Learning Case Study of a Shallow-Water Model to Assess an Early-Warning System for Fast Alpine Muddy-Debris-Flow

The current climate change could lead to an intensification of extreme weather events, such as sudden floods and fast flowing debris flows. Accordingly, the availability of an early-warning device system, based on hydrological data and on both accurate and very fast running mathematical-numerical mo...

Full description

Bibliographic Details
Main Authors: Antonio Pasculli, Jacopo Cinosi, Laura Turconi, Nicola Sciarra
Format: Article
Language:English
Published: MDPI AG 2021-03-01
Series:Water
Subjects:
Online Access:https://www.mdpi.com/2073-4441/13/6/750
id doaj-3ee7996ad4ab4f44ae026b74e9b222d3
record_format Article
spelling doaj-3ee7996ad4ab4f44ae026b74e9b222d32021-03-11T00:05:12ZengMDPI AGWater2073-44412021-03-011375075010.3390/w13060750Learning Case Study of a Shallow-Water Model to Assess an Early-Warning System for Fast Alpine Muddy-Debris-FlowAntonio Pasculli0Jacopo Cinosi1Laura Turconi2Nicola Sciarra3Department of Engineering and Geology, University of “G. D’Annunzio”, Chieti-Pescara, 66013 Chieti, ItalyDepartment of Engineering and Geology, University of “G. D’Annunzio”, Chieti-Pescara, 66013 Chieti, ItalyNational Research Council (CNR), Research Institute for the Hydrogeological Protection (IRPI), 10135 Torino, ItalyDepartment of Engineering and Geology, University of “G. D’Annunzio”, Chieti-Pescara, 66013 Chieti, ItalyThe current climate change could lead to an intensification of extreme weather events, such as sudden floods and fast flowing debris flows. Accordingly, the availability of an early-warning device system, based on hydrological data and on both accurate and very fast running mathematical-numerical models, would be not only desirable, but also necessary in areas of particular hazard. To this purpose, the 2D Riemann–Godunov shallow-water approach, solved in parallel on a Graphical-Processing-Unit (GPU) (able to drastically reduce calculation time) and implemented with the RiverFlow2D code (version 2017), was selected as a possible tool to be applied within the Alpine contexts. Moreover, it was also necessary to identify a prototype of an actual rainfall monitoring network and an actual debris-flow event, beside the acquisition of an accurate numerical description of the topography. The Marderello’s basin (Alps, Turin, Italy), described by a 5 × 5 m Digital Terrain Model (DTM), equipped with five rain-gauges and one hydrometer and the muddy debris flow event that was monitored on 22 July 2016, were identified as a typical test case, well representative of mountain contexts and the phenomena under study. Several parametric analyses, also including selected infiltration modelling, were carried out in order to individuate the best numerical values fitting the measured data. Different rheological options, such as Coulomb-Turbulent-Yield and others, were tested. Moreover, some useful general suggestions, regarding the improvement of the adopted mathematical modelling, were acquired. The rapidity of the computational time due to the application of the GPU and the comparison between experimental data and numerical results, regarding both the arrival time and the height of the debris wave, clearly show that the selected approaches and methodology can be considered suitable and accurate tools to be included in an early-warning system, based at least on simple acoustic and / or light alarms that can allow rapid evacuation, for fast flowing debris flows.https://www.mdpi.com/2073-4441/13/6/750numerical modellingmuddy flowshallow waterparametric sensitivity analysesrheological lawsGPU approach
collection DOAJ
language English
format Article
sources DOAJ
author Antonio Pasculli
Jacopo Cinosi
Laura Turconi
Nicola Sciarra
spellingShingle Antonio Pasculli
Jacopo Cinosi
Laura Turconi
Nicola Sciarra
Learning Case Study of a Shallow-Water Model to Assess an Early-Warning System for Fast Alpine Muddy-Debris-Flow
Water
numerical modelling
muddy flow
shallow water
parametric sensitivity analyses
rheological laws
GPU approach
author_facet Antonio Pasculli
Jacopo Cinosi
Laura Turconi
Nicola Sciarra
author_sort Antonio Pasculli
title Learning Case Study of a Shallow-Water Model to Assess an Early-Warning System for Fast Alpine Muddy-Debris-Flow
title_short Learning Case Study of a Shallow-Water Model to Assess an Early-Warning System for Fast Alpine Muddy-Debris-Flow
title_full Learning Case Study of a Shallow-Water Model to Assess an Early-Warning System for Fast Alpine Muddy-Debris-Flow
title_fullStr Learning Case Study of a Shallow-Water Model to Assess an Early-Warning System for Fast Alpine Muddy-Debris-Flow
title_full_unstemmed Learning Case Study of a Shallow-Water Model to Assess an Early-Warning System for Fast Alpine Muddy-Debris-Flow
title_sort learning case study of a shallow-water model to assess an early-warning system for fast alpine muddy-debris-flow
publisher MDPI AG
series Water
issn 2073-4441
publishDate 2021-03-01
description The current climate change could lead to an intensification of extreme weather events, such as sudden floods and fast flowing debris flows. Accordingly, the availability of an early-warning device system, based on hydrological data and on both accurate and very fast running mathematical-numerical models, would be not only desirable, but also necessary in areas of particular hazard. To this purpose, the 2D Riemann–Godunov shallow-water approach, solved in parallel on a Graphical-Processing-Unit (GPU) (able to drastically reduce calculation time) and implemented with the RiverFlow2D code (version 2017), was selected as a possible tool to be applied within the Alpine contexts. Moreover, it was also necessary to identify a prototype of an actual rainfall monitoring network and an actual debris-flow event, beside the acquisition of an accurate numerical description of the topography. The Marderello’s basin (Alps, Turin, Italy), described by a 5 × 5 m Digital Terrain Model (DTM), equipped with five rain-gauges and one hydrometer and the muddy debris flow event that was monitored on 22 July 2016, were identified as a typical test case, well representative of mountain contexts and the phenomena under study. Several parametric analyses, also including selected infiltration modelling, were carried out in order to individuate the best numerical values fitting the measured data. Different rheological options, such as Coulomb-Turbulent-Yield and others, were tested. Moreover, some useful general suggestions, regarding the improvement of the adopted mathematical modelling, were acquired. The rapidity of the computational time due to the application of the GPU and the comparison between experimental data and numerical results, regarding both the arrival time and the height of the debris wave, clearly show that the selected approaches and methodology can be considered suitable and accurate tools to be included in an early-warning system, based at least on simple acoustic and / or light alarms that can allow rapid evacuation, for fast flowing debris flows.
topic numerical modelling
muddy flow
shallow water
parametric sensitivity analyses
rheological laws
GPU approach
url https://www.mdpi.com/2073-4441/13/6/750
work_keys_str_mv AT antoniopasculli learningcasestudyofashallowwatermodeltoassessanearlywarningsystemforfastalpinemuddydebrisflow
AT jacopocinosi learningcasestudyofashallowwatermodeltoassessanearlywarningsystemforfastalpinemuddydebrisflow
AT lauraturconi learningcasestudyofashallowwatermodeltoassessanearlywarningsystemforfastalpinemuddydebrisflow
AT nicolasciarra learningcasestudyofashallowwatermodeltoassessanearlywarningsystemforfastalpinemuddydebrisflow
_version_ 1724226219716640768