Hostname: page-component-586b7cd67f-gb8f7 Total loading time: 0 Render date: 2024-11-28T01:26:52.744Z Has data issue: false hasContentIssue false

Hydrological dispersion module of JRODOS: development and pilotimplementation – the vistula river basin

Published online by Cambridge University Press:  16 September 2010

M. Zheleznyak
Affiliation:
Ukrainian Center of Environmental and Water Projects, Prospect Glushkova, 42, 03187 Kiev, Ukraine
S. Potempski
Affiliation:
Institute of Atomic Energy POLATOM, Centre of Excellence MANHAZ, 05-400 Otwock-Swierk, Poland
R. Bezhenar
Affiliation:
Ukrainian Center of Environmental and Water Projects, Prospect Glushkova, 42, 03187 Kiev, Ukraine
A. Boyko
Affiliation:
Ukrainian Center of Environmental and Water Projects, Prospect Glushkova, 42, 03187 Kiev, Ukraine
I. Ievdin
Affiliation:
Ukrainian Center of Environmental and Water Projects, Prospect Glushkova, 42, 03187 Kiev, Ukraine
A. Kadlubowski
Affiliation:
Institute of Meteorology and Water Management, Podleśna 61, 01-673 Warsaw, Poland
D. Trybushnyi
Affiliation:
Ukrainian Center of Environmental and Water Projects, Prospect Glushkova, 42, 03187 Kiev, Ukraine Karlsruhe Institute of Technology, Kaiserstraße 12, 76131 Karlsruhe, Germany
Get access

Abstract

Contemporary open source JAVA technologies implemented within the EURANOS project for thecross-platform re-engineering of the decision support system RODOS (JRODOS) were used alsoto redesign the Hydrological Dispersion Module (HDM) of this system. JHDM – thehydrological model chain of JRODOS contains models to simulate the radionuclide transportin the system “atmospheric fallout on watershed – river net” and calculate the doses viaaquatic pathways. JHDM used for this purpose a limited number of the input parameters tocharacterize the hydrological properties of the catchment/river network of interest. Thepilot implementation of JHDM for the Vistula river basin carried out by POLATOM andsupported by the national hydrological institute, demonstrated good perspectives of theapproach used in JHDM for the decision support in cases of accidental contamination ofwater systems. Particular needs for further improvements of the JHDM software system havebeen identified.

Type
Article
Copyright
© EDP Sciences, 2010

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Gering F., Hübner S., Müller H. (2003) User Guide for the Aquatic Food Chain and Dose Module FDMA in RODOS PV4.0, RODOS(WG3)-TN(99) 10, FZK Karlsruhe, 49 p.
Ievdin, I., Trybushnyi, D., Zheleznyak, M., Raskob, W. (2010) RODOS re-engineering: aims and implementation details, Radioprotection 45, S181-S189.CrossRefGoogle Scholar
Johannessen O.M., Volkov V.A., Pettersson L.M., Maderich V.S., Zheleznyak M.J., Gao Y., Bobylev L.P., Stepanov A., Neelov V., Tishkov V.P., Nielsen S.P. (2009) Radioactivity and pollution in the Nordic Seas and Arctic Region: observations, modelling and simulations. Springer, Series: Springer Praxis Books, ISBN: 978-3-540-24232-1.
Kolomeev M., Madsen H. (2002) Description of RETRACE: A new catchment model of the hydrological dispersion module in the RODOS system RODOS(RA5)-TN(01)-09, Report of FP5 DAONEM Project FIKR-CT-2000-00025, FZK Karlsuhe. – 32 p.
Lepicard, S., Heling, R., Maderich, V. (2004) POSEIDON/RODOS model for radiological assessment of marine environment after accidental releases: application to coastal areas of the Baltic, Black and North seas, J. Environ. Radioact. 72, 153-161.CrossRefGoogle ScholarPubMed
Margvelashvily, N., Maderich, V., Zheleznyak, M. (1997) THREETOX – a computer code to simulate three-dimensional dispersion of radionuclides in stratified water bodies, Radiat. Prot. Dosim. 73, 177-180.CrossRefGoogle Scholar
Monte, L. (1996) Analysis of models assessing the radionuclide migration from catchments to water bodies, Health Phys. 70, 227-237.CrossRefGoogle ScholarPubMed
Monte, L., Periañez, R., Kivva, S., Laptev, G., Angeli, G., Barros, H., Zheleznyak, M. (2006) Assessment of state-of-the-art models for predicting the remobilisation of radionuclides following the flooding of heavily contaminated areas: the case of Pripyat River floodplain, J. Environ. Radioactiv. 88, 267-288.CrossRefGoogle ScholarPubMed
Onishi Y., Voitsekhovich O., Zheleznyak M. (Eds.) (2006) Chernobyl – What Have We Learned? : The Successes and Failures to Mitigate Water Contamination Over 20 Years, Springer, ISBN: 978-1-4020-5348-1.
Raskob, W., Heling, R., Zheleznyak, M. (2004) Is there a need for hydrological modelling in Decision Support Systems for nuclear emergencies? Radiat. Prot. Dosim. 109, 111-114.CrossRefGoogle Scholar
Zheleznyak, M., Heling, R., Raskob, W. (2002) Hydrological dispersion module of the decision support system RODOS, Radioprotection 37 (C1), 683-688. CrossRefGoogle Scholar
Zheleznyak, M., Demchenko, R., Khursin, S., Kuzmenko, Yu., Tkalich, P., Vitjuk, N. (1992) Mathematical modeling of radionuclide dispersion in the Pripyat-Dnieper aquatic system after the Chernobyl accident, Sci. Tot. Environ. 112, 89-114.CrossRefGoogle ScholarPubMed
Zheleznyak, M.J., Tkalich, P.V., Lyashenko, G.B., Marinets, A.V. (1993) Aquatic dispersion model -first approaches to integration into the E decision support system based on post-Chernobyl experience, Radiat. Prot. Dosim. 50, 235-242.CrossRefGoogle Scholar