On integrated sediment transport modelling for flash events in mountain environments

Czasopismo : Acta Geophysica
Tytuł artykułu : On integrated sediment transport modelling for flash events in mountain environments

Autorzy :
Yamasaki, K.
Department of Earth and Planetary Sciences, Faculty of Science, Kobe University, Nada, Kobe, Japan, yk2000@kobe-u.ac.jp,
Teisseyre, R.
Institute of Geophysics, Polish Academy of Sciences, Warszawa, Poland, rt@igf.edu.pl,
Li, C.
School of Computer Engineering and Science, Shanghai University, Shanghai, China, jyyin@staff.shu.edu.cn,
Majdański, M.
Institute of Geophysics, Polish Academy of Sciences, Warszawa, Poland, mmajd@igf.edu.pl,
Trojanowski, J.
Institute of Geophysics, Polish Academy of Sciences, Warszawa, Poland, jtroj@igf.edu.pl,
Öztürk, S.
Gümüşhane University, Department of Geophysics, Gümüşhane, Turkey, serkanozturk@gumushane.edu.tr,
Chattopadhyay, A.
Department of Applied Mathematics, Indian School of Mines, Dhanbad, India, amares.c@gmail.com,
Beziuk, G.
Wroclaw University of Technology, Institute of Telecommunications and Acoustics, Wrocław, Poland, grzegorz.beziuk@pwr.wroc.pl,
Giang, N.V.
Institute of Geophysics, VAST, Hanoi, Vietnam, nvgiang189@yahoo.com,
Di Cristo, C.
Dipartimento di Meccanica, Strutture, Ambiente e Territorio, Universita` di Cassino, Cassino, Italy, dicristo@unicas.it,
Radice, A.
Dipartimento di Meccanica, Strutture, Ambiente e Territorio, Universita` di Cassino, Cassino, Italy, dicristo@unicas.it,
Abstrakty : Sediment production and transport in mountain basins during short-term, intense events depend on a variety of processes. Available models typically consider a limited portion of the phenomenological chain, frequently either sediment supply or solid transport along the waterways. On the other hand, proper depiction of on-site processes requires ability to model all the process stages and suitable integration between different models. In this manuscript, an integrated modelling is attempted for small catchments in Italian Alpine foothills. The integrated approach has involved: (i) hydrologic estimation of peak discharge, (ii) evaluation of the volumetric sediment supply into the stream, and (iii) computation of the morphologic evolution of the river bed. The results are discussed focussing on: (i) the feasibility of a joint modelling like the one presented, in the light of all the limitations imposed by the different nature of hillslope-devoted and river-devoted models; and (ii) the sensitivity of the obtained results to some parameters, for an assessment of result reliability.

Słowa kluczowe : mountain basins, sediment supply, fluvial sediment transport, morphologic evolution,
Wydawnictwo : Instytut Geofizyki PAN
Rocznik : 2012
Numer : Vol. 60, no. 1
Strony : 191 – 213
Bibliografia : Arnold, J.G., J.R. Wiliams, and D.R. Maidment (1995), Continuous-time water and sediment-routing model for large basins, J. Hydraul. Eng. 121, 2, 171-183.
Bemporad, G.A., J. Alterach, F.F. Amighetti, M. Peviani, and I. Saccardo (1997), A distributed approach for sediment yield evaluation in Alpine regions, J. Hydrol. 197, 1-4, 370-392.
Brambilla, D., L. Longoni, M. Papini, E. Giorgetti, and A. Radice (2011), On analysis of sediment sources towards proper characterization of hydro-geological risk for mountain environments, Int. J. Safety and Security Eng. (in print).
Ceriani, M., G. Crosta, P. Frattini, and S. Quattrini (2000), Evaluation of hydrogeological hazard on alluvial fans, Proc. Int. Symp INTERPRAEVENT 2000, Villach, Austria, Vol. 2, 213-225.
Chiari, M., K. Friedl, and D. Rickenmann (2010), A one-dimensional bedload transport model for steep slopes, J. Hydraul. Res. 48, 2, 152-160.
Chikita, K. (1990), Sedimentation by river-induced turbudity currents: field measurements and interpretation, Sedimentology 37, 5, 891-905.
Cohen, H., J.B. Laronne, and I. Reid (2010), Simplicity and complexity of bed load response during flash floods in a gravel bed ephemeral river: a 10 year field study, Water Resour. Res. 46, W11542.
D’Agostino, V., M. Cerato, and R. Coali (1996), Extreme events of sediment transport in the eastern Trentino torrents, Proc. Int. Symp INTERPRAEVENT 1996, Vol. 1, 377-386.
De Cesare, G., A. Schleiss, and F. Hermann (2001), Impact of turbidity currents on reservoir sedimentation, J. Hydraul. Eng. 127, 1, 6-16.
De Vente, J., and J. Poesen (2005), Predicting soil erosion and sediment yield at the basin scale: Scale issues and semi-quantitative models, Earth-Sci. Rev. 71, 1-2, 95-125.
Elçi, S., P.A. Work, and E.J. Hayter (2007), Influence of stratification and shoreline erosion on reservoir sedimentation patterns, J. Hydraul. Eng. 133, 3, 255-266.
Fäh, R., R. Müller, P. Rousselot, D. Vetsch, C. Volz, L. Vonwiller, R. Veprek, and D. Farshi (2010), Basement reference manual, available at www.basement.ethz.ch.
Ferguson, R., T. Hoey, S. Wathen, and A. Werritty (1996), Field evidence for rapid downstream fining of river gravels through selective transport, Geology 24, 2, 179-182.
Garcia, C., H. Cohen, I. Reid, A. Rovira, X. Úbeda, and J.B. Laronne (2007), Processes of initiation of motion leading to bedload transport in gravel-bed rivers, Geophys. Res. Lett. 34, L06403.
Giandotti, M. (1934), Previsione delle piene e delle magre dei corsi d’acqua, Memorie e studi idrografici, Pubbl. 2 del Servizio Idrografico Italiano 8, 107 (in Italian).
Gomez, B., and M. Church (1989), An assessment of bed load sediment transport formulae for gravel bed rivers, Water Resour. Res. 25, 6, 1161-1186.
Gomez, B., B.J. Rosser, D.H. Peacock, D.M. Hicks, and J.A. Palmer (2001), Downstream fining in a rapidly aggrading gravel bed river, Water Resour. Res. 37, 6, 1813-1823.
Hampel, R. (1977), Geschiebewirtschaft in Wildbächen, Wildbach und Lawinenverbau 41, 1, 3-34 (in German).
Jaeggi, M. (2008), Some aspects of the sediment transport during the 2005 floods in Switzerland, Ann. Warsaw Univ. of Life Sci. – SGGW, Land Reclam. 39, 33-48.
Jain, M.K., U.C. Kothyari, and K.G. Ranga Raju (2005), GIS based distributed model for soil erosion and rate of sediment outflow from catchments, J. Hydraul. Eng. 131, 9, 755-769.
Klaassen, G.J. (1997), FRIMAR: Flooding risks in mountain areas, available AT http://www.hrwallingford.co.uk/Mitch/papers/klaassen.pdf.
Krysanova, V., F. Hattermann, and F. Wechsung (2005), Development of the ecohydrological model SWIM for regional impact studies and vulnerability assessment, Hydrol. Process. 19, 3, 763-783.
Lajczak, A. (1996), Modelling the long-term course of non-flushed reservoir sedimentation and estimating the life of dams, Earth Surf. Proc. Land. 21, 12, 1091-1107.
Lenzi, M.A. (2001), Step-pool evolution in the Rio Cordon, northeastern Italy, Earth Surf. Proc. Land. 26, 9, 991-1008.
Lenzi, M.A., and L. Marchi (2000), Suspended sediment load during floods in a small stream of the Dolomites (northeastern Italy), Catena 39, 4, 267-282.
Lenzi, M.A., V. D’Agostino, and P. Billi (1999), Bedload transport in the instrumentem catchment of the Rio Cordon. Part I: Analysis of bedload records, conditions and threshold of bedload entrainment, Catena 36, 3, 171-190.
Lenzi, M.A., L. Mao, and F. Comiti (2003), Interannual variation of suspended sediment load and sediment yield in an alpine catchment, Hydrolog. Sci. J. 48, 6, 899-915.
Lenzi, M.A., L. Mao, and F. Comiti (2004), Magnitude-frequency analysis of Bed load data in an Alpine boulder bed stream, Water Resour. Res. 40, W07201.
Lenzi, M.A., L. Mao, and F. Comiti (2006), When does bedload transport begin in steep boulder-bed streams?, Hydrol. Proc. 20, 16, 3517-3533.
Lisle, T.E., Y. Cui, G. Parker, J.E. Pizzuto, and A.M. Dodd (2001), The dominancie of dispersion in the evolution of bed material waves in gravel-bed rivers, Earth Surf. Proc. Land. 26, 13, 1409-1420.
Madej, M.A., and V. Ozaki (1996), Channel response to sediment wave propagation and movement, Redwood Creek, California, USA, Earth Surf. Proc. Land. 21, 10, 911-927.
Mandelli, M., L. Longoni, M. Papini, F. Roncoroni, and A. Radice (2009), Modellazione del trasporto di sedimenti sul bacino del Tartano (Valtellina), GEAM 46, 2, 53-64 (in Italian).
Mao, L., and M.A. Lenzi (2007), Sediment mobility and bedload transport conditions in an alpine stream, Hydrol. Process. 21, 14, 1882-1891.
Mao, L., G.P. Uyttendaele, A. Iroumé, and M.A. Lenzi (2008), Field based analysis of sediment entrainment in two high gradient streams located in Alpine and Andine environments, Geomorphology 93, 3-4, 368-383.
Mao, L., M. Cavalli, F. Comiti, L. Marchi, M.A. Lenzi, and M. Arattano (2009), Sediment transfer processes in two Alpine catchments of contrasting morphological settings, J. Hydrol. 364, 1-2, 88-98.
Marchi, L., and P.R. Tecca (1996), Magnitudo delle collate detritiche nelle Alpi Orientali Italiane, GEAM 33, 2, 79-86 (in Italian).
Martin, Y. (2003), Evaluation of bed load transport formulae using field evidence from the Vedder River, British Columbia, Geomorphology 53, 1-2, 75-95.
Meyer-Peter, E., and R. Müller (1948), Formulas for bed-load transport, Proc. 2nd Meeting of IAHR, Stockholm, Sweden.
Milzow, C., P. Molnar, B.W. McArdell, and P. Burlando (2006), Spatial organization in the step-pool structure of a steep mountain stream (Vogelbach, Switzerland), Water Resour. Res. 42, W04418.
Montgomery, D.R., and J.M. Buffington (1997), Channel-reach morphology in mountain drainage basins, Bull. Geol. Soc. Am. 109, 5, 596-611.
Owczarek, P. (2008), Hillslope deposits in gravel-bed rivers and their effects on the evolution of alluvial channel forms: A case study from the Sudetes and Carpathian Mountains, Geomorphology 98, 1-2, 111-125.
Paola, C., G. Parker, R. Seal, S.K. Sinha, J.B. Southard, and P.R. Wilcock (1992), Downstream fining by selective deposition in a laboratory flume, Science 258, 5089, 1757-1760.
Papanicolaou, A.N., A. Bdour, and E. Wicklein (2004), One-dimensional hydrodynamic/ sediment transport model applicable to steep mountain streams, J. Hydraul. Res. 42, 4, 357-375.
Reid, S.C., S.N. Lane, J.M. Berney, and J. Holden (2007), The timing and magnitude of coarse sediment transport events within an upland, tempera te gravel-bed river, Geomorphology 83, 1-2, 152-182.
Rickenmann, D. (1995), Beurteilung von Murgängen, Schweizer Ingenieur und Architekt 48, 1104-1108 (in German).
Rickenmann, D. (1997), Sediment transport in Swiss torrents, Earth Surf. Proc. Land. 22, 10, 937-951.
Rickenmann, D. (2001), Comparison of bed load transport in torrents and gravel bed streams, Water Resour. Res. 37, 12, 3295-3305.
Rickenmann, D., and A. Koschni (2010), Sediment loads due to fluvial transport and debris flows during the 2005 flood events in Switzerland, Hydrol. Proc. 24, 8, 993-1007.
Rickenmann, D., and M. Zimmermann (1993), The 1987 debris flows in Switzerland: documentation and analysis, Geomorphology 8, 2-3, 175-189.
Seal, R., C. Paola, G. Parker, J.B. Southard, and P.R. Wilcock (1997), Experiments on downstream fining of gravel: I. Narrow-channel runs, J. Hydraul. Eng. 123, 10, 874-884.
Shields, A. (1936), Application of Similarity Principles and Turbulence Research to Bed-Load Movement, Mitteilungen der Preussischen Versuchsanstalt für Wasserbau und Schiffbau, Tech. Hochsch., Berlin, Germany (in German).
Sklar, L.S., J. Fadde, J.G. Venditti, P. Nelson, M.A. Wydzga, Y. Cui, and W.E. Dietrich (2009), Translation and dispersion of sediment pulses in flume experiments simulating gravel augmentation below dams, Water Resour. Res. 45, W08439.
Takei, A. (1984), Interdependence of sediment budget between individual torrents and a river-system, Proc. Int. Symp. INTERPRAEVENT, Villach, Austria, Vol. 2, 35-48.
Turowski, J.M., E.M. Yager, A. Badoux, D. Rickenmann, and P. Molnar (2009), The impact of exceptional events on erosion, bedload transport and channel stability in a step-pool channel, Earth Surf. Proc. Land. 34, 12, 1661-1673.
Turowski, J.M., D. Rickenmann, and S.J. Dadson (2010), The partitioning of the Total sediment load of a river into suspended load and bedload: A review of empirical data, Sedimentology 57, 4, 1126-1146.
Van Rompaey, A., P. Bazzoffi, R.J.A. Jones, and L. Montanarella (2005), Modeling sediment yields in Italian catchments, Geomorphology 65, 1-2, 157-169.
Wang, G., P. Hapuarachchi, H. Ishidaira, A.S. Kiem, and K. Takeuchi (2009), Estimation of soil erosion and sediment yield during individual rainstorms AT catchment scale, Water Resour. Manag. 23, 8, 1447-1465.
Warren, S.D., H. Mitasova, M.G. Hohmann, S. Landsberger, F.Y. Iskander, T.S. Ruzycki, and G.M. Senseman (2005), Validation of a 3-D enhancement of the Universal Soil Loss Equation for prediction of soil erosion and sedyment deposition, Catena 64, 2-3, 281-296.
Wilcock, P.R. (1998), Two-fraction model of initial sediment motion in gravel-bed rivers, Science 280, 5362, 410-412.
Wilcox, A.C., E.E. Wohl, F. Comiti, and L. Mao (2011), Hydraulics, morphology, and energy dissipation in an alpine step-pool channel, Water Resour. Res. 47, W07514.
Williams, J.R., and H.D. Berndt (1975), Sediment yield prediction with Universal equation using runoff energy factor. In: Present and Prospective Technology for Predicting Sediment Yield and Sources, USDA, ARS-S-40, 244-252.
Wright, S.A., D.J. Topping, D.M. Rubin, and T.S. Melis (2010), An approach for modeling sediment budgets in supply-limited rivers, Water Resour. Res. 46, W10538.
Cytuj : Yamasaki, K. ,Teisseyre, R. ,Li, C. ,Majdański, M. ,Trojanowski, J. ,Öztürk, S. ,Chattopadhyay, A. ,Beziuk, G. ,Giang, N.V. ,Di Cristo, C. ,Radice, A. , On integrated sediment transport modelling for flash events in mountain environments. Acta Geophysica Vol. 60, no. 1/2012