ENVIRONMENTAL AND ENERGY JUSTIFICATION OF THE NEED FOR AGRICULTURAL AREAS TO ENSURE FOOD SECURITY OF UKRAINE
DOI:
https://doi.org/10.34132/ers.2023.01.01.03Keywords:
arable land; food safety; WFE strategy; Efficiency of photosynthesis; crop capacity; food basket; ecosystem energy.Abstract
The article examines the energy equivalent of the needs in cultivated areas to ensure food security of Ukraine. It was determined that integration into WFE-strategies of food policy requires a comprehensive assessment of the energy component of agricultural production relative to the area of arable land, which will include the productivity of the main crops in the aspect of converting solar energy into food calories. A methodology was created and the efficiency of converting solar energy into the commodity energy value of the products of the grocery basket was calculated: 0.15-0.8% for cereals and vegetables, 0.042-0.054% for meat, 0.015-0.035% for drinks and spices, 0.12 % for dairy products, 0.37-0.93% for eggs. The overall efficiency of human consumption of solar energy through the food chain is 0.22%. To meet these needs, 1,831.3 m2 is needed, which receives 545.8 MW of solar energy during the growing season. It was determined that the yield fluctuations of the main crops are sinusoidal and their use in modeling the need for sowing areas will in the future allow to develop a dynamic model of management of benefits and quotas to stimulate the coverage of a possible shortage of certain main products. Also estimated is the amount of energy that can be used without affecting the yield by renewable energy when using a mobile configuration of its placement (or, on the contrary, directed to artificial lighting of the crop under stationary systems). As a result, basic indicators were obtained, which can be relied upon when developing a food security strategy for cities, and it was also determined that a standard household plot of 0.25 hectares fully covers the needs of one person with a surplus.
References
Herrera-Franco, G., Bollmann, H. A., Lofhagen, J. C. P., Bravo-Montero, L., & Carrión-Mero, P. (2023). Ap-proach on water-energy-food (WEF) nexus and climate change: A tool in decision-making processes. Environmental Development, 100858. https://doi.org/10.1016/j.envdev.2023.100858
Muhirwa, F., Shen, L., Elshkaki, A., Chiaka, J. C., Zhong, S., Bönecke, E., Hirwa, H., Seka, A. M., Habiyakare, T., Tuyishimire, A., & Harerimana, B. (2023). Alert in the dynamics of water-energy-food production in African coun-tries from a nexus perspective. Resources, Conservation and Recycling, 194, 106990. https://doi.org/10.1016/j.resconrec.2023.106990
Lombardi, G. V., Atzori, R., Acciaioli, A., Giannetti, B., Parrini, S., & Liu, G. (2019). Agricultural landscape modification and land food footprint from 1970 to 2010: A case study of Sardinia, Italy. Journal of Cleaner Production, 239, 118097. https://doi.org/10.1016/j.jclepro.2019.118097
Zhen, L., Cao, S., Cheng, S., Xie, G., Wei, Y., Liu, X., & Li, F. (2010). Arable land requirements based on food consumption patterns: Case study in rural Guyuan District, Western China. Ecological Economics, 69(7), 1443-1453. https://doi.org/10.1016/j.ecolecon.2008.12.008
Bosma, R. H., & Verdegem, M. C. J. (2011). Sustainable aquaculture in ponds: Principles, practices and limits. Livestock Science, 139(1-2), 58-68. https://doi.org/10.1016/j.livsci.2011.03.017
Andryushchenko, A. І., & Alimov, S. І. (2008). Stavove rybnictvo. Kyiv: NAU. Retrieved from https://uteka.ua/ua/publication/agro-4-gospodarski-operacii-v-agrosektori-35-praktichni-rekomendacii-shhodo-zariblennya-viroshhuvalnix-staviv
Miyamoto, K. (1997). Renewable Biological Systems for Alternative Sustainable Energy Production. FAO Agri-cultural Services Bulletin (Issue 128). Rome: Food and Agriculture Organization of the United Nations. Retrieved from https://www.fao.org/3/w7241e/w7241e05.htm#1.2.1
Sonnino, A. (1994). Agricultural biomass production is an energy option for the future. Renewable Energy, 5(5-8), 857-865. https://doi.org/10.1016/0960-1481(94)90105-8
Bao, K., Thrän, D., & Schröter, B. (2023). Land resource allocation between biomass and ground-mounted PV under consideration of the food–water–energy nexus framework at regional scale. Renewable Energy, 203, 323-333. https://doi.org/10.1016/j.renene.2022.12.027
Ukrstat. (2021). Plantation. Sown areas for the harvest of 1991-2020. Official website of the State Statistics Ser-vice. Retrieved from ukrstat.gov.ua
Andreev, V., Sluchak, O., Sluchak, O., Alekseeva, A., & Krysinska, D. (2022). Development of a methodology for modeling the state of the water ecosystem based on the methods of ecological stoichiometry, taking into account the energy approach. Herald of Khmelnytskyi National University, (315), 10-23. DOI: 10.31891/2307-5732-2022-315-6-10-23.
Verkhovna Rada of Ukraine. (2011). On adoption as a basis of the draft Law of Ukraine on Food security of Ukraine: resolution of the Verkhovna Rada of Ukraine dated 14.06.2011 No. 3498-VI. Retrieved from http://zakon3.rada.gov.ua/laws/show/3498-17

