Impact of the long-time armed conflicts on the ecological safety of industrial objects


Keywords: water pollution, industrial enterprises, armed conflict, ecological consequences, flooding of mines, ecological risks, technogenic load

Abstract

The article analyzes the consequences of pollution from industrial enterprises, as well as the risks of disruption of operation and flooding of mines. The armed conflict in the East of Ukraine led to serious environmental consequences – it is the pollution of groundwater, water bodies, air pollution, decommissioning of large areas of arable land, destruction and damage to objects of the nature reserve fund, forest fires, etc. It has been shown that in areas where the armed conflict continues, there has been significant pollution of the environment with chemical toxic substances, metal fragments and heavy metals due to artillery shelling and the use of explosives. As a result, numerous funnels were formed, which mutilated the land and destroyed natural protected areas, flooded mines, built fortifications, ditches, and damaged sewage and water supply networks. Risks associated with damage to communications, businesses and other facilities that pose an increased environmental risk, increase the scale of the negative impact. The problem of flooding of mines and excessive mineralization of waters, which are the part of the production process, is very relevant for both Luhansk and Donetsk regions. Solving this problem requires significant efforts from both the Ukrainian state and international environmental organizations. The main problem is that the mines are located in both controlled and uncontrolled by the Ukrainian government. The fate of coal mines in the territory not controlled by t government of Ukraine is uncertain and requires control by international organizations that are able to conduct monitoring activities. The coal industry in the EU is at «coal-out phase», i. e. at the stage of gradual abandonment of coal mining. First of all, this is dictated by the EU’s course to reach a carbon-free economy by 2050, which means the gradual abandonment of coal generation and the transition to renewable energy sources. And also in accordance with the EU Directive No787 in 2010 On the need to close unprofitable mines.

Author Biographies

Oleksii V. Pyrikov
Foundation for the Development, NGO
Оksana V. Lunova
State ecology academy of postgraduate education and management, Kyiv, Ukraine
Viкtor M. Yermakov
State ecology academy of postgraduate education and management, Kyiv, Ukraine
Rolf Petry
Consultants of DMT GmbH & Co. KG, Ам TÜV 1, Essen, 45307, Germany
Natalya O. Lubenska
Consultants of DMT GmbH & Co. KG, Ам TÜV 1, Essen, 45307, Germany

References

1. Bondar O., Yermakov V., Ulutskyi O., 2018. Zvit pro rezul’taty vyvchennja ekologichnoi’ sytuacii’ na terytorii’ Donec’koi’ ta Lugans’koi’ oblastej [Report on the results of studying the environmental situation in the Donetsk and Luhansk regions] MinTOT, Kyiv, 1–72 (In Ukrainian).
2. Denisov N., Averin D., with contributions from Yushchuk A., Yermakov V., Ulytskyi O., Bystrov P., Zibtsev S., Chumachenko S., Nabyvanets Y., 2018. Assessment of environmental damage in eastern Ukraine and recovery priorities. This publication has been prepared under the project «Assessment of Environmental Damage in Eastern Ukraine,» implemented by the OSCE Project Co-ordinator in Ukraine with financial support from the Governments of Austria and Canada and in cooperation with Zoï Environment Network, Switzerland. 1–88.
3. Lunova O., 2018. Modeliuvannia stsenariiv rozvytku tekhnoekosystem [The modeling of scenarios for techno- ecosystem development]. Heotekhnichna mekhanika: mizhvid. zb. nauk. 143. 40–48 (In Ukrainian)
4. Lunova O., 2018. Metodolohiia vyboru tekhnolohichnykh rishen optymizatsii funktsionuvannia tekhnoekosystem [The metodology for choosing the technological solution allowing optimizing the techno-ecosystem functioning]. Heotekhnichna mekhanika: mizhvid. zb. nauk. 141. 70–78. (In Ukrainian)
5. Lunova O., 2019. Ocinka ekologichnyh ryzykiv tehnoekosystem na prykladi rajoniv vugil’nyh rodovyshh Donbasu [Estimation of ecological risks of technoecosystems on an example of areas of coal deposits of Donbass] Ekologichni nauky: naukovo- praktychnyj zhurnal 4 (27) T.1. 38–44 (In Ukrainian)
6. Lunova O., 2019. Osoblyvosti formuvannia tekhnoekosystem vuhilnykh rodovyshch ta otsinka ekolohichnykh ryzykiv [The feature of techno-ecosystems formation at mining field and the risk assessment]. Heotekhnichna mekhanika: mizhvid. zb. nauk. prats. 149. 58–67. (In Ukrainian)
7. Lunova О., Yermakov, V., Averin, D., 2019. Potential territorial risk in the eastern Ukraine. Journal of Geology, Geography and Geoecology 28 (3). 600–609.
8. Lunova O., Yermakov V., 2019. Vplyv vuglevydobuvnyh pidpryjemstv na riven’ ekologichnoi’ bezpeky tehnoekosystem Donbasu [Influence of coal mining enterprises on the level of ecological safety of technical ecosystems of Donbass] 137–142 (In Ukrainian)
9. Lunova O., Yermakov V., 2020. Zvit pro naukovo-doslidnu robotu «Zmenshennja ryzyku katastrof ta vrazlyvosti naselennja v Shidnij Ukrai’ni» [Reducing the risk of disasters and vulnerability of the population in Eastern Ukraine] 1–73 (In Ukrainian)
10. Lunova O., 2020. Naukovi osnovy upravlinnia ekolohichnoiu bezpekoiu promyslovykh kompleksiv vuhlevydobuvnykh pidpryiemstv [The scientific foundations of ecological safety management at coal-mining enterprises.]. Ekolohichni nauky: naukovo-praktychnyi zhurnal 1(28). 50–59. (In Ukrainian)
11. Lunova O., 2020. Prohnozuvannia stupenia ekolohichnoi nebezpeky za intehralnym pokaznykom ekolohichnoho vplyvu [The forecasting of the environmental safety based on the integral indicator of ecological impact]. Ekolohichni nauky: naukovo-praktychnyi zhurnal 4(29) 24–31 (In Ukrainian)
12. Nabyvanets Y., 2018. Ocinka mozhlyvogo vplyvu konfliktu na shodi Ukrai’ny na jakist’ poverhnevyh vod (za rezul’tatamy spil’nyh doslidzhen’ laboratorii’ SDBUVR ta Instytutu navkolyshn’ogo seredovyshha, Slovac’ka Respublika) [Assessment of the possible impact of the conflict in eastern Ukraine on the surface water quality (based on the results of joint research by the SDBUVR laboratory and the Institute of the Environment, Slovak Republic] Ukrai’ns’kyj gidrometeorologichnyj instytut Derzhavnoi’ sluzhby Ukrai’ny z nadzvychajnyh sytuacij i Nacional’noi’ akademii’ nauk Ukrai’ny (In Ukrainian)
13. Weberink M., Steinkohle, 2018. Jahresbericht des Gesamtverbands Steinkohle [Annual Report of the General Assembly Steinkohle], Mining Report Glückauf 154, 6.
14. Yermakov V., 2000. Reactivation of subsidence zones due to coal-mine closure in Donbass. Mining Technology 109, 191–194
15. Yermakov V., Lunova, O. Averin, D., 2019. Osnovni oznaky skladnykh tekhnoekosystem ta yikh zbalansovanist [The main features of complex techno-systems and their balance] Visti Donetskoho hirnychoho instytutu 1(44), 23–33 (In Ukrainian)
16. Yermakov V., Lunova O., Lubenska N., 2021 K voprosu restrukturyzacyy ugol’noj promyshlennosty v Ukrayne v kontekste yevropeyskogo opyta [On the issue of restructuring the coal industry in Ukraine in the context of European experience] Ekologichni nauky: naukovo- praktychnyj zhurnal 7 (34), V.1. 16–21 (In Russian)
Published
2022-08-04
How to Cite
Pyrikov, O., LunovaО., Yermakov, V., Petry, R., & Lubenska, N. (2022). Impact of the long-time armed conflicts on the ecological safety of industrial objects. Journal of Geology, Geography and Geoecology, 31(2), 380-389. https://doi.org/https://doi.org/10.15421/112235