ukrainian version
 
MAIN PUBLICATIONS:

1.  R. Periáñez, R. Bezhenar, I. Brovchenko, C. Duffa, M. Iosjpe, K.T. Jung, K.O. Kim, T. Kobayashi, L. Liptak, A. Little, V. Maderich, P. McGinnity, B.I. Min, H. Nies, I. Osvath, K.S. Suh, G. de With, Marine radionuclide transport modelling: Recent developments, problems and challenges // Environmental Modelling & Software, 122, 2019 https://doi.org/10.1016/j.envsoft.2019.104523

2. R Periáñez, R Bezhenar, I Brovchenko, KT Jung, Y Kamidara, KO Kim, T Kobayashi, L Liptak, V Maderich, BI Min, KS Suh Fukushima 137Cs releases dispersion modelling over the Pacific Ocean. Comparisons of models with water, sediment and biota data // 2019, Journal of environmental radioactivity, 198, p. 50-63.

3. R. Periáñez, I. Brovchenko, K.T. Jung, K.O. Kim, V. Maderich, The marine kd and water/sediment interaction problem // Journal of Environmental Radioactivity, 2018, https://doi.org/10.1016/j.jenvrad.2018.02.014

4.  Maderich V., Jung K.T., Brovchenko I., Kim K.O. Migration of radioactivity in multi-fraction sediments. // Environmental Fluid Mechanics, 2017, Vol. 17(6), 1207-1231.

5. R. Periáñez, R. Bezhenar, I. Brovchenko, C. Duffa, M. Iosjpe,  K.T. Jung, T. Kobayashi, F. Lamego, V. Maderich, B.I. Min, H. Nies, I. Osvath, I. Outola, M. Psaltaki, K.S. Suh, G. de With, Modelling of marine radionuclide dispersion in IAEA MODARIA program: Lessons learnt from the Baltic Sea and Fukushima scenarios // Science of The Total Environment, Volumes  569-570 (2016) 594-602.

6. Kateryna Terletska, Kyung Tae Jung, Tatiana Talipova, Vladimir Maderich,  Igor Brovchenko  and  Roger Grimshaw Internal breather-like wave generation by the second mode solitary wave interaction with a step Physics of fluids,2016, 28(11)  pp. 10.1063/1.4967203.

7. Raúl Perianez, Igor Brovchenko, Celine Duffa, Kyung-Tae Jung, Takuya Kobayashi, Fernando Lamego, Vladimir Maderich, Byung-Il Min, Hartmut Nies, Iolanda Osvath, Maria Psaltaki, Kyung-Suk Suh "A new comparison of marine dispersion model performances for Fukushima Dai-ichi releases in the frame of IAEA MODARIA program" Journal of Environmental Radioactivity 150(2015), 247-269.

8. V. Maderich, K. Jung , Terletska E , Talipova T., I. Brovchenko Incomplete similarity of internal solitary waves with trapped core Fluid Dynamics Research // Fluid Dyn. Res. 47 (2015) 035511 (19pp).

9. Talipova T., Terletska K., Maderich V., Brovchenko I., Jung K.T., Pelinovsky E., Grimshaw R., (2013) Internal solitary wave transformation over a bottom step: loss of energy, Physics of Fluids 25, 032110; doi: 10.1063/1.4797455.

10. Roland A., Zhang Y.J., Wang H.V., Meng Y, Teng Y.-C., Maderich V., Brovchenko I., Dutour-Sikiric M., Zanke U. (2012) A fully coupled 3D wave-current interaction model on unstructured grids. J. Geophys Res., 117, C00J33, p.1-18 doi:10.1029/2012JC007952.

11. Maderich V., Brovchenko I., K.T. Jung (2012) Oil spreading in instantaneous and continuous spills on rotating Earth. Environmental Fluid Mechanics 12, 361–378. doi: 10.1007/s10652-012-9239-2.

12. Maderich V., Talipova T., Grimshaw R., Terletska K., Brovchenko I., Pelinovsky E., Choi B.H. (2010) Interaction of a large amplitude interfacial solitary wave of depression with a bottom step. Physics of Fluids , 22, 076602, doi:10.1063/1.345598.

13. Maderich V., Talipova T., Grimshaw R., Pelinovsky E., Choi B.H., Brovchenko I.,  Terletska K., Kim D.C. (2009) The transformation of an interfacial solitary wave of elevation at a bottom step. Nonlinear Processes in Geophysics , 16, 33-42.

14. Maderich V., Heling R., Bezhenar  R., Brovchenko I., Jenner H., Koshebutskyy V., Kuschan A., Terletska K. (2008) Development and application of 3D numerical model THREETOX to the prediction of cooling water transport and mixing in the inland and coastal waters. Hydrological Processes, 22, 1000-1013.

15. Brovchenko I., Kanarska Y., Maderich V., Terletska K. (2007) 3D non-hydrostatic modelling of bottom stability under impact of the turbulent ship propeller jet. Acta Geophysica, 55 ,no 1, pp. 47-55.

16. Brovchenko I., Maderich V. (2005) Oil dispersion by breaking waves and currents. Modeling of transport of spilled oil in wind and wave driven sea. Sea Technology, 46, No. 4, p.17-21.

17. Maderich V., Kim K.O., Brovchenko I., Jung K.T., Kivva S., Kovalets K. Dispersion of Particle-Reactive Elements Caused by the Phase Transitions in Scavenging // JGR Oceans Volume127, Issue10.

18. Brovchenko I., Kim, K.O., Maderich V., Jung K.T., Bezhenar R., Ryu J.H., Min J.E. (2022) Sediment and Radioactivity Transport in the Bohai, Yellow, and East China Seas: A Modeling Study. J. Mar. Sci. Eng., 10, 596. https://doi.org/10.3390/jmse10050596.

19. Brovchenko I., Maderich V., Choi B.H., Kim K.O., Martazinova V. (2022) Modelling of short-term variations of currents temperature, salinity and sea level in the Strait of Dardanelles // Ocean Engineering, Volume 245, 2022,110567, https://doi.org/10.1016/j.oceaneng.2022.110567.

20. Brovchenko I., Kim K.O., Maderich V., Jung K.T., Bezhenar R., Ryu J.H., Min J.E. (2022) Sediment and Radioactivity Transport in the Bohai, Yellow, and East China Seas: A Modeling Study. J. Mar. Sci. Eng., 10, 596. https://doi.org/10.3390/jmse10050596.

21. Maderich V., Kim K.O., Brovchenko I. et al. Scavenging processes in multicomponent medium with first-order reaction kinetics: Lagrangian and Eulerian modeling. Environ Fluid Mech (2021). https://doi.org/10.1007/s10652-021-09799-1.

       Last modified: Jun 6, 2023
© Copyright 2006 IMMSP
Development: Tugayenko Alexander