Abstract
The paper proposes an analysis of the winter phenomena generated by severe persistent negative temperatures (over two months) and sudden changes in weather, as well as of the effects induced by these phenomena on the anthropogenic and natural environment. In the first chapter of the paper, a selective radiography of the main international and national publications related to the winter phenomena on the watercourses is done, with a focus on natural manifestations of ice jam type. A significant concentration of specialists and studies is noticeable in the Nordic world area or in countries with high mountain areas. Also in the first chapter, it provides information about the studied area—the upper watershed of Tisa River, in general, and the Romanian watershed of the upper Tisa, as a case study, as well as on the monitoring activity of the Romanian part of the study basin. The second chapter is dedicated to the presentation of three major components of this space—the morphological, climatic, and hydric—decisive general conditions for the winter phenomena that occurred on the watercourses. In the third part, and the most extended, the specific conditions of occurrence are analyzed at the level of detail (morphological and morphometric, weather conditions—with special regard to the synoptic, the temperature and precipitation variation in the study period), the anthropogenic conditions of the riverbed influence on the studied river sectors. It also includes an analysis on the rivers state, types of winter phenomena occurred during the December 1, 2016–February 14, 2017 period—where the complex winter chart was a great help in the correlation between parameters and in highlighting the phenomena severity—their evolution, monitoring, and management. At the end of this chapter, the variation of the river water levels reported to the defense levels is detailed, as of great significance in explaining the effects generated by natural occurrences. In the last part, issues related to the effects of the winter phenomena on the anthropogenic and natural environment are presented, with details on the produced damages according to the different categories of affected items. The most important aspect related to the consequences refers to damage limitation and the absence of human victims, due to the prompt, concerted, and synchronized actions of all the involved authorities and institutions.
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References
Ardelean G, Béreş I (2000) The vertebrate fauna of Maramureş. The Universitaria Collection, Edit. Dacia, Cluj-Napoca, 378 p
Ashton GD (1986) River and lake ice engineering. Water Resources Publications, Littleton, Colorado, USA, 485 p
Bas N, Jenkins D, Rothery P (1984) Ecology of otters in Northern Scotland. V. The distribution of otter (Lutra lutra) faeces in relation to bankside vegetation in the river Dee in summer 1981. J Appl Ecol 21:507–513
Bashta AT, Potish L (2007) Mammals of the Transcarpathian region (Ukraine), Lviv, 260 p
Bates R.E., Billelo M.A. (1966) Defining the cold regions of the Northern Hemisphere. Cold Regions Research and Engineering Laboratory, Technical Report, Nr. 178
Beltaos S (1990) Fracture and breakup of river ice cover. Can J Civ Eng 17(2):173–183
Beltaos S (1993) Numerical computation of river ice jams. Can J Civ Eng 20(1):88–99
Beltaos S (2007) Hydro-climatic impacts on the ice cover of the lower Peace River. Hydrol Process 19
Beltaos S (2008) Progress in the study and management of river ice jams. Cold Reg Sci Technol 51:2–19
Beltaos S (2016) Extreme sediment pulses during ice breakup, Saint John River, Canada. Cold Reg Sci Technol 128(2016):38–46
Beltaos S, Burrell BC (2015) Hydroclimatic aspects of ice jam flooding near Perth-Andover, New Brunswick, Canadian. J Civ Eng 42(9) Special Issue: SI Pages: 686–695
Beltaos S, Burrell BC (2016a) Transport of suspended sediment during the breakup of the ice cover, Saint John River, Canada. Cold Reg Sci Technol 129:1–13
Beltaos S, Burrell BC (2016b) Characteristics of suspended sediment and metal transport during ice breakup, Saint John River, Canada. Cold Reg Sci Technol 123:164–176
Beltaos S, Prowse TD (2001) Climate impacts on extreme ice-jam events in Canadian rivers. Hydrol Sci J 46(1):157–181. https://doi.org/10.1080/02626660109492807
Boar N (2005) The Romanian-Ukrainian cross-border region of Maramureş, Edit. Presa Universitară Clujeană, 294 p
Boivin M, Buffin-Belanger T, Piegay H (2017) Interannual kinetics (2010–2013) of large wood in a river corridor exposed to a 50-year flood event and fluvial ice dynamics 3rd International Conference on Wood in World Rivers, Padova, Italy & Geomorphology, vol 279, Special Issue: SI Pages: 59–73
Chiş VT, Kosinszki S (2011) Geographical introductory characterization of the Upper Tisa River Basin (Romania-Ukraine), “The Upper Tisa River Basin”. Transylvanian Rev Systematical Ecol Res 11:1–4
Ciaglic V (1965) The evolution of the freezing phenomenon on river Bistricioara in the winter of 1963–1964 (in Romanian). Hidrotehnica 10(2):92–101
Cocuţ M (2008) The characteristics of water flow in the Basin of Maramureş and in the limitrophe mountain zone. Doctoral thesis—manuscript. Babeş-BolyaiUniversity, College of Geography, Cluj-Napoca, 115 p
Cojoc G, Romanescu G, Tîrnovan A (2015) Exceptional floods on a developed river. Case study for the Bistrita River from the Eastern Carpathians (Romania). Nat Hazards 77(3):1421–1451
Colceriu R (2002) Ice jams, risk factors in the upper hydrographic basin of the Mures river (in Romanian), Edit. “Dimitrie Cantemir” Tg. Mureş, 154 p
Colceriu R (2003) The study of freezing phenomena in the upper course of Mures river (between the source and Tg. Mureş) (in Romanian). Doctoral thesis, The Geography Institute of the Bucharest Academy, manuscript
Colceriu R (2010) The strategy and the outlook against floods in the Mures hydrographic basin space (in Romanian). From “The water resources of Romania—vulnerability at anthropic pressures”. In: Gâştescu P, Breţcan P (eds) The first Limnogeography national symposium works, 11–13 June, Valahia Univeristy, Târgovişte, Edit. Transversal, pp 175–183
Constantinescu C (1964) The factors that treats the existence and the duration of winter phenomena on Danube on the downstream sector from Tr. Severin (in Romanian). Meteorologia, Hidrologia şi Gospodărirea Apelor, 1
Daly SF (2009) Investigation of changes in conveyance of the St. Clair River over time using a state-space Model. US Army Engineering Research and Development Center, Cold Regions Research and Engineering Laboratory, ERDC/CRREL, Hanover, NH
Delibes M, Macdonald SM, Mason CF (1991) Seasonal marking, habitat and organochlorine contamination in otters (Lutra lutra): a comparison between catchments in Andalucía and Wales. Mammalia 55:567–578
Derecki JA, Quinn FH (1986) Record St. Clair River Ice Jam of 1984. J Hydraul Eng ASCE 112(12):1182–1194
Găman C (2014) Considerations on recent freezing phenomena on Bistriţa and Bistricioara rivers. PESD 8(2):225–242. De Gruyter Open, https://doi.org/10.2478/pesd-2014-0037
Gholamreza-Kashi S (2016) A forecasting methodology for predicting frazil ice flooding along urban streams using hydro-meteorological data. Can J Civ Eng 43(8):716–723
Giurma I, Stefanache D (2010) Winter phenomena on the Bistrita river between hazard and vulnerability (in Romanian). Paper N.I.H.W.M. National Institute of Hydrology and Water Management—Jubilee Conference, “Gheorghe Asachi” Technical University, Iaşi
Harka A, Bănărescu PM, Telcean I (1999) Fish fauna of the Upper Tisa, în Upper Tisa Valley, Tiscia monograph series, Szolnok-Szeged-Târgu Mures, pp 439–454
Huang Y, Sun J, Li W (2016) Experimental observations of the flexural failure process of snow covered ice. Cold Reg Sci Technol 129:14–30
Ichim I, Rădoane M (1986) The effects of dams in the landform dynamic. Geomorfological approach (in Romanian), Edit. Academiei, Bucureşti
Ichim I, Bătucă D, Rădoane M, Duma D (1989) The morphologic and the dynamic of river beds (in Romanian), Edit. Tehnică, Bucureşti
Jasek M (2003) Ice jam release surges, ice runs, and breaking fronts: Field measurements, physical descriptions, and research needs. Can J Civ Eng 30(1):113–127
Jurajda P, Reichard M (2006) Immediate impact of an extensive summer flood on the adult fish assemblage of a channelized Lowland River. J Freshw Ecol 21(3):493–501
Jurajda P, Hohausova E, Gclnar M (1998) Seasonal dynamics of fish abundance below a migration barrier in the lower regulated River Morava. Folia Zool 47:215–223
Koegel M, Das A, Marszelewski W et al (2017) Feasibility study for forecasting ice jams along the river Oder. Wasserwirtschaft 107(5):20–28
Kolerski T (2014) Modeling of ice phenomena in the mouth of the Vistula River. Acta Geophys 62(4):893–914
Kolerski T, Shen HT (2010) St. Clair River ice jam dynamics and possible effect on bed changes. In: Proceedings of the 20th I.A.H.R. International Symposium on Ice, 14–18 June 2010, Lahti, Finland
Kolerski T, Shen HT (2015) Possible effects of the 1984 St. Clair River ice jam on bed changes. Can J Civ Eng 42(9):696–703
Korytny LM, Kichigina NV (2006) Geographical analysis of river floods and their causes in southern East Siberia. Hydrol Sci J 51:3
Kowalczyk T, Hicks F (2003) Observations of dynamic ice jam release waves on the Athabasca River near Fort McMurray. Can J Civ Eng 34:473–484
Kraatz S, Khanbilvardi R, Romanov P (2017) A comparison of MODIS/VIIRS cloud masks over ice-bearing river: on achieving consistent cloud masking and improved river ice mapping. Remote Sens 9(3):229
Kruuk H (1995) Wild Otters. Predation and populations. Oxford University Press, Oxford
Kupferberg SJ, Palen WJ, Lind AJ et al (2012) Effects of flow regimes altered by dams on survival, population declines, and range-wide losses of California river-breeding frogs. Conserv Biol 26:513–524
Lagadec A, Boucher E, Germain D (2015) Tree ring analysis of hydro-climatic thresholds that trigger ice jams on the Mistassini River. Que Hydrol Process 29(23):4880–4890
Leopold LB, Maddock T (1953) The hydraulic geometry of stream channels and some physiographic implications, U.S. Geological Survey Professional Paper, 275 p
Leopold LB, Wolman MG, Miller JP (1964) Fluvial processes in geomorphology. W. Freeman and Co., San Francisco, p 522
Lindenschmidt KE, Das A, Rokaya P et al (2016) Ice-jam flood risk assessment and mapping. Hydrol Process 30(21):3754–3769
Liu L, Shen HT (2004) Dynamics of ice jam release surges. In: Proceedings of the 17th IAHR International Symposium on Ice, St. Petersburg, pp 244–250
Lu S, Shen HT, Crissman RD (1999) Numerical study of ice dynamics in upper Niagara River. J Cold Reg Eng ASCE 13(2):78–102
Lucie C, Nowroozpour A, Ettema R (2017) Ice jams in straight and sinuous channels: insights from small flumes. J Cold Reg Eng 31(3):04017006
Lucza Z (2017) This winter through the eyes of the hydrologist. FELSŐ-TISZA HIRADÓ, LVI. évfolyam 01.szám, pp 20–22 (in Hungarian) (https://www.fetivizig.hu/WEB/FETIKOVIZIG/VIZIGINFO_Start.nsf/Node.xsp?documentId=A7D2D748C29962FEC12580FA00315B18&action=editDocument)
Lukianets O, Obodovskyi I (2015) Spatial, temporal and forecast evaluation of rivers’ streamflow of the Drainage Basin of the upper tisa under the conditions of climate change. Environ Res Eng Manage 71(1):36–46
Matthews VJ (1998) Patterns in freshwater fish ecology. Chapmann Hall, New York
Melquist WE, Hornocker MG (1983) Ecology of river otters in West Central Idaho. Wildl Monogr 83:1–60
Michener VK, Haeuber RA (1998) Flooding: natural and managed disturbances. Bioscience 48:677–680
Miţă P (1977) The freezing and the thermic regime of water courses in Romania (in Romanian). Doctoral thesis—manuscript, University of Bucharest
Morse B, Hicks F (2005) Advances in river ice hydrology 1999–2003. Hydrol Process 19(1):247–263. https://doi.org/10.1002/hyp
Mustăţea A (1996) Exceptional floods on Romanian territory. Genesis and effects (in Romanian), Edit. INHGA, Bucharest, 376 p
Nafziger J, She Y, Hicks F (2016) Celerities of waves and ice runs from ice jam releases. Cold Reg Sci Technol 123:71–80
Ocock J, Kingsford RT, Penman TD, Rowley JJL (2014) Frogs during the flood: Differential behaviours of two amphibian species in a dryland floodplain wetland. Austral Ecol 39:929–940
Oprea E, Irimia D (2015) Monitoring the conservation status of species and habitats in Romania on the basis of Article 17 of the Habitats Directive, a Project financed through SOP Environment, 2007–2013
Paparyha P, Pipash Ludmyla, Shmilo V, Veklyuk Anatoly (2011) Hydrochemical Status of Streams and Rivers of the Upper Tysa River Basin in the Ukrainian Carpathians. “The Upper Tisa River Basin”. Transylvanian Rev Systematical Ecol Res 11:47–52
Păvăleanu I (2003) The ice jam phenomenon on Bistrita river, upstream of Izvoru Muntelui (in Romanian), Tehnical University “Gheorghe Asachi”. Faculty of Hydrotehnics—manuscript, Iaşi
Pawlowski B (2016) Internal structure and sources of selected ice jams on the lower Vistula River. Hydrol Process 30(24):4543–4555
Poff XL, Allan JD, Bain MB, Karr JR, Prestegaard KL, Richter BD, Sparks RE, Stromberg JC (1997) The natural flow regime. Bioscience 47:769–784
Pop PG (2000) The Carpathians and sub-Carpathians of Romania, Edit. Presa Universitară, Cluj-Napoca, 264 p
Posea G, Moldovan C, Posea A (1980) County of Maramureş. Romanian Academy’s Publishing, Bucureşti, p 179
Prenda J, López-Nieves P, Bravo R (2001) Conservation of otter (Lutra lutra) in a Mediterranean area: the importance of habitat quality and temporal variation in water availability. Aquatic Conserv Mar Freshw Ecosyst 11:343–355. https://doi.org/10.1002/aqc.454
Prowse TD, Beltaos S (2002) Climatic control of river-ice hydrology: a review. Hydrol Process 16:805–822
Prowse TD, Bonsal BR (2004) Historical trends in river-ice break-up: a review. Nord Hydrol 35(4–5):281–293
Prowse TD, Conly FM (1998) Effects of climatic variability and flow regulation on ice-jam flooding of a northern delta. Hydrol Process 12:1589–1610
Rădoane M (2004) Relief dinamics în the area of Izvoru Muntelui Lake (in Romanian), Edit. Universităţii Suceava, Suceava
Rădoane M, Ciaglic V, Rădoane N (2008) Researches on the ice jam formation in the upstream of Izvoru Muntelui reservoir. Analele Universității Ștefan cel Mare, Suceava, Secțiunea Geografie XVII:45–58
Rădoane M, Ciaglic V, Rădoane N (2010) Hydropower impact on the ice jam formation on the upper Bistriţa River, Romania. Cold Reg Sci Technol J 60(3):193–204
Rasmussen JL (1996) Floodplain management. Fisheries 21:6–10
Rhodes DD (1977) The b-f-m diagrame: graphical representation and interpretation of at-a-station hydraulic geometry. Am J Sci 277
Robb DM, Gaskin SJ, Marongiu J-C (2016) SPH-DEM model for free-surface flows containing solids applied to river ice jams. J Hydraul Res 54(1):27–40
Romanescu G (2003) Floods, between natural and accidental (in Romanian). The “Riscuri şi catastrofe” magazine, No. II, Edit. Casa Cărţii de Ştiință, Cluj-Napoca, pp 130–138
Romanescu G (2005) The upstream floods risk of Izvorul Muntelui Lake and the immediate effect of geomorfological characters of the river bed (in Romanian). The “Riscuri şi catastrofe” magazine, Edit. Casa Cărţii de Ştiință, Cluj-Napoca, pp 117–124
Romanescu G (2015) Water management. Hydrotechnical improvement of hydrographic basins and the wet zones (in Romanian), Edit. Terra Nostra, Iași, 324 p
Romanescu G and Bounegru O (2012) Ice dams and backwaters as hydrological risk phenomena—case study: the Bistrita River, upstream of the Izvorul Muntelui Lake (Romania). Flood Recovery Innovation and Response III, WIT Transactions on Ecology and The Environment, vol 159, WIT Press, pp 167–178, https://doi.org/10.2495/friar120141
Romanescu G, Stoleriu C (2017) Exceptional floods in the Prut basin, Romania, in the context of heavy rains in the summer of 2010. Nat Hazards Earth Syst Sci 17:381–396
Romanescu G, Cojoc GM, Sandu IG, Tîrnovan A, Dăscălița D, Sandu I (2015) Pollution sources and water quality in the Bistrita Catchment (Eastern Carpathians). Chem Mag 66(6):855–863
Sabău D, Bătinaş R, Roşu I, Şerban G (2017) Fresh Water Resources in the Natura 2000 Pricop-Huta Certeze and Tisa Superioară Protected Areas. “Air and Water—Components of the environment” Conference Proceedings. In: Şerban G, Croitoru A, Tudose T, Bătinaş R, Horvath CS, Holobâcă I(eds) Babeş-Bolyai University, Faculty of Geography, Cluj-Napoca, România, Edit. Casa Cărţii de Ştiinţă, pp 166–175
Semenescu M (1960) The freezing phenomenon in the sector of Porţile de Fier (in Romanian). Meteorologia Hidrologia şi Gospodărirea Apelor 4
Şerban G, Pandi G, Sima A (2012) The need for reservoir improvement in Vişeu river basin, with minimal impact on protected areas. In: Order to prevent flooding. Studia University “Babeş-Bolyai”, Geographia, LVII, nr. 1, Cluj-Napoca, pp 71–80
Şerban G, Sabău A, Rafan S, Corpade C, Niţoaia A, Ponciş R (2016) Risks Induced by maximum flow with 1% probability and their effect on several species and habitats in Pricop-Huta-Certeze and Upper Tisa Natura 2000 Protected Areas. “Air and Water—Components of the environment” Conference Proceedings. In: Şerban G, Bătinaş R, Croitoru A, Holobâcă I, Horvath C, Tudose T (eds) Babeş-Bolyai University, Faculty of Geography, Cluj-Napoca, România, Edit. Casa Cărţii de Ştiinţă, pp 58–69
She Y, Hicks F (2006) Modeling ice jam release wave with consideration for ice effects. Cold Reg Sci Technol 20:137–147
Shen HT, Liu L (2003) Shokotsu River ice jam formation. Cold Reg Sci Technol J 37:35–49
Shen HT (2016) River ice processes. In: Wang LK, Yang CT, Wang MHS (eds) Handbook of environmental engineering, vol 16. Advances in Water Resources Management, pp 483–530
Shen HT, Gao L, Kolerski T, Liu L (2008) Dynamics of ice jam formation and release. J Coast Res S52:25–32
Shen HT, Su J, Liu L (2000) SPH simulation of River Ice dynamics. J Comput Phys 165(2):752–770
Sorocovschi V, Şerban G (2012) Elements of climatology and hydrology. Part II—Hydrology. ID Education form. Edit. Casa Cărţii de Ştiinţă, Cluj-Napoca, 242 p
Sorocovschi V, Şerban G, Bătinaş R (2002) Hydric risks in the lower basin of Aries river (in Romanian). “Riscuri şi catastrofe” magazine, Edit. Casa Cărţii de Ştiință, vol I, Cluj-Napoca, pp 143–148
Ştefănache D (2007a) Studies of the evolution of some dangerous hydrological phenomena (in Romanian). Doctoral thesis, Tehnical University “Gheorghe Asachi”, Iaşi—manuscript
Ştefănache D (2007b) Le phénomène d‟hiver sur les rivières de la Roumanie -L‟évolution des barrages de glace du basin hydrographique supérieur de la rivière de Bistriţa, 14th Workshop on the Hydraulics of Ice Covered Rivers, Québec
Surdeanu V, Berindean N, Olariu P (2005) The natural and antrophic factors that leads to ice jams in the upper basin of Bistrita river (in Romanian). “Riscuri şi catastrofe” magazine, vol IV, no 2, Cluj-Napoca, pp 125–134
Telcean I, Cupşa Diana (2011) The occurrence of carpathian brook lamprey Eudontomyzon danfordi regan 1911 (petromyzontes, petromyzontidae) in the upper tisa tributaries from northern romania. Pisces hungarici 5:123–128
Thériault I, Saucet J-P, Taha W (2010) Validation of the mike-ice model simulating river flows in presence of ice and forecast of changes to the ice regime of the Romaine river due to hydroelectric project. In: Proceedings of the 20th IAHR International Symposium on Ice, Lahti, Finland
Tockner K, Klaus I, Baumgartner C, Ward JV (2006) Amphibian diversity and nestedness in a dynamic floodplain river (Tagliamento, NE-Italy). Hydrobiologia 565:121–133
Ujvári I (1972) The geography of Romanian waters, Edit. Ştiinţifică, Bucureşti, 578 p
USACE (1984) April 1984 Ice Jam Report; St. Clair River. Department of the Army, Corps of Engineers, Detroit District, Great Lake, Hydraulics and Hydrology Branch, Detroit, MI
Wang J, Hua J, Sui J et al (2016) The impact of bridge pier on ice jam evolution—an experimental study. J Hydrol Hydromechanics 64(1):75–82
Wang J, Shi F-Y, Chen P-P et al (2015a) Impact of bridge pier on the stability of ice jam. J Hydrodyn 27(6):865–871
Wang J, Shi F-Y, Chen P-P et al (2015b) Impacts of bridge piers on the initiation of ice cover—an experimental study. J Hydrol Hydromechanics 63(4):327–333
Wang J, Shi F-Y, Chen P-P, Wu P, Sui J (2014) Simulations of ice jam thickness distribution in the transverse direction. J Hydrodyn Ser B 26(5):762–769
White KD, Eames HJ (1999) CRREL Ice Jam Database, USA CRREL Report 99-2, CRREL, Hanover, NH. www.dtic.mil/get-tr-doc/pdf?AD=ADA362147
White KD, Tuthill AM, Vuyovich CM, Weyrick PB (2007) Observed climate variability impacts and river ice in the United States. CGU HS Committee on River Ice Processes and the Environment, 14th Workshop on the Hydraulics of Ice Covered Rivers, June 20–22, Quebec City, Quebec, Canada, 1–11 pp
Yatsyk AV, Byshovets LB et al (1991) Small rivers of Ukraine: Manual. In: Yatsyk AV (ed) К: Urozhai Publisher, 296 p (in Ukrainian)
Zare S, Moore S, Rennie CD et al (2016) Boundary shear stress in an ice-covered river during breakup. J Hydraul Eng 142(4):04015065
Zeleňáková M, Zvijáková L (2017) Using risk analysis for flood protection assessment. Springer International Publishing, Springer, 140 p, https://doi.org/10.1007/978-3-319-52150-3
* * * (1992) The atlas of water cadastre of Romania, Ministry of Environment and Aquaproject S.A., Bucureşti, 683 p
* * * (2015) Frogs in wetlands, http://www.environment.nsw.gov.au/wetlands/WetlandFrogs.htm
* * * (1996) Instructions of organization and the program of the hydrometric network’s activity on rivers (in Romanian), N.I.M.H., Bucharest
* * * (2009) Sub-Basin Level Flood Action Plan Tisza River Basin, International Commission for the Protection of the Danube River—Flood Protection Expert Group, Hungary, Romania, Slovakia, Serbia, Ukraine
* * * (2013) Best Practice for Building and Working Safely on Ice Covers in Alberta. Government of Alberta, Occupational Health and Safety Contact Centre, http://work.alberta.ca/occupational-health-safety/274.html
* * * (2013) Guide for the activity of hydrometric stations on rivers, N.I.H.G.A., Bucharest
* * * Cold Regions Research and Engineering Laboratory (CRREL) of the U.S. Army Corps of Engineers, http://www.erdc.usace.army.mil/Locations/CRREL/
* * * Photo source 1: https://map.viamichelin.com/map/carte?map=viamichelin&z=4&lat=50.45043&lon=30.52449&width=550&height=382&format=png&version=latest&layer=background&debug_pattern=.*;
* * * Photo source 2: https://upload.wikimedia.org/wikipedia/commons/9/95/Romania_Ukraine_Locator.png
* * * Records of S.T.B.W.A. - M.W.M.S. (Maramureș Water Management System)
* * * Records of S.T.B.W.A. (“Someș-Tisa” Basin Water Administration, Cluj)
* * * (2016) Microsoft Office Home and Student
* * * (2008) The Climate of Romania. National Administration of Meteorology, Edit. of Romanian Academy, Bucharest
Acknowledgements
We want to thank the Administration of the “Somes-Tisa” Water Basin, Cluj (S.T.W.B.A.), and Maramureș W.M.S. for the provided data and for the pictures captured during the extreme winter events in the analyzed basin. Thank you also all those who have offered or will offer suggestions for the improvement of the present paper.
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Sabău, D., Şerban, G., Kocsis, I., Stroi, P., Stroi, R. (2018). Winter Phenomena (Ice Jam) on Rivers from the Romanian Upper Tisa Watershed in 2006–2017 Winter Season. In: Zelenakova, M. (eds) Water Management and the Environment: Case Studies. WINEC 2017. Water Science and Technology Library, vol 86. Springer, Cham. https://doi.org/10.1007/978-3-319-79014-5_7
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