Article
Article name	Use of mathematical modeling for estimation of environmental consequences of the regional economy reindustrialization
Authors	Pyanova E.. candidate of physical and mathematical sciences , research scientist, pianova@ngs. ru Faleychik A.. candidate of physical and mathematical sciences, associate professor, faa55@bk.ru Faleychik L.. candidate of technical sciences major research scientist; associate professor, lfaleych ik@bk.ru
Bibliographic description	Pyanova Е., Faleychik А., Faleychik L. Use of mathematical modeling for estimation of environmental consequences of the regional economy reindustrialization // Transbaikal State University Journal, 2017, vol. 23, no. 12, pp. 41-50. DOI: 10.21209/2227-9245-2017-23-12-41-50.
Category	Earth science
DOI	502.3:504.61
DOI	10.21209/2227-9245-2017-23-12-41-50
Article type	Original article
Annotation	The atmospheric circulation generation and the pollutants transport processes in the Chitino-Ingodinsky basin under complex orography conditions are studied. The orographic and climate features of the hydrometeorological regime formation of the atmosphere are important factors to creation of the pollution high levels in the Chita city air basin. The authors have created scenarios of possible development of local atmospheric circulations during the winter and summer periods. The simulation on the winter scenarios was supposed that the background wind was absent. Summer scenarios simulate the atmospheric transport of smoke from a forest fire in the Chita neighborhood. The results of scenario calculations which have been performed on the basis of a numerical model of atmospheric dynamics and impurity transport are presented. It was noted that the research in this field have a special significance in the context of ongoing processes of reindustrialization of the region’s economy, in particular, when businesses switch to new technologies and new fuel
Key words	economic development of region; anthropogenic impact assessment; air pollution; math modeling; geographical information systems; geoinformation technologies; reindustrialization
Article information
References	1. Aloyan A. E., Faleychik A. A., Faleychik L. M. Matematicheskie modeli ratsionalnogo prirodopolzovaniya (Mathematical models of rational environmental use). Novosibirsk: Nauka, 1989, pp. 14—35. 2. Bart A. A., StarchenkoA. V., FazlievA. Z. Optika atmosfery i okeana (Atmospheric and oceanic op tics), 2012, no. 25 (7), pp. 594-601. 3. BitekhtinaM. A., MikhailutaS. V., LezheninA. A., TaseikoO. V. VestnikKemerovskogogosudarstvennogo universiteta (Bulletin of the Kemerovo State University), 2012, no. 4(2), pp. 143—148. 4. Klimaticheskie kharakteristiki usloviy rasprostraneniya primesey v atmosfere (Climatic characteristics of the conditions for the propagation of impurities in the atmosphere) / ed. E. Yu.Bezuglaya, M. E. Berlyand). Leningrad, Gidrometeoizdat, 1983, 328 p. 5. Marchuk G. I. Matematicheskoe modelirovanie v probleme okruzhayuschey sredy (Mathematical Modeling in the Problem of Environment). Moscow: Nauka, 1982. 320 p. 6. Mikhailuta S. V., LezheninA. A., Taseiko O. V., Bitekhtina M. A. Inzhenemaya ekologiya (Engineering ecology), 2012, no 3, pp. 26—37. 7. Penenko V. V. Interekspo Geo-Sibir (Interexpo Geo-Siberia), 2017, no. 4(1), pp. 70—73. 8. Penenko V. V., Aloyan A. E. Modeli i metody dlya zadach ohrany okruzhayuschey sredy (Models and methods for environment protection problems). Novosibirsk: Nauka, 1985. 256 p. 9. Penenko V. V., Tsvetova E. A. Optika atmosfery i okeana (Atmospheric and oceanic optics), 2017, no. 30 (6), pp. 509-514. 10. Pyanova E. A. Vychislitelnye tehnologii. (Computational Technologies), 2005, vol. 10. no. 3, pp. 106—111. 11. Pyanova E. A., Faleychik L. M. Vychislitelnye tehnologii (Computational Technologies). 2012, no. 17 (1), pp. 109-119. ’ ’ 12. Faleychik L.M. Vestnik Novosibirskogo gosudarstvennogo universiteta. Ser. Informacionnye tehnologii (Novosibirsk State University Journal. Ser. Information Technologies), 2012, no. 10 (2), pp. 14—24. 13. Yaclimeneva N. V., Golvey A. Yu. Vestnik Chelyabinskogo gosudarstvennogo universiteta (Bulletin of the Chelyabinsk State University), 2011, no. 5 (220), pp. 84—89. 14. Integrated Systems of Meso-Meteorological and Chemical Transport Models (Integrated Systems of Meso-Meteorological and Chemical Transport Models) / ed. A. Baklanov, A. Makhura, R. Soklii. Springer-Verlag Berlin Heidelberg, 2011. 15. Jarvis A., Reuter H. I., Nelson A., Guevara E. Hole filled SRTM for the globe (Hole-filled SRTM for the globe). Version 4. 2008. Available at: http://www.n^i^srtm.csi.cgiar.org (Date of access: 12.09.2017). 16. Mikhailuta S. V., LezheninA. A., PittdA., TaseikoO. V. Urban Climate (Urban Climate), 2017, vol. 19, pp. 122-140. 17. Penenko V., Tsvetova E. J. of Computation and Applied Mathematics (J. of Computation and Applied Mathematics), 2009, vol. 226, issue 2, pp. 319—330. 18. Pyanova E. A., Penenko V. V., Faleychik L. M. Proc. SPIE 10035, 22nd International Symposium on Atmospheric and Ocean Optics: Atmospheric Physics (Proc. SPIE 10035, 22nd International Symposium on Atmospheric and Ocean Optics: Atmospheric Physics). 100356D (November 29, 2016). 19. Pyanova E. A., Penenko V. V., Faleychik L. M. Proc. SPIE 10466, 23rd International Symposium on Atmospheric and Ocean Optics: Atmospheric Physics (Proc. SPIE 10466, 23rd International Symposium on Atmospheric and Ocean Optics: Atmospheric Physics). 104666J (November 30, 2017).
Full article	Use of mathematical modeling for estimation of environmental consequences of the regional economy reindustrialization