Recycling and decontamination of organic waste in Ukraine: Current state, technologies and prospects for the biogas industry
Keywords:
biogas; organic waste processing; animal husbandry; pathogen inactivation.
Abstract
Global and regional competition for natural resources, particularly for land and water, food and fodder, takes place in the context of a dire necessity to limit greenhouse gas emissions and is becoming more and more pressing every year. Environmental soundness, sustainability and security are becoming more relevant and are considered as key elements of modern agricultural enterprises' operation. The concept of the coming years in animal husbandry is non-waste production, which consists in the complete recycling of waste, and if it is impossible – in their safe disposal. If the waste cannot be reused or upcycled, such waste should be transformed into energy. The production of biogas and biomethane contributes to solving two global problems: the growing amount of organic waste produced by modern economies and the negative impact of CO2 emissions on climate change and the environment. We considered the social and economic prerequisites developed in the main sectors of contemporary Ukrainian livestock breeding in terms of potential sources of raw materials for biogas production. The main focus of the study is on the elements of greening of national agriculture, production and on the prospects for the development of the biogas industry in Ukraine. Favourable conditions for the development of biogas technologies have been identified among large producers of livestock products (dairy cattle breeding, swine breeding and poultry farming). In other sectors, opportunities are still limited due to economic, social and legislative difficulties. The paper also analyses the prospects for the use of various means of combating pathogens for the processing and disposal of organic waste. The main role of anaerobic digestion as an alternative method for the inactivation of dangerous pathogens responsible for infectious and parasitic diseases of animals and humans has been determined.References
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Fedorovych, J., Salyga, J., Fedorovych, V., Mazur, N., & Bodnar, P. (2022). Development of goat breeding in Ukraine. Visnyk Agrarnoyi Nauky, 100(2), 42–49.
Ganguly, R. K., & Chakraborty, S. K. (2020). Eco-management of industrial organic wastes through the modified innovative vermicomposting process: A sustainable approach in tropical countries. In: Bhat, S., Vig, A., Li, F., & Ravindran, B. (Eds.). Earthworm assisted remediation of effluents and wastes. Springer, Singapore. Pp. 161–177.
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Hapich, H., & Onopriienko, D. (2024). Ecology and economics of irrigation in the south of Ukraine following destruction of the Kakhov Reservoir. International Journal of Environmental Studies, 81(1), 301–314.
Hapich, H., Novitskyi, R., Onopriienko, D., Dent, D., & Roubik, H. (2024). Water security consequences of the Russia – Ukraine war and the post-war outlook. Water Security, 21, 100167.
Ishchenko, S., Pysarenko, N., & Klius, Y. (2021). Assessment and ways of overcoming crisis phenomena in the field of animal husbandry in Ukraine. Efektyvna Ekonomika, 2, 1–3.
Izhboldina, O., & Makarenko, D. (2019). Overview of organic fertilizer processing methods. The Scientific and Technical Bulletin of the Institute of Animal Science NAAS of Ukraine, 122, 92–102.
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Kobets, A. S., Puhach, A. M., Izhboldina, O. O. (2019). Compost mixer-aerator. Utility model patent № 135653 МПК А 01 С 3/00 10.07.2019 Bul. №13.
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Kryvokhyzha, Y. M., Pinchuk, V. O., & Tertychna, O. V. (2022). Assessment of phytotoxicity of disinfectants used for manure disinfection. Agroecological Journal, 2, 92–97.
Kumla, J., Suwannarach, N., Sujarit, K., Penkhrue, W., Kakumyan, P., Jatuwong, K., Vadthanarat, S., & Lumyong, S. (2020). Cultivation of mushrooms and their lignocellulolytic enzyme production through the utilization of agro-industrial waste. Molecules, 25(12), 2811.
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