Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
The continuity of sediment transport in many catchment-river-sea systems worldwide has been disturbed by anthropogenic interferences. These interferences alter the sediment balance and result either in a surplus or lack of sediment, and with mostly negative, impacts to the economy, development and infrastructure, and environment. The main issues discussed related to surplus or lack of sediment belongs to: i) siltation of reservoirs with negative effects on hydropower production or water storage, and ii) erosion at downstream reaches where sediments are essential for channel formation and aquatic habitats. Both problems are recognized in Poland, however, only dealt with when they cause local economic problems. The paper focuses on examples of sustainable sediment managements in catchment-river-sea systems, and presents the idea of combining the Macromodel DNS with the SWAT module. The resulting modelling and analytical tool can be considered very valuable in sediment quantity management.
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
25--37
Opis fizyczny
Bibliogr. 49 poz., rys., tab.
Twórcy
autor
- AGH University of Science and Technology Faculty of Geology, Geophysics and Environmental Protection Mickiewicza street 30, Kraków, 30-059, Poland
autor
Bibliografia
- Apitz S.E. (2012), Conceptualizing the role of sediment in sustaining ecosystem services: Sediment-ecosystem regional assessment (SEcoRA), “Science of the Total Environment” No. 415, p. 9-30
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- Babiński Z. (2007), Deep erosion downstream of reservoirs on the example of selected dams in the world, “Nauka Przyroda Technologie” No. 1(2), p. 11 (in Polish)
- Bagarello V. et al. (2010), Testing alternative erosivity indices to predict event soil loss from bare plots in Southern Italy, “Hydrological processes” No. 24(6), p. 789-797
- Bartnik W. et al. (2015), Warunki przywracania struktury siedlisk dla ryb na odcinku Wisłoki w km 73+200 – 42+600, “Gospodarka Wodna” No. 5, p. 147-152 (in Polish)
- Burt T. et al. (2016), More rain, less soil: Long-term changes in rainfall intensity with climate change, “Earth Surface Processes and Landforms” No. 41, p. 563-566
- Chapman P.E., Smith M. (2010), Assessing, managing and monitoring contaminated aquatic sediments, “Marine Pollution Bulletine” No. 64(10), p. 2000-2004
- Duru U. et al. (2017), Modeling stream flow and sediment yield using the SWAT model: a case study of Ankara River basin, Turkey, “Physical Geography”, doi.org/10.1080 /02723646.2017.1342199
- Errico R.M. et al. (2013), Development and validation of observing‐system simulation experiments at NASA’s Global Modeling and Assimilation Office, “Quarterly Journal of Royal Meteorological Society” No. 139(674), p. 1162-1178
- Fremion F. et al. (2016), Impact of sediments resuspension on metal solubilization and water quality during recurrent reservoir sluicing management, “Science of the Total Environment” No. 562, p. 201-215
- Gaeuman D. (2014), High-flow gravel injection for construction designed in-flow channel features, “River Research and Applications” No. 30(6), p. 685-706
- Gray J.R. et al. (2010), Bedload-Surrogate Monitoring Technologies, U.S. Geological Survey Scientific Investigations, Report 2010-5091
- Habel M. et al. (2017), Issues related to renewal of the bed load downstream of dams. Assessment of the possibility to artificially rebuild the load downstream the Włocławek dam, “Gospodarka Wodna” No. 11, p. 361-363 (in Polish)
- Habersack H. et al. (2017), Integrated automatic and continuous bedload monitoring in gravel bed rivers, “Geomorphology” No. 291, p. 80-93
- Haregeweyn N. et al. (2017), Comprehensive assessment of soil erosion risk for better land use planning in river basins: Case study of the Upper Blue Nile River, “Science of the Total Environment” No. 574, p. 95-108
- Heckmann T. et al. (2017), Feeding the hungry river: Fluvial morphodynamics and the entrainment of artificially inserted sediment at the dammed river Isar, Eastern Alps, Germany, “Geomorphology” No. 291, p. 128-142
- IPCC (2014), Climate Change 2014, Synthesis Report, Core Writing Team, R.K.Pachauri, L.A. Meyer (eds), Geneva, p. 151
- Kantoush S.A., Sumi T. (2010), Geomorphic response of rivers below dams by sediment replenishment technique, in: Dittrich et al. (eds), River Flow, Bundesanstalt für Wasserbau, p. 1155-1163
- Kondolf G.M. (1997), Hungry water: effects of dams and gravel mining on river channels, “Environmental Management” No. 21(4), p. 533-551
- Kondolf G.M. et al. (2014), Sustainable sediment management in reservoirs and regulated rivers: Experiences from five continents, “Earth’s Future” No. 2, p. 256-280
- Kuhl D. (1992), 14 years of artificial grain feeding in the Rhine downstream the barrage Iffezheim, Proceedings of the 5th International Symposium on River Sedimentation, p. 1121-1129
- Li P. et al. (2017), Comparison of soil erosion models used to study the Chinese Loess Plateau, “Earth-Science Reviews” No. 17, p. 17-30
- Li Z. et al. (2009), Impacts of land use change and climate variability on hydrology in an agricultural catchment on the Loess Plateau of China, “Journal of Hydrology” No. 377(1), p. 35-42
- Li Y. et al. (2017), Assessing the impacts of climate and land use lane cover changes on hydrological droughts in the Yellow River Basin using SWAT model with time-varying parameters, Proceedings of Agro-Geoinformatics 6th International Conference, p. 1-6
- Likens G.E., Bormann F.H. (1974), Linkages between terrestrial and aquatic ecosystems, “BioScience” No. 24(8), p. 447-456
- Lin CP. et al. (2016), Extensive Monitoring System of Sediment Transport for Reservoir Sediment Management in: L. Wang et al. (eds) Natural Resources and Control Processes. “Handbook of Environmental Engineering” Vol. 17
- Melaku N.D. et al. (2017), Prediction of soil and water conservation structure impacts on runoff and erosion processes using SWAT model in the northern Ethiopian highlands, “Journal of Soils and Sediments” No. 1, p. 13
- Merz J.E. et al. (2005), Effects of gravel augmentation on macroinvertebrate assemblages in a regulated California river, “River Research and Applications” No. 21(1), p. 61-74
- Middelkoop, H. et al. (2001), Impact of climate change on hydrological regimes and water resources management in the Rhine basin, “Climatic change” No. 49(1), p. 105-128
- Mizugaki S. et al. (2014), Interpreting runoff process of suspended sediment at the watershed scale by observation and fingerprinting for improvement of model, in: American Geophysical UnionFall Meeting Abstracts H23L-1047
- Neitsch S.L. et al. (2011), Soil and water assessment tool theoretical documentation version 2009, Texas Water Resources Institute
- Nerantzaki S.D. et al. (2015), Modeling suspended sediment transport and assessing the impacts of climate change in a karstic Mediterranean watershed, “Science of the Total Environment” No. 538, p. 288-297
- NOAA (2017), National Centers for Environmental Information, State of the Climate: Global Climate Report for Dec. 2016, https://www.ncdc.noaa.gov/sotc/global/201612
- Olyaie E. et al. (2015), A comparison of various artificial intelligence approaches performance for estimating suspended sediment load of river systems: a case study in United States, “Environmental Monitoring and Assessment” No. 187(4), p. 189
- Panagos P. et al. (2017), Global rainfall erosivity assessment based on high-temporal resolution rainfall record, “Scientific Reports” No. 7, p. 4175
- Parzonka W. et al. (2010), Estimation of the degradation of the middle Odra river bed and programme of the restoration works, “Infrastructure and Ecology of Rural Areas” No. 8(1), p. 59-68 (in Polish)
- Peraza-Castro M. et al. (2015), Modeling environmental services in rivers at catchment scale, “Annales de Limnologie, International Journal of Limnology” No. 51(1), p. 59-70
- Perelo L.W. (2010), Review: In situ and bioremediation of organic pollutants in aquatic sediments, “Journal of Hazardous Materials” No. 177(1-3), p. 81-89
- Rodríguez-Blanco M.L. et al. (2016), Sediment yield at catchment scale using the SWAT (Soil and Water Assessment Tool) model, “Soil Science” No. 181(7), p. 326-334
- Schmitt R.J.P. et al. (2017), Losing ground – scenarios of land loss as consequence of shifting sediment budgets in the Mekong Delta, “Geomorphology” No. 294, p. 58-69
- Shivhare N. et al. (2017), Identification of critical soil erosion prone areas and prioritization of micro-watersheds using geoinformatics techniques, “Ecological Engineering”, doi.org/10.1016/j.ecoleng.2017.09.004
- Suedel B.C. et al. (2015), The effects of a simulated suspended sediment plume on eastern oyster (Crassostrea virginica) survival, growth, and condition, “Estuaries and coasts” No. 38(2), p. 578-589
- Sundborg A. (1992), Lake and reservoir sedimentation. Prediction and interpretation, “Geografiska Annaler” No. 74A, p. 93-100
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- Wilk P. (2015), Method of calculating river absorption capacity (RAC) as a tool to assess the physicochemical state of surface flowing waters, PhD thesis, IMGW-PIB (in Polish)
- Wilk P. et al. (2017), The flattening phenomenon in a seasonal variability analysis of the total nitrogen loads in river waters, “Czasopismo Techniczne” No. 11, p. 137-159
- Verma S. et al. (2015), Climate change impacts on flow, sediment and nutrient export in a Great Lakes watershed using SWAT, “CLEAN–Soil, Air, Water” No. 43(11), p. 1464-1474
- Vigiak O. et al. (2015), Adapting SWAT hillslope erosion model to predict sediment concentrations and yields in large Basins, “Science of the Total Environment” No. 538, p. 855-875
- Zeug S.C. et al. (2014), Gravel augmentation increases spawning utilization by anadromous salmonids: a case study from California, USA, “River Research and Applications” No. 30(6), p. 707-718
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-9f9f439f-bbff-46e1-8f44-0128b8b8ad61