Networks and Systems, 194: 931-942, DOI:10.1007/978-3-030-69221-6_72.
• 15. KUZEMKO C., BRADSHAW M., BRIDGE G., GOLDTHAU A., JEWELL J., OVERLAND I., SCHOLTEN D., VAN DE GRAAF T., WESTPHAL K., 2020, Covid-19 and the politics of sustainable energy transitions, Energy Research and Social Science, 68: 101685, DOI: 10.1016/j.erss.2020.101685.
• 16. LIAKHOVYCH G., KUPCHAK V., BORYSIAK O., HUHUL O., HALYSH N., BRYCH V., SOKOL M., 2021, Innovative human capital management of energy enterprises and the role of shaping the environmental behavior of consumers of green energy based on the work of smart grids, Propósitos y Representaciones, 9, SPE(3): e1293, DOI:10.20511/pyr2021.v9nSPE3.1293.
• 17. MARINAS M., 2018, Renewable energy consumption and economic growth. Causality relationship in Central and Eastern European countries, PLoS One, 13(10): e0202951, DOI: 10.1371/journal.pone.0202951.
• 18. MULESА O. YU., 2015, Adaptation of the fuzzy c-means method to the problem of determining the structure of social groups, Tekhnolohichnoy audit i reservy proizvodstva, 2/2 (22): 73-76, https://www.uzhnu.edu.ua/uk/infocentre/get/5703 (13.02.2022).
• 19. PENG J., YEE V. F., JIŘÍ J. K., 2021, Impacts of COVID-19 on energy demand and consumption: Challenges, lessons and emerging opportunities, Applied Energy, 285: 116441, DOI: /10.1016/j.apenergy.2021.116441.
• 20. PYSMENNA U., TRYPOLSKA H., SOTNYK I., 2020, Vulnerability of the renewable energy sector to energy security threats exacerbated by the COVID-19 pandemic, Pidpryiemnytsvo ta innivatsii, (14): 79-85, DOI: 10.37320/2415-3583/14.16.
• 21. Record of Ukrainian energy. In August, the share of renewable energy reached 16.6%, 2021, https://glavcom.ua/economics/finances/rekord-ukrajinskoji-energetiki-u-serpni-chastka-vidnovlyuvanoji-energiji-dosyagla-166-707678.html (25.01.2022).
• 22. Renewables now, 2021, https://renewablesnow.com/ (25.01.2022).
• 23. SOAVA G., MEHEDINTU A., STERPU M., GRECU E., 2021, The Impact of the COVID-19 Pandemic on Electricity Consumption and Economic Growth in Romania, Energies, 14, 2394, DOI: 10.3390/en14092394.

Uwagi

Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).