Makarieva O.M., Nesterova N.V., Yampolsky G.P., Kudymova E.Yu., Ostashov A.A., Kolupaeva A.D., 2019. Assessment of maximum instant discharge of various frequency at ungauged mountainous river Khemchik (Tuva Republic) based on mathematical modelling. Engineering Survey, Vol. XIII, No. 2, pp. 36-51, https://doi.org/10.25296/1997-8650-2019-13-2-36-51.
1. Borsch S.V., Simonov Y.A., Khristoforov A.V., 2015. Flood forecasting and early warning system for rivers of the Black Sea shore of Caucasian region and the Kuban river basin. Proceedings of the Hydrometcenter of Russia, Special Issue No. 356, Moscow. (in Russian)
2. Vasilenko N.G., 2013. Hydrology of rivers of the BAM zone: Expeditionary research. Nestor-Istoriya, Saint Petersburg. (in Russian)
3. Vinogradov A.Yu., 2012. On the issue of responsibility of design and survey organizations at the present stage. Natural and technical sciences, No. 4(60), pp. 374–376. (in Russian)
4. Vinogradov A.Yu., 2012. Modern problems of engineering-hydrological surveys in the design of forest roads. From the law on technical regulation to SP 33-101-2003. Publishing house of the Saint-Petersburg State Forestry University, Saint-Petersburg. (in Russian)
5. Vinogradov Yu. B., 1988. Mathematical modeling of runoff formation processes (experience of critical analysis). Gidrometeoizdat, Leningrad. (in Russian)
6. Vinogradova T.A., Pryakhina G.V., Mosolova G.I., 2014. Methodological foundations of field hydrology and the organization of complex expeditionary works in mountainous watersheds. Vestnik of Saint-Petersburg University. Issue 7. Geologiya. Geografiya, No. 4, pp. 189–196. (in Russian)
7. Ganyushkin D.А., Chistyakov K.V., Moskalenko I.G., 2011. The present-day glaciation of the north-west of inner Asia and its dynamics. Vestnik of Saint-Petersburg University. Series 7. Geology. Geography, No. 2, pp. 94–110. (in Russian)
8. Grave N.A., Gavrilova M.K., Gravis G.F., Katasonov E.M., Klyukin N.K., Koreysha G.F., Kornilov B.A., Chistotinov L.V., 1964. The freezing of the earth's surface and the glaciation of the Suntar-Hayata ridge (Eastern Yakutia). Nauka, Moscow. (in Russian)
9. Gudilin I.S. (ed.), 1980. Landscape map of the USSR. Scale 1:2 500 000. Gidrospetsgeologiya, Moscow. (in Russian)
10. Zhirkevich A.N., Asarin A.E., 2010. Probable maximum flood (PMF): basic information and problems of its calculation method application in Russia. Gidrotekhnicheskoe stroitelʹstvo, No. 4, pp. 30–36. (in Russian)
11. Kamanin L.G., Likhanov B.N. (eds.), 1964. Central Siberia. Nauka, Moscow. (in Russian)
12. Kurbatskaya S.S., Kurbatskaya S.G., Mironycheva-Tokareva N.P., Kudryashova S.Y., Chumbaev A.S., 2018. Biological productivity of tundra-ecosystems of the northern macro slope of the Mongun-Taiga mountain range. Ecosystems of Central Asia: investigations, conservation, sustainble use, Proceedings of the XIV Ubsunur International Symposium, Ulangom, Mongolia, pp. 99–102. (in Russian)
13. Makarieva O.M., Beldiman I.N., Lebedeva L.S., Vinogradova T.A., Nesterova N.V., 2017. On the issue of validity of recommendations from SP 33-101-2003 for assessment of maximum flow characteristics of small rivers in the permafrost zone. Engineering Survey, No. 6–7, pp. 50–63, https://doi.org/10.25296/1997-8650-2017-6-7-50-63. (in Russian)
14. Makarieva O.M, Vinogradova T.A., Nesterova N.V., Vinogradov A.Y., Beldiman I.N., Kolupaeva A.D., 2018. Modeling of catastrophic floods in the Tuapse River basin. Georisk, Vol. XII, No. 3, pp. 78–89. (in Russian)
15. Makarieva O.M., Nesterova N.V., Vinogradova T.A., Beldiman I.N., Kolupaeva A.D., 2019. Calculation of the characteristics of catastrophic floods of the unexplored Tsemes river (Novorossiysk, the Black Sea coast of Russia) based on the Hydrograph hydrological model. Vestnik of Saint-Petersburg University. Earth Sciences, Vol. 64, Issue 1, pp. 24–43. (in Russian)
16. Makarieva O.M., Nesterova N.V., Lebedeva L.S., Vinogradova T.A., 2019. Modeling runoff formation processes in the high-mountain permafrost zone of Eastern Siberia (A case study of Suntar-Khayata Range). Geography and Natural Resources, No. 1, pp. 178–186. (in Russian)
17. Nesterova N.V., Makarieva O.M., Vinogradova T.A., Lebedeva L.S., 2018. Simulating of the Baikal-Amur Railway zone runoff formation on the basis of the “Mogot” trail ground data. Water sector of Russia: problems, technologies, management, No. 1, pp. 18–36. (in Russian)
18. Pryakhina G.V., Zelepukina E.S., Zhuravlyov S.A., Amburtseva N.I., Chistyakov K.V., 2014. Landscape-hydrological structure of the Amyl river catchment and its consideration in modeling the formation of river flow. Geography and Natural Resources, No. 4, pp. 131–137. (in Russian)
19. Pryakhina G.V., Zelepukina E.S., Zhuravlev S.A., Osipova T.N., Amburtseva N.I., Vinogradova T.A., 2017. Estimation of run-off from the small mountain drainage basins using the model of run-off formation. Vestnik Moskovskogo universiteta, Series 5. Geography, pp. 29–37. (in Russian)
20. Razumov V.V., Razumova N.V., Pchelkin V.I., 2015. Scales and danger of flooding in the Siberian region of Russia. The science. Innovation, Technology, No 4. URL: https://cyberleninka.ru/article/n/masshtaby-i-opasnost-navodneniy-v-sibirskom-regione-rossii (accessed: 5 February 2019). (in Russian)
21. Surface water resources of the USSR, 1973. Vol. 16, Angara-Yenisei region, Issue 1, Enisey, Gidrometeoizdat, Leningrad. (in Russian).
22. Certificate of state registration of computer program No. 2018619084 “Comprehensive program of the distributed hydrological model "Hydrograph"”, right holder O.M. Makarieva, the date of registration is 30.07.2018. (in Russian)
23. Fridland V.M. (ed.), 1988. Soil Map of the Russian Soviet Federal Socialist Republic. Scale: 1:2 500 000. Main Department of Geodesy and Cartography, Moscow. (in Russian)
24. Ball J., Babister M., Nathan R., Weeks W., Weinmann E., Retallick M., Testoni I., 2019. Australian Rainfall and Runoff: A Guide to Flood Estimation, Commonwealth of Australia (Geoscience Australia).
25. Beven K., 2012. Rainfall-Runoff Modelling: the Primer. Wiley-Blackwell, Chichester.
26. Brocca L., Melone F., Moramarco T., 2011. Distributed rainfall–runoff modelling for flood frequency estimation and flood forecasting. Hydrological processes, Vol. 25, No. 18, pp. 2801–2813, https://doi.org/10.1002/hyp.8042.
27. Madsen H., Lawrence D., Lang M., Martinkova M., Kjeldsen T.R., 2013. A review of applied methods in Europe for flood-frequency analysis in a changing environment. NERC/Centre for Ecology and Hydrology, p. 180. (ESSEM COST Action ES0901).
28. Maghsood F.F., Moradi H., Massah Bavani A.R., Panahi M., Berndtsson R., Hashemi H., 2019. Climate change impact on flood frequency and source area in Northern Iran under CMIP5 scenarios. Water, Vol. 11, Issue 2, p. 273, https://doi.org/10.3390/w11020273.
29. Makarieva O., Nesterova N., Lebedeva L., Sushansky S., 2018. Water balance and hydrology research in a mountainous permafrost watershed in upland streams of the Kolyma River, Russia: a database from the Kolyma Water-Balance Station, 1948–1997. Earth System Science Data, Vol. 10, No. 2, pp. 689–710, https://doi.org/10.5194/essd-10-689-2018.
30. Minderlein S., Menzel L., 2014. Evapotranspiration and energy balance dynamics of a semi-arid mountainous steppe and shrubland site in Northern Mongolia. Environmental Earth Sciences, Vol. 73, No. 2, pp. 593–609, https://doi.org/10.1007/s12665-014-3335-1.
31. Raup B.H., Racoviteanu A., Khalsa S.J.S., Helm C., Armstrong R., Arnaud Y., 2007. The GLIMS geospatial glacier database: a new tool for studying glacier change. Global and Planetary Change, Vol. 56, No. 1–2, pp. 101–110, https://doi.org/10.1016/j.gloplacha.2006.07.018.
32. Rogger M., Kohl B., Pirkl H., Komma J., Kirnbauer R., Merz R., Blöschl G., 2012. Runoff models and flood frequency statistics for design flood estimation in Austria — Do they tell a consistent story? Journal of Hydrology, Vol. 456–457, pp. 30–43, https://doi.org/10.1016/j.jhydrol.2012.05.068.
33. Viviroli D., Mittelbach H., Gurtz J., Weingartner R., 2009. Continuous simulation for flood estimation in ungauged mesoscale catchments of Switzerland — Part II: Parameter regionalisation and flood estimation results. Journal of Hydrology, Vol. 377, Issue 1–2, pp. 208–225, https://doi.org/10.1016/j.jhydrol.2009.08.022.
34. The official site of the IA Tuva-Online, 2014. “In Tuva, the total damage from the flood amounted to more than 767 million rubles”, URL: https://www.tuvaonline.ru/2014/06/16/v-tuve-obschiy -uscherb-ot-pavodka-sostavil-bolee-767-millionov-rubley.html (accessed: 5 February 2019). (in Russian)
35. Official portal of the Republic of Tyva, 2014. “In Tuva, the consequences of severe flooding and flooding that happened in the summer are eliminated”, URL: http://gov.tuva.ru/press_center/news/activity/11161/. (accessed: 5 February 2019). (in Russian)
OLGA M. MAKARIEVA*
Melnikov Permafrost Institute, Siberian Branch, Russian Academy of Sciences; Yakutsk, Russia; omakarieva@gmail.com
Address: Bld. 36, Merzlotnaya St., 677010, Yakutsk, Russia
Saint Petersburg State University; Saint Petersburg, Russia
Address: Bld. 7-9, Universitetskaya Emb., 199034, Saint Petersburg, Russia
NATALIIA V. NESTEROVA
Saint Petersburg State University; Saint Petersburg, Russia; nnesterova1994@gmail.com
State Hydrological Institute; Saint Petersburg, Russia
Address: Bld. 23, 2nd Line V.О., 199053, Saint Petersburg, Russia
GRIGORY P. YAMPOLSKY
EcoStandart Technical Solutions LLC; Moscow, Russia; ygp@ecostandard.ru
Address: Bld. 13, Pde 16, Perevedenovskiy Ln., 105082, Moscow, Russia
ELENA Yu. KUDYMOVA
Ministry of Natural Resources and Ecology of the Tuva Republic; Kyzyl, Russia; elenavolodya@yandex.ru
Address: Bld. 1b, Kalinina St., 667011, Kyzyl, Russia
Golevskaya Mining Company LLC; village Toora-Khem, Todzhinsky District, Tuva Republic, Russia
Address: Bld. 14, Ulug-Khemskaya St., 667003, Kyzyl, Russia
ANDREY A. OSTASHOV
Saint Petersburg State University; Saint Petersburg, Russia; andrey.ostashov@gmail.com
ALEXANDRA D. KOLUPAEVA
Saint Petersburg State University; Saint Petersburg, Russia; alya.kolupaeva.97@mail.ru