Analysis of damaging hydrogeological events: the case of Calabria region (southern Italy)
Author(s)
Language
English
Obiettivo Specifico
1VV. Altro
Status
Published
JCR Journal
N/A or not JCR
Journal
Issue/vol(year)
43
Publisher
Springer Verlag
Pages (printed)
483-495
Date Issued
2009
Alternative Location
Abstract
A period of bad weather conditions due to prolonged intense rainfall and strong winds can trigger landslides, floods, secondary floods (accumulation of rain on surfaces with low permeability), and sea storms, causing damage to humans and infrastructure. As a whole, these periods of bad weather and triggered phenomena can be defined as damaging hydrogeological events (DHEs). We define a methodological approach based on seven simple indexes to analyze such events. The indexes describe the return period (T) and trend of rainfall, the extent of hit areas, and the level of damages; they can be considered attributes of georeferenced features and analyzed with GIS techniques. We tested our method in an Italian region frequently hit by DHEs. In a period of 10 years, 747 damaging phenomena (landslides, 43%; floods, 38%) and 94 DHEs have been classified. The road network and housing areas are the most frequently damaged elements, threatened by all types of damaging phenomena. T classes are almost in accordance with the level of damage. These results can be used to outline warning levels for civil protection purposes, to forecast the areas most likely to be hit and the potential ensuing damage, to disseminate information concerning vulnerable areas, and to increase people’s awareness of risk
References
Aleotti, P. and Polloni, G. 2005. Valutazione e mitigazione del rischio frane. ISBN-13: 9788886977517 Hevelius, Benevento (Italy).
Barnikel, F. and Becht, M. 2003. A historical analysis of hazardous events in the Alps – the case of Hindelang (Bavaria, Germany). Natural Hazards and Earth System Sciences, 3: 625-635.
Barrera, A., Barriendos, M., and Llasat, M. C. 2005. Extreme flash floods in Barcelona County. Adv. Geosci., 2, 111–116, 2005, http://www.adv-geosci.net/2/111/2005/.
Blong, R. 2003. A review of damage intensity scales. Natural Hazards and Earth System Sciences, 29: 57-76.
Calcaterra, D., Parise, M. and Palma, B. 2003. Combining historical and geological data for the assessment of the landslide hazard: a case study from Campania, Italy. Natural Hazards and Earth System Sciences, 3, 3-16.
Carrara, A., Crosta, G., and Frattini, P. 2003. Geomorphological and historical data in assessing landslide hazard. Earth Surf. Process. Landforms, 28, 1125–1142.
Crozier, M. 1986. Climatic triggering of landslide episodes. Landslides: causes, consequences and environment. Croom Helm: 169-192.
Cruden, D.M. 1997. Estimating the risks from landslides using historical data. In: Landslide Risk Assessment; Proceedings of the International Workshop, Cruden, D.M. and Fell, R. (eds). Balkema: 177-184.
Cuesta, M.J.D., Sanchez, M.J. and Garcia, A.R. 1999. Press archives as temporal records of landslides in the North of Spain: relationships between rainfall and instability slope events, Geomorphology, 30: 125–132.
Devoli, G. Morales, A. Høeg, K. 2007. Historical landslides in Nicaragua—collection and analysis of data, Landslides 4: 5-18.
Dore, M.H.I. 2003. Forecasting the Conditional Probabilities of Natural Disasters in Canada as a Guide for Disaster Preparedness. Natural Hazards and Earth System Sciences, 28: 249-269.
Dwyer, A. Zoppou, C. Nielsen, O., Day, S. and Roberts, S. 2004. Quantifying social vulnerability: a methodology for identifying those at risk to natural hazards, Australian Government, Record 14.
Dwyer, A. 2003. Programming solutions for community risk. AusGEO News, 70, 37-40.
Etkin, D. 1999. Risk transference and related trends: driving forces towards more mega-disasters. Global Environmental Change Part B: Environmental Hazards, 1(2), 51-92.
Fairbridge, R.W. 1968. The encyclopedia of geomorphology. Reinhold, New York.
Flageollet, J.C., Maquaire, O., Martin, B., Weber, D. 1999. Landslides and climatic conditions in the Barcelonette and Vars basins (Southern French Alps, France). Geomorphology, 30: 65-78.
Glade, T. 2001. Landslide hazard assessment and historical landslide data - an inseparable couple? In: Glade, T., Albini, P. and Frances, F. (eds.): The use of historical data in natural hazard assessments. Advances of Technological and Natural Hazard Research, Kluwer, 153-169.
Glade, T., Albini, P. and Frances, F. 2001. An introduction to the use of historical data in natural hazard assessments. In: Glade, T., Albini, P., Frances, F. (eds.). The Use of Historical Data in Natural Hazards Assessment, Advances in Natural and Technological Hazards Research, 17, Kluwer, XVII-XXV.
Glaser, R. and Stangl, H. 2003. Historical floods in the Dutch Rhine Delta. Natural Hazards and Earth System Sciences, 3, 605-613.
Glaser, R. and Stangl, H. 2004. Climate and floods in central Europe since ad 1000: data, methods, results and consequences. Surveys in Geophysics 25: 485–510, Kluwer Academic Publishers, Netherlands.
Guzzetti, F. 2000. Landslide fatalities and the evaluation of landslide risk in Italy. Engineering Geology, 58, 89-107.
Hosking, J.R.M. 1986. The theory of probability-weighted moments. IBM Math., Research Report RC12210. Yorktown Heights, New York, 160 pp.
Ibbeken, H. and Schleyer, R. 1991. Source and sediment, a case study of provenance and mass balance at an active plate margin (Calabria). Springer Verlag, 286 pp.
Ibsen, M. L. and Brunsden, D. 1996. The nature, use and problems of historical archives for the temporal occurrence of landslides, with specific reference to the south coast of Britain, Ventnor, Isle of Wight, Geomorphology 15, 241-258.
I.F.R.C. (International Federation of Red Cross) 2001. World disasters report - Focus on recovery, ISBN 92-9139-075-5, Edited by J. Walter, SADAG, Bellegarde-Valserine, France.
Iovine, G., Petrucci, O., Rizzo, V. and Tansi, C. 2006. The March 7th 2005 Cavallerizzo (Cerzeto) landslide in Calabria - Southern Italy. Engineering geology for tomorrow's cities. The 10th IAEG Congress, Nottingham, United Kingdom, 6-10 September 2006.
ISTAT (Istituto Nazionale di Statistica) 2003. Bilancio demografico nazionale: Calabria. http://www.istat.it/salastampa/comunicati/non_calendario/20040726_01/calabria.pdf.
Jenkinson, A.F. 1955. The frequency distribution of the annual maximum (or minimum) values of meteorological elements. Quarterly Journal of the Royal Meteorological Society, 81: 158-171.
Ogniben, L. 1973. Schema geologico della Calabria in base ai dati odierni, Geol. Romana, 12, 243-585.
Petrucci, O. and Polemio, M. 2002. Hydro-geologic multiple hazard: a characterisation based on the use of meteorological and geomorphological data - 1st European Conference on Landslides, 24–26 June 2002, Prague, Czech Republic. Rybar, Stemberk and Wagner eds, Balkema Publishers, 269-274.
Petrucci, O. and Polemio, M. 2007. Ricorrenza degli eventi alluvionali, dissesto idrogeologico e trend climatico nella Locride (Calabria SE), In: Clima e cambiamenti climatici: le attività di ricerca del CNR, B. Carli, G. Cavarretta, M. Colacino and S. Fuzzi eds, CNR, ISBN 978-88-8080-075-0, 747-750, Roma.
Petrucci, O. and Polemio, M. 2003. The use of historical data for the characterisation of multiple damaging hydrogeological events, Natural Hazards and Earth System Sciences, 3: 17-30.
Petrucci, O., De Matteis, V. and Versace, P. 2003. Aspetti metodologici nella identificazione dell’impatto al suolo degli eventi alluvionali, Atti del Convegno Nazionale: La Difesa della Montagna, Pub. GNDCI N. 2830, 522-530.
Rossi, F. and Versace, P. 1982. Criteri e metodi per l'analisi statistica delle piene. Valutazione delle piene. C.N.R.-Progetto Finalizzato Conservazione del Suolo n.165, 63-130.
Sorriso-Valvo, M., Antronico, L., Gaudio, R., Gullà, G., Iovine, G., Merenda, G., Minervino, I., Nicoletti, P.G., Petrucci, O. and Terranova, O. 2004. Carta dei dissesti causati in Calabria meridionale dall'evento meteorologico dell'8-10 settembre 2000, CNR-GNDCI, Pub. N. 2859, Geodata N. 45, Rubbettino, Soveria Mannelli, Catanzaro (Italy).
Tortorici, L. 1982. Lineamenti geologico-strutturali dell'Arco Calabro-Peloritano: Rendiconti della Società Italiana di Mineralogia e Petrologia, V.38.
Versace, P., Ferrari, E., Gabriele, S. and Rossi, F. 1989. Valutazione delle piene in Calabria, CNR-IRPI, Rende, Cosenza (Italy), Geodata N. 30.
Wieczorek, G.F. and Jäger, S. 1996. Triggering mechanisms and depositional rates of postglacial slope-movements processes in the Yosemite Valley, California. Geomorphology, 15: 17-31.
Barnikel, F. and Becht, M. 2003. A historical analysis of hazardous events in the Alps – the case of Hindelang (Bavaria, Germany). Natural Hazards and Earth System Sciences, 3: 625-635.
Barrera, A., Barriendos, M., and Llasat, M. C. 2005. Extreme flash floods in Barcelona County. Adv. Geosci., 2, 111–116, 2005, http://www.adv-geosci.net/2/111/2005/.
Blong, R. 2003. A review of damage intensity scales. Natural Hazards and Earth System Sciences, 29: 57-76.
Calcaterra, D., Parise, M. and Palma, B. 2003. Combining historical and geological data for the assessment of the landslide hazard: a case study from Campania, Italy. Natural Hazards and Earth System Sciences, 3, 3-16.
Carrara, A., Crosta, G., and Frattini, P. 2003. Geomorphological and historical data in assessing landslide hazard. Earth Surf. Process. Landforms, 28, 1125–1142.
Crozier, M. 1986. Climatic triggering of landslide episodes. Landslides: causes, consequences and environment. Croom Helm: 169-192.
Cruden, D.M. 1997. Estimating the risks from landslides using historical data. In: Landslide Risk Assessment; Proceedings of the International Workshop, Cruden, D.M. and Fell, R. (eds). Balkema: 177-184.
Cuesta, M.J.D., Sanchez, M.J. and Garcia, A.R. 1999. Press archives as temporal records of landslides in the North of Spain: relationships between rainfall and instability slope events, Geomorphology, 30: 125–132.
Devoli, G. Morales, A. Høeg, K. 2007. Historical landslides in Nicaragua—collection and analysis of data, Landslides 4: 5-18.
Dore, M.H.I. 2003. Forecasting the Conditional Probabilities of Natural Disasters in Canada as a Guide for Disaster Preparedness. Natural Hazards and Earth System Sciences, 28: 249-269.
Dwyer, A. Zoppou, C. Nielsen, O., Day, S. and Roberts, S. 2004. Quantifying social vulnerability: a methodology for identifying those at risk to natural hazards, Australian Government, Record 14.
Dwyer, A. 2003. Programming solutions for community risk. AusGEO News, 70, 37-40.
Etkin, D. 1999. Risk transference and related trends: driving forces towards more mega-disasters. Global Environmental Change Part B: Environmental Hazards, 1(2), 51-92.
Fairbridge, R.W. 1968. The encyclopedia of geomorphology. Reinhold, New York.
Flageollet, J.C., Maquaire, O., Martin, B., Weber, D. 1999. Landslides and climatic conditions in the Barcelonette and Vars basins (Southern French Alps, France). Geomorphology, 30: 65-78.
Glade, T. 2001. Landslide hazard assessment and historical landslide data - an inseparable couple? In: Glade, T., Albini, P. and Frances, F. (eds.): The use of historical data in natural hazard assessments. Advances of Technological and Natural Hazard Research, Kluwer, 153-169.
Glade, T., Albini, P. and Frances, F. 2001. An introduction to the use of historical data in natural hazard assessments. In: Glade, T., Albini, P., Frances, F. (eds.). The Use of Historical Data in Natural Hazards Assessment, Advances in Natural and Technological Hazards Research, 17, Kluwer, XVII-XXV.
Glaser, R. and Stangl, H. 2003. Historical floods in the Dutch Rhine Delta. Natural Hazards and Earth System Sciences, 3, 605-613.
Glaser, R. and Stangl, H. 2004. Climate and floods in central Europe since ad 1000: data, methods, results and consequences. Surveys in Geophysics 25: 485–510, Kluwer Academic Publishers, Netherlands.
Guzzetti, F. 2000. Landslide fatalities and the evaluation of landslide risk in Italy. Engineering Geology, 58, 89-107.
Hosking, J.R.M. 1986. The theory of probability-weighted moments. IBM Math., Research Report RC12210. Yorktown Heights, New York, 160 pp.
Ibbeken, H. and Schleyer, R. 1991. Source and sediment, a case study of provenance and mass balance at an active plate margin (Calabria). Springer Verlag, 286 pp.
Ibsen, M. L. and Brunsden, D. 1996. The nature, use and problems of historical archives for the temporal occurrence of landslides, with specific reference to the south coast of Britain, Ventnor, Isle of Wight, Geomorphology 15, 241-258.
I.F.R.C. (International Federation of Red Cross) 2001. World disasters report - Focus on recovery, ISBN 92-9139-075-5, Edited by J. Walter, SADAG, Bellegarde-Valserine, France.
Iovine, G., Petrucci, O., Rizzo, V. and Tansi, C. 2006. The March 7th 2005 Cavallerizzo (Cerzeto) landslide in Calabria - Southern Italy. Engineering geology for tomorrow's cities. The 10th IAEG Congress, Nottingham, United Kingdom, 6-10 September 2006.
ISTAT (Istituto Nazionale di Statistica) 2003. Bilancio demografico nazionale: Calabria. http://www.istat.it/salastampa/comunicati/non_calendario/20040726_01/calabria.pdf.
Jenkinson, A.F. 1955. The frequency distribution of the annual maximum (or minimum) values of meteorological elements. Quarterly Journal of the Royal Meteorological Society, 81: 158-171.
Ogniben, L. 1973. Schema geologico della Calabria in base ai dati odierni, Geol. Romana, 12, 243-585.
Petrucci, O. and Polemio, M. 2002. Hydro-geologic multiple hazard: a characterisation based on the use of meteorological and geomorphological data - 1st European Conference on Landslides, 24–26 June 2002, Prague, Czech Republic. Rybar, Stemberk and Wagner eds, Balkema Publishers, 269-274.
Petrucci, O. and Polemio, M. 2007. Ricorrenza degli eventi alluvionali, dissesto idrogeologico e trend climatico nella Locride (Calabria SE), In: Clima e cambiamenti climatici: le attività di ricerca del CNR, B. Carli, G. Cavarretta, M. Colacino and S. Fuzzi eds, CNR, ISBN 978-88-8080-075-0, 747-750, Roma.
Petrucci, O. and Polemio, M. 2003. The use of historical data for the characterisation of multiple damaging hydrogeological events, Natural Hazards and Earth System Sciences, 3: 17-30.
Petrucci, O., De Matteis, V. and Versace, P. 2003. Aspetti metodologici nella identificazione dell’impatto al suolo degli eventi alluvionali, Atti del Convegno Nazionale: La Difesa della Montagna, Pub. GNDCI N. 2830, 522-530.
Rossi, F. and Versace, P. 1982. Criteri e metodi per l'analisi statistica delle piene. Valutazione delle piene. C.N.R.-Progetto Finalizzato Conservazione del Suolo n.165, 63-130.
Sorriso-Valvo, M., Antronico, L., Gaudio, R., Gullà, G., Iovine, G., Merenda, G., Minervino, I., Nicoletti, P.G., Petrucci, O. and Terranova, O. 2004. Carta dei dissesti causati in Calabria meridionale dall'evento meteorologico dell'8-10 settembre 2000, CNR-GNDCI, Pub. N. 2859, Geodata N. 45, Rubbettino, Soveria Mannelli, Catanzaro (Italy).
Tortorici, L. 1982. Lineamenti geologico-strutturali dell'Arco Calabro-Peloritano: Rendiconti della Società Italiana di Mineralogia e Petrologia, V.38.
Versace, P., Ferrari, E., Gabriele, S. and Rossi, F. 1989. Valutazione delle piene in Calabria, CNR-IRPI, Rende, Cosenza (Italy), Geodata N. 30.
Wieczorek, G.F. and Jäger, S. 1996. Triggering mechanisms and depositional rates of postglacial slope-movements processes in the Yosemite Valley, California. Geomorphology, 15: 17-31.
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