Analysis of river drying in Slovenia

Jan Cvelfer Domadenik; Mojca Šraj; Mira Kobold

Authors: Jan Cvelfer Domadenik, Mojca Šraj, Mira Kobold
Citation: Acta hydrotechnica, vol. 36, no. 65, pp. 123-137, 2023. https://doi.org/10.15292/acta.hydro.2023.08
Abstract: Intermittent watercourses lack water during some periods of the year, which especially applies to karst sinking streams. Droughts also occur in dry periods with no rainfall over a longer period of time. The drying up of Slovenian rivers was analysed using the data from the state hydrological monitoring of the Slovenian Environment Agency. By analysing the periodic statistics of minimum low discharges (nQnp), 18 gauging stations were extracted where the watercourses dried up during the measurement period. For these stations, sets of mean daily discharges were analysed, and dry days where the flow was equal to zero were listed. The number of dry days and the number of consecutive dry days were analysed by month and year, and the longest dry periods were determined. The results are presented graphically. At most of the gauging stations considered, the number of dry days was the highest in the years characterized by extreme hydrological droughts, namely 2003, 2012, and 1993. In some watercourses, drying up is a constant phenomenon that occurs almost every year, while others only dry up in years characterized by extreme droughts. Exceptions to this are the karst rivers, which sink and are therefore dry for part of the year. The Pivka and Branica Rivers regularly dry up. Watercourses in Pomurje and Velunja, Kožbanjšček, and Dragonja also dry up very often. Analysis results demonstrated that river drying has become more frequent in the past two decades. The driest month is August, followed by July and September.
Keywords: Hydrological drought, minimum low discharge, water gauging station, number of dry days, number of consecutive dry days.
Full text: a36jcd.pdf
References:
- ARSO (2021). Mesečne statistike. Ljubljana. http://www.arso.gov.si/vode/podatki/arhiv/hidroloski_arhiv.html (Pridobljeno 10. 5. 2021.)
- ARSO (2022). Arhiv hidroloških podatkov. Ljubljana. https://vode.arso.gov.si/hidarhiv/pov_arhiv_tab.php (Pridobljeno 16. 2. 2022.)
- Bertalanič, R., Dolinar, M., Draksler, A., Honzak, L., Kobold, M., Kozjek, K., Lokošek, N., Medved, A., Vertačnik, G., Vlahović, Ž, Žust, A. (2018). Ocena podnebnih sprememb v Sloveniji do konca 21. stoletja. Sintezno poročilo - prvi del. Ministrstvo za okolje in prostor, Agencija Republike Slovenije za okolje, Ljubljana.
- Bonacci, O., Terzić, J., Roje-Bonacci, T., Frangen, T. (2019). An Intermittent Karst River: The Case of the Čikola River (Dinaric Karst, Croatia). Water 11(11), 2415. https://doi:10.3390/w11112415.
- Boulton, A. J. (2003). Parallels and contrasts in the effects of drought on stream macroinvertebrate assemblages. Freshwater Biology 48, 1173–1185.
- Brenčič, M. (2011). Zakaj je izginila reka Iška? https://www.obcina-ig.si/wp-content/uploads/stab-civilne-zascite/Zakaj_je_izginila_reka_Iska.pdf (Pridobljeno 17. 1. 2023.)
- Cegnar, T. (2010). Podnebne spremembe in potreba po prilagajanju nanje. V: Cegnar, T. (ur.), Okolje se spreminja: podnebna spremenljivost Slovenije in njen vpliv na vodno okolje. Agencija Republike Slovenije za okolje, Ljubljana, 3–14.
- Cunja, J., Kobold, M., Šraj, M. (2019). Časovna in prostorska analiza največjih hidroloških suš v Sloveniji. Ujma 33, 95–103.
- Cunja, J., Kobold, M., Šraj, M. (2020). Analysis of runoff deficit using the treshold method for the case of three gauging stations in Slovenia. Acta hydrotechnica 33(59), 113–127. https://doi.org/10.15292/acta.hydro.2020.08.
- Cvelfer Domadenik, J. (2023). Analiza presušitve rek v Sloveniji. Univerza v Ljubljani, FGG.
- Delo (2010). Trije kilometri Iške popolnoma presahnili. https://old.delo.si/novice/slovenija/trije-kilometri-iske-popolnoma-presahnili.html (Pridobljeno dne 10. 1. 2022.)
- Dolinar, M., Vertačnik, G. (2010). Spremenljivost temperaturnih in padavinskih razmer v Sloveniji. V: Cegnar, T. (ur.), Okolje se spreminja: podnebna spremenljivost Slovenije in njen vpliv na vodno okolje. Ministrstvo za okolje in prostor, Agencija Republike Slovenije za okolje, Ljubljana, 37–40.
- IPCC (2007). Climate Change 2007: The Physical Science Basis. Chapter 1. Cambridge University Press, Cambridge.
- IPCC (2022). Climate Change 2022: Impacts, Adaptation and Vulnerability. Chapter 4. Cambridge University Press, Cambridge.
- Jelen, M., Mikoš, M., Bezak, N. (2020). Karst springs in Slovenia: Trend analysis. Acta Hydrotechnica, 33, 1–12. https://doi.org/10.15292/acta.hydro.2020.01.
- Kobold, M. (2004). Hidrološka suša slovenskih vodotokov v obdobju 2000–2002. Ujma 17-18, 102–111.
- Kobold, M. (2015). Hidrološko stanje voda kot posledica vremenskega dogajanja. Vetrnica: glasilo Slovenskega meteorološkega društva 8, 4–7.
- Kobold, M. (2023). Primerjava hidrološke suše površinskih voda leta 2022 s sušnimi leti 1993, 2003 in 2012. Ujma 37, 98–107.
- Kobold, M., Ulaga, F. (2010). Hidrološko stanje voda in podnebna spremenljivost. V: Cegnar, T. (ur.), Okolje se spreminja: podnebna spremenljivost Slovenije in njen vpliv na vodno okolje. Ministrstvo za okolje in prostor, Agencija Republike Slovenije za okolje, Ljubljana, 43–56.
- Kobold, M., Dolinar, M., Frantar, P. (2012). Spremembe vodnega režima zaradi podnebnih sprememb in drugih antropogenih vplivov. Zbornik I. kongresa o vodah Slovenije 2012, Ljubljana, 12–17.
- Kogovšek, J. (2012). Kras in voda. Zbornik I. kongresa o vodah Slovenije 2012, Ljubljana, 91–101.
- Kostevc, L., Kobold, M., Šraj, M. (2022). Analysis of seasonal and spatial variability of river flow characteristics in Slovenia. Acta Hydrotechnica, 35, 57–74. https://doi.org/10.15292/acta.hydro.2022.05.
- Lake, P. S. (2003). Ecological effects of perturbation by drought in flowing waters. Freshwater Biology 48, 1161–1172. https://doi.org/10.1046/j.1365-2427.2003.01086.x.
- Magalhaes, M. F., Beja, P., Schlosser, I. J., Collares-Pereira, M. J. (2007). Effects of multi-year droughts on fish assemblages of seasonally drying Mediterranean streams. Freshwater Biology 52, 1494–1510. https://doi.org/10.1111/j.1365-2427.2007.01781.x.
- Oblak, J., Kobold, M., Šraj, M. (2021). The influence of climate change on discharge fluctuations in Slovenian rivers. Acta geographica Slovenica 61-2, 155–169. https://doi.org/10.3986/AGS.9942.
- Smith, K. and Ward, R. (1998). Floods. Physical Processes and Human Impacts. John Wiley & Sons, England.
- Sušnik, A., Gregorič, G., Uhan, J., Kobold, M., Andjelov, M., Petan, S., Pavlič, U., Valher, A. (2013). Spremenljivost suš v slovenskem prostoru in analiza suše 2013. Zbornik referatov, 24. Mišičev vodarski dan, Maribor, 102–109.
- Šterbenk, E., Ževart, M., Ramšak, R. (2004). Jezera: o katerih bomo še slišali. Geografski obzornik, 51-1, 4–11. https://www.dlib.si/details/URN:NBN:SI:DOC-JX96WXMA (Pridobljeno, 12. 1. 2023).
- Tallaksen, M. in Van Lanen, A. (2004). Hydrological Drought: Processes and Estimation Methods for Streamflow and Groundwater. Developments in Water Science 48. Elsevier, Amsterdam. Chapter 1, 3–17.
- Toreti, A., Bavera, D., Acosta Navarro, J., Cammalleri, C., de Jager, A., Di Ciollo, C., Hrast Essenfelder, A., Maetens, W., Magni, D., Masante, D., Mazzeschi, M., Niemeyer, S., Spinoni, J. (2022). Drought in Europe August 2022. Publications Office of the European Union, Luxembourg. https://edo.jrc.ec.europa.eu/documents/news/GDO-EDODroughtNews202208_Europe.pdf (Pridobljeno 10. 10. 2022).
- Zalokar, L., Kobold, M., Šraj, M. (2021). Investigation of Spatial and Temporal Variability of Hydrological Drought in Slovenia Using the Standardised Streamflow Index (SSI). Water (Switzerland), 13, 3197. https://doi.org/10.3390/w13223197.