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With the development of information technology, electromagnetic radiation becomes a tangible view of the physical (wave) environmental pollution. Modern scientific research aimed at the components of the elec tromagnetic environment pollution problems mainly involves the anthropocentric approach. There is no procedure for determining the influence of harmful physical factors on biota, in particular in terms of water (Daphnia magna Straus) and air (Drosophila melanogaster L.) environments. A clear system of rationing of maximum permissible levels of electromagnetic radiation, including volume and ecosystems protected areas has not been developed. The article considers the relevant scientific and practical problem of creating a framework for assessing and predicting the negative impact of electromagnetic radiation on the biota related to ethological changes and teratogenesis. The characteristic of all the constituent elements of the system determines the degree of the negative impact of the induction of the magnetic field on the biota: activity, mortality; reproduction; availability, and frequency of Teratology. A method for determining the activity levels of Daphnia and Drosophila total average activity biota was developed and described. The trajectory patterns of Daphnia motion at low activity in the state of stability, with increased activity in the excited state, were created. The results of the research on the negative impact of electromagnetic radiation of industrial frequency on biota were presented. The critical levels of the magnetic field and noise pollution, which cause the depletion and destruction of the test object, the relationship between ethological changes and the occurrence of mutations depending on radiation levels were determined. The biological test objects were proven to minimize the error of the results of determination of electromagnetic effects on the biota, in comparison with the mathematical methods of research.
Czasopismo
Rocznik
Tom
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42--49
Opis fizyczny
Bibliogr. 16 poz., rys., tab.
Twórcy
autor
- Lublin University of Technology, ul. Nadbystrzycka 38a, 20-618, Lublin, Poland
autor
- Institute Information and Computational Technologies CS MES RK, Pushkin St, 125, Almaty 050000, Kazakhstan
autor
- Kremenchuk Mykhailo Ostrohradskyi National University, Pershotravneva St. 20, Kremenchuk, 36900, Ukraine
autor
- Kremenchuk Mykhailo Ostrohradskyi National University, Pershotravneva St. 20, Kremenchuk, 36900, Ukraine
autor
- National University of Life and Environmental Sciences of Ukraine, Heroiv Oborony St. 15, Kyiv, 03041, Ukraine
autor
- Vinnytsia Cooperative Institute, Akademika Jangelia St, 59, Vinnytsia, 21000, Ukraine
autor
- Kyiv National University of Construction and Architecture, Pam’yatnyk Mykoli Ostrovs’komu, Povitroflots’kyi Ave, Kyiv, 03037, Ukraine
autor
- Vinnytsia Mykhailo Kotsiubynskyi State Pedagogical University, Ostroz’koho St, 32, Vinnytsia, Ukraine, 21000
autor
- M.Kh.Dulaty Taraz Regional University, Tole Bi St 40, Taraz, Kazakhstan
autor
- M.Kh.Dulaty Taraz Regional University, Tole Bi St 40, Taraz, Kazakhstan
autor
- Abai Kazakh National Pedagogical University, CS MES RK, Pushkin St 125, Almaty, 050000, Kazakhstan
autor
- M.Kh.Dulaty Taraz Regional University, Tole Bi St 40, Taraz, Kazakhstan
Bibliografia
- 1. Burlaka N.I., Gozhenko S.S. 2010. Electromagnetic fields, its types, characteristics, classification, and the impact on public health. Aktual’nye problemy transportnoj mediciny, 4(2(22)), 24–32. (in Russian)
- 2. Chernyy A.P., Nykyforov V.V., Rodkin D.I., Nozhenko V.Yu. 2013. Modern situation of the investigation of electromagnetic radiations on human’s organism. Inzhenernye i obrazovatel’nye tekhnologii v elektrotekhnicheskikh i kompyuternykh sistemakh: ezhekvartalnyy nauchno-prakticheskiy zhurnal. Kremenchug: KrNU; 2/2013(2). Available at: http://eetecs.kdu.edu.ua/ (in Russian)
- 3. Kukharenko D., Novokhatko O., Maznytska O., Sakun O., Chernaia E. 2020. The Influence of an Electromagnetic Field on the Additional Increment of Biogas in a Power Plant. Materials of the international conferences on Modern Electrical and energy systems. Kremenchuk, 380–383.
- 4. Maletkin V.N., Nekrutenko V.V., Goljaev I.E. 2011. Biophysics effects of electromagnetic fields on Earth in terms of human health and safety. Vіsnik Shіdnoukraїns’kogo nacіonal’nogo unіversitetu іm. V. Dalja, 11/2(165), 165–169. (in Russian)
- 5. Nykyforov V., Sakun O., Yelizarov M., Chorna O. 2020. Measurement of Magnetic Induction of an Induction Motor Magnetic Field on the Basis of Biological Express Systems. Materials of the international conferences on Modern Electrical and energy systems. Kremenchuk, 380–383.
- 6. Oleshko T.I. 2011. A systematic approach to the environmental assessment of risks from electromagnetic radiation cellular elements. Sovremennye informacionno-kommunikacijni tehnologii COMINFO”2011, mater. VII mezhdunar. nauk. tehn. konferencii, 10–14 oktjabrja 2011 goda, sb. tezisov. Kiev: GUIKT, 207–208. (in Ukranian)
- 7. Orlyuk T.M. 2014. Influence of a constant magnetic field and magnetized water tap on morphological blood parameters of broiler chickens. Nauchnye doklady Natsionalnogo universiteta bioresursov i prirodopolzovaniya Ukrainy, 4. Available at: http://nbuv.gov.ua/j-pdf/Nd_2014_4_6.pdf (in Ukranian)
- 8. Pasenko A.V., Maznytska O.V., Rotai T.M., Nykyforova L.E., Kotyra A., Yeraliyeva B., Borankulova G. 2021. Biomass of Excess Activated Sludge from Aeration Tanks as Renewable Raw Materials in Environmental Biotechnology. Biomass as Raw Material for the Production of Biofuels and Chemicals. Routledge, Taylor & Francis Group, London, 105–118.
- 9. Podobed I.M. 2012. On the opposite properties of the same radiation and its impact on workers.Problemy ohrany truda v Ukraine: sb. nauk. rabot. Kiev, 23, 90–95. (in Ukranian)
- 10. Sakun O.A. 2014. Determining the degree of adverse effects of noise and magnetic field to the test object. Vestnik Kremenchugskogo natsionalnogo universiteta imeni Mikhaila Ostrogradskogo 3, 149–154. (in Ukranian)
- 11. Svjatenko А.І., Novokhatko O.V., Pasenko A.V., Maznytska O.V., Nykyforova L.E., Rotai T.М., Gromaszek K., Bizhanova A., Kalabayeva A. 2021. The Use of Activated Sludge Biomass for Cleaning of Wastewater from Dairy Enterprises. Biomass as Raw Material for the Production of Biofuels and Chemicals. Routledge, Taylor & Francis Group, London, 119–134.
- 12. Tomashevskaya L.A., Kravchun T.E., Zaritskaya M.V., Lemeshko L.P., Medvedev S.V. 2013. Influence of magnetic fields of industrial frequency on the morphological composition of the blood of rats. Gigiena naselennykh mest, 61, 405–411. Available at: http://nbuv.gov.ua/j-pdf/gnm_2013_61_69.pdf (in Ukranian)
- 13. Ushakova O.А., Savina N.B., Kovshun N.E., Nykyforova L.E., Lyakhovchenko N.V., Wójcik W., Yerkeldessova G., Oralbekova A. 2021. Ecological and Economic Principles of Rational Use of Biomass. Biomass as Raw Material for the Production of Biofuels and Chemicals. Routledge, Taylor & Francis Group, London, 135–144.
- 14. Yaremchuk M. 2014. Influence of electromagnetic radiation of radio frequency range on biological objects. Visnyk of Lviv National University – Biological series, 65, 34–49.
- 15. Zagirnyak M., Chornyi O., Nykyforov V., Sakun O., Panchenko K.. 2016. Experimental research of electromechanical and biological systems compatibility. Przegląd elektrotechniczny, 92(1), 128–131.
- 16. Zalyubovskaya N.P. 1970. By assessing the action of microwaves millimeter and submillimeter ranges for various biological objects. avtoref. dis. na soiskanie nauch. step. kand. biol. nauk: spets. 03.091. Kharkov. (in Russian)
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-967e668d-a711-4c61-a368-2616b92846e7
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