Article information

2019 , Volume 24, ¹ 6, p.79-89

Malkovsky S.I., Sorokin A.A., Girina O.A.

Development of an information system for numerical modelling of the propagation of volcanic ash from Kamchatka and Kuril volcanoes

Purpose. Ash clouds and plumes forming during explosive eruptions of the volcanoes of Kamchatka and the Kuril Islands pose a great danger to aviation flights. In this regard, the urgent and important task is to predict and analyze their movement. To solve this task, a modelling subsystem based on the PUFF model was created as part of the automated information system (AIS) “Signal”. It allows to predict the direction, speed and height of the propagation of ash clouds and plumes in the atmosphere. At the same time, for more accurate assessment of the danger of ash clouds and plumes, it is necessary to determine not only their qualitative, but also quantitative characteristics, for example, the concentration of ash at the flight levels of aircrafts, the amount of ash deposited on the surface, etc. To solve this problem, research was done to expand the capabilities of the AIS “Signal” by integrating the Eulerian FALL3D model into it. The present article presents the results of this work.

Methodology. Implementation of system and user interfaces for automating the processes of collecting and preparing auxiliary data (reference information about volcanoes, meteorological data, etc.), performing numerical calculations in the FALL3D model and visualizing the results obtained, was carried out on the basis of similar interfaces created earlier in AIS “Signal” for the PUFF model. This significantly accelerate the process of integration the FALL3D model into the existing AIS modelling subsystem. Implementation of the operating modes of the subsystem and evaluating the efficiency of its functioning were carried out as part of the study of ash clouds and plumes propagation that formed during explosive events on the volcanoes of Kamchatka.

Findings. As part of the integration of the FALL3D model into the modelling subsystem, informational interaction of its software components with the services of AIS “Signal” was organized. Algorithms for the formation of collections of meteorological data necessary for the functioning of the model were proposed and implemented. User interfaces have been created that allow specialists to calculate the characteristics of ash clouds with the ability to set detailed initial parameters for an explosive event and model settings.

Originality. The integration of the FALL3D model into the AIS “Signal” significantly expands its ability to predict propagation of ash clouds and plumes formed during explosive eruptions of the volcanoes of Kamchatka and the Kuril Islands. In addition to the instruments for determining the direction, speed, and height of the spread of volcanic ash, tools have been developed to determine the ash concentration at the flight levels of aircrafts, as well as the thickness and mass of the ashfall. Numerical experiments have showed a good agreement between the obtained modelling results and the satellite data.

[full text] [link to elibrary.ru]

Keywords: volcano, numerical modeling, satellite monitoring, information system, AIS Signal, PUFF, FALL3D

doi: 10.25743/ICT.2019.24.6.010.

Author(s):
Malkovsky Sergey Ivanovich
Position: Research Scientist
Office: Institution of Science Computing Center of the Far Eastern Branch of the Russian Academy of Sciences
Address: 680000, Russia, Khabarovsk, 65, Kim U Chen st.
Phone Office: (4212) 703913
E-mail: sergey.malkovsky@ccfebras.ru
SPIN-code: 3653-9904

Sorokin Aleksei Anatolyevich
PhD.
Position: Leading research officer
Office: CC FEB RAS
Address: 680000, Russia, Khabarovsk, 65, Kim Yu Chen str.
Phone Office: (4212) 703913
E-mail: alsor@febras.net
SPIN-code: 1767-2259

Girina Olga Alekseevna
PhD.
Position: Leading research officer
Office: IVS FEB RAS
Address: 683006, Russia, Petropavlovsk-Kamchatskii, 9, Piip blv.
Phone Office: (4152) 202 044
E-mail: girina@kscnet.ru
SPIN-code: 2173-5438

References:

[1] Rose, W.I., Durant, A.J. Fine ash content of explosive eruptions. Journal of Volcanology and Geothermal Research. 2009; (186(1–2):32–39. DOI: 10.1016/j.jvolgeores.2009.01.010

[2] Gordeev, E.I., Girina, O.A. Volcanoes and their hazard to aviation. Herald of the Russian Academy of Sciences. 2014; 84(1):1–8. DOI: 10.1134/S1019331614010079.

[3] Sorokin, A.Ą., Korolev, S.P., Malkovsky, S.I. The Signal Automated Information System: Research and Operational Monitoring of Dangerous Natural Phenomena in the Russian Far East. CURRENT PROBLEMS IN REMOTE SENSING OF THE EARTH FROM SPACE. 2019; 16(3):238-248. DOI: 10.21046/2070-7401-2019-16-3-238-248.

[4] Sorokin, A.Ą., Korolev, S.P., Girina, O.A., Balashov, I.V., Efremov, V.Yu., Romanova, I.M., Malkovsky, S.I. The Integrated Software Platform for a Comprehensive Analysis of Ash Plume Propagation from Explosive Eruptions of Kamchatka Volcanoes. CURRENT PROBLEMS IN REMOTE SENSING OF THE EARTH FROM SPACE. 2016; 13(4):9-19. DOI: 10.21046/2070-7401-2016-13-12-9-19.

[5] Malkovsky, S.I., Sorokin, A.A., Korolev, S.P. Improving the system of numerical simulation of volcanic ash propagation using the PUFF model. Russian Journal of Earth Sciences. 2017; 17(5):ES5003. DOI :10.2205/2017ES000612

[6] Searcy, C., Dean, K., Stringer, W. PUFF: a high-resolution volcanic ash tracking model. Journal of Volcanology and Geothermal Research. 1998; 80(1–2):1–16

[7] Romanova, I.M., Girina, O.A., Maksimov, A.P., Melekestsev, I.V. Development of Integrated Information Web System "Volcanoes of the Kurile-Kamchatka Island Arc" (VOKKIA). Informatika i Sistemy Upravleniya. 2012; 3(33):179–187.

[8] Gordeev, E.I., Girina, O.A., Loupian, E.A., Sorokin, A.A., Kramareva, L.S., Efremov, V.Yu., Kashnitskii, A.V., Uvarov, I.A., Burtsev, M.A., Romanova, I.M., Mel’nikov, D.V., Manevich, A.G., Korolev, S.P., Verkhoturov, A.L. The VolSatView information system for Monitoring the Volcanic Activity in Kamchatka and on the Kuril Islands. Journal of Volcanology and Seismology. 2016; 10(6):382–394. DOI: 10.1134/S074204631606004X.

[9] Sorokin, A.A., Girina, O.A., Lupyan, E.A., Mal’kovskii, S.I., Balashov, I.V., Efremov, V.Yu., Kramareva, L.S., Korolev, S.P., Romanova, I.M., Simonenko, E.V. Satellite observations and numerical simulation results for the comprehensive analysis of ash cloud transport during the explosive eruptions of Kamchatka volcanoes. Russian Meteorology and Hydrology. 2017; 42(12):759–765. DOI: 10.3103/S1068373917120032.

[10] Costa, A., Macedonio, G., Folch, A. A three-dimensional Eulerian model for transport and deposition of volcanic ashes. Earth and Planetary Science Letters. 2006; 241(3–4):634–647. DOI: 10.1016/j.epsl.2005.11.019.

[11] Scollo, S., Prestifilippo, M., Spata, G., D’Agostino, M., Coltelli, M. Monitoring and forecasting Etna volcanic plumes. Natural Hazards and Earth System Science. 2009; 9(5):1573–1585. DOI: 10.5194/nhess-9-1573-2009.

[12] Poret, M., Costa, A., Folch, A., Martı, A. Modelling tephra dispersal and ash aggregation: The 26th April 1979 eruption, La Soufriere St. Vincent. Journal of Volcanology and Geothermal Research. 2017; (347):207–220. DOI: 10.1016/j.jvolgeores.2017.09.012.

[13] Folch, A., Costa, A., Basart, S. Validation of the FALL3D ash dispersion model using observations of the 2010 Eyjafjallajokull volcanic ash clouds // Atmospheric Environment. 2012. Vol. 48. P. 165–183. DOI: 10.1016/j.atmosenv.2011.06.072

[14] Folch A., Costa A., Macedonio G. FALL3D 7.3.1 User's Manual. Available at: http://datasim.ov.ingv.it/download/fall3d/manual-fall3d-7.3.1.pdf (accessed 22.11.2019).

[15] Costa, A., Pioli, L., Bonadonna, C. Assessing tephra total grain-size distribution: Insights from field data analysis. Earth and Planetary Science Letters. 2016; (443):90–107. DOI: 10.1016/j.epsl.2016.02.040

[16] Mastin, L.G., Guffanti, M., Servranckx, R., Webley, P., Barsotti, S., Dean, K., Durant, A., Ewert, J.W., Neri, A., Rose, W.I., Schneider, D., Siebert, L., Stunder, B., Swanson, G., Tupper, A., Volentik, A., Waythomas, C.F. A multidisciplinary effort to assign realistic source parameters to models of volcanic ash-cloud transport and dispersion during eruptions. Journal of Volcanology and Geothermal Research. 2009; 186(1–2):10– 21. DOI: 10.1016/j.jvolgeores.2009.01.008.

[17] Stohl, A., Prata, A.J., Eckhardt, S., Clarisse, L., Durant, A., Henne, S., Kristiansen, N.I., Minikin, A., Schumann, U., Seibert, P., Stebel, K., Thomas, H.E., Thorsteinsson, T., Tørseth, K., Weinzierl, B. Determination of time- and height-resolved volcanic ash emissions and their use for quantitative ash dispersion modeling: the 2010 Eyjafjallajokull eruption. Atmospheric Chemistry and Physics. 2011; 11(9):4333–4351. DOI: 10.5194/acp-11-4333-2011

[18] Sorokin, A.A., Makogonov, S.I., Korolev, S.P. The Information Infrastructure for Collective Scientific Work in the Far East of Russia. Scientific and Technical Information Processing. 2017; (4):302–304.


Bibliography link:
Malkovsky S.I., Sorokin A.A., Girina O.A. Development of an information system for numerical modelling of the propagation of volcanic ash from Kamchatka and Kuril volcanoes // Computational technologies. 2019. V. 24. ¹ 6. P. 79-89
Home| Scope| Editorial Board| Content| Search| Subscription| Rules| Contacts
ISSN 1560-7534
© 2024 FRC ICT