Simulating debris flows through a hexagonal cellular automata model: SCIDDICA S&amp;lt;sub&amp;gt;3–hex&amp;lt;/sub&amp;gt;

D'Ambrosio, Donato; Gregorio, Salvatore Di; Iovine, Giulio

doi:10.5194/nhess-3-545-2003

Cited by 87 publications

(38 citation statements)

References 29 publications

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“…Debris flow entrainment modeling has been introduced into runout models using algorithms considering the properties of the debris flow (Crosta et al, 2003;D'Ambrosio et al, 2003;Medina et al, 2008). Another approach relies on user-specified erosion layer properties (Beguería et al, 2009;Hungr and McDougall, 2009;Hussin et al, 2012) where the user predefines the volume or depth of eroded sediment.…”

Section: F Frank Et Al: the Importance Of Entrainment And Bulking Omentioning

confidence: 99%

“…Physically based numerical models were developed to investigate runout distance and inundation patterns as well as flow heights and flow velocities (Crosta et al, 2003;D'Ambrosio et al, 2003;Medina et al, 2008;Hungr and McDougall, 2009;Christen et al, 2012). Only recently have researchers focused on better understanding the process by which debris flows entrain sediment from the bed of a torrent channel as part of the erosion process (e.g., Hungr et al, 2005;Mangeney et al, 2007;Berger et al, 2011;McCoy et al, 2010McCoy et al, , 2012McCoy et al, , 2013.…”

Section: Introductionmentioning

confidence: 99%

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The importance of entrainment and bulking on debris flow runout modeling: examples from the Swiss Alps

Frank

McArdell

Huggel

et al. 2015

Nat. Hazards Earth Syst. Sci.

132

137

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Abstract. This study describes an investigation of channelbed entrainment of sediment by debris flows. An entrainment model, developed using field data from debris flows at the Illgraben catchment, Switzerland, was incorporated into the existing RAMMS debris-flow model, which solves the 2-D shallow-water equations for granular flows. In the entrainment model, an empirical relationship between maximum shear stress and measured erosion is used to determine the maximum potential erosion depth. Additionally, the average rate of erosion, measured at the same field site, is used to constrain the erosion rate. The model predicts plausible erosion values in comparison with field data from highly erosive debris flow events at the Spreitgraben torrent channel, Switzerland in 2010, without any adjustment to the coefficients in the entrainment model. We find that by including bulking due to entrainment (e.g., by channel erosion) in runout models a more realistic flow pattern is produced than in simulations where entrainment is not included. In detail, simulations without entrainment show more lateral outflow from the channel where it has not been observed in the field. Therefore the entrainment model may be especially useful for practical applications such as hazard analysis and mapping, as well as scientific case studies of erosive debris flows.

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Section: F Frank Et Al: the Importance Of Entrainment And Bulking Omentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The importance of entrainment and bulking on debris flow runout modeling: examples from the Swiss Alps

Frank

McArdell

Huggel

et al. 2015

Nat. Hazards Earth Syst. Sci.

132

137

View full text Add to dashboard Cite

show abstract

“…Computational debris-flow runout models, which usually neglect entrainment, are often used to assess runout distance and pattern (Crosta et al, 2003;D'Ambrosio et al, 2003;Medina et al, 2008;Hungr and McDougall, 2009; and are therefore useful for hazard analysis where predictions of flow intensity (e.g., the spatial distribution of flow depth and velocity) are required (e.g., Scheuner et al, 2011). Because the debris-flow process has often been observed to cause significant entrainment of sediment, which can strongly influence the flow (e.g., Dietrich and Dunne, 1978;Suwa and Okuda, 1980;Gallino and Pierson, 1984;Hungr et al, 1984;Benda, 1990;Pierson et al, 1990;Meyer and Wells, 1997;Vallance and Scott, 1997;Berti et al, 1999;Cannon and Reneau, 2000;Fannin and Wise, 2001;May, 2002;Wang et al, 2003;Revellino et al, 2004;Scott et al, 2005;Godt and Coe, 2007;Breien et al, 2008;Gartner et al, 2008;Pastor et al, 2009;Guthrie et al, 2010;Procter et al, 2010;Berger et al, 2010aBerger et al, , b, 2011Schürch et al, 2011;Iverson et al, 2011;McCoy et al, 2012;Cascini et al, 2014;Tobler et al, 2014;Frank et al, 2015), including entrainment and bulking debris-flow runout modeling would be appropriate.…”

Section: Introductionmentioning

confidence: 99%

“…Because the debris-flow process has often been observed to cause significant entrainment of sediment, which can strongly influence the flow (e.g., Dietrich and Dunne, 1978;Suwa and Okuda, 1980;Gallino and Pierson, 1984;Hungr et al, 1984;Benda, 1990;Pierson et al, 1990;Meyer and Wells, 1997;Vallance and Scott, 1997;Berti et al, 1999;Cannon and Reneau, 2000;Fannin and Wise, 2001;May, 2002;Wang et al, 2003;Revellino et al, 2004;Scott et al, 2005;Godt and Coe, 2007;Breien et al, 2008;Gartner et al, 2008;Pastor et al, 2009;Guthrie et al, 2010;Procter et al, 2010;Berger et al, 2010aBerger et al, , b, 2011Schürch et al, 2011;Iverson et al, 2011;McCoy et al, 2012;Cascini et al, 2014;Tobler et al, 2014;Frank et al, 2015), including entrainment and bulking debris-flow runout modeling would be appropriate. Processed-based entrainment rates using algorithms which consider the material properties of the debrisflow bulk (Crosta et al, 2003;D'Ambrosio et al, 2003;Medina et al, 2008; as well as pre-specified entrainment rates which pre-define the absolute volume of eroded material (Beguería et al, 2009;Hungr and McDougall, 2009;Hussin et al, 2012) have been introduced in numerical runout models.…”

Section: Introductionmentioning

confidence: 99%

Debris-flow modeling at Meretschibach and Bondasca catchments, Switzerland: sensitivity testing of field-data-based entrainment model

Frank

McArdell

Oggier³

et al. 2017

Nat. Hazards Earth Syst. Sci.

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Abstract. Debris-flow volumes can increase due to the incorporation of sediment into the flow as a consequence of channel-bed erosion along the flow path. This study describes a sensitivity analysis of the recently introduced RAMMS (Rapid Mass Movements) debris-flow entrainment model, which is intended to help solve problems related to predicting the runout of debris flows. The entrainment algorithm predicts the depth and rate of erosion as a function of basal shear stress based on an analysis of erosion measurements at the Illgraben catchment, Switzerland (Frank et al., 2015). Starting with a landslide-type initiation in the RAMMS model, the volume of entrained sediment was calculated for recent well-documented debris-flow events at the Bondasca and the Meretschibach catchments, Switzerland. The sensitivity to the initial landslide volume was investigated by systematically varying the initial landslide volume and comparing the resulting debris-flow volume with estimates from the field sites. In both cases, the friction coefficients in the RAMMS runout model were calibrated using the model, whereby the entrainment module was (1) inactivated to find plausible values for general flow properties by adjusting both coefficients (ξ and µ) and then (2) activated to further refine coefficient µ, which controls erosion (patterns). The results indicate that the model predicts plausible erosion volumes in comparison with field data. By including bulking due to entrainment in runout models, more realistic runout patterns are predicted in comparison to starting the model with the entire debris-flow volume (initial landslide plus entrained sediment). In particular, lateral bank overflow -not observed during these events -is prevented when using the sediment entrainment model, even in very steep (≈ 60-65 %) and narrow (4-6 m) torrent channels. Predicted sediment entrainment volumes are sensitive to the initial landslide volume, suggesting that the model may be useful for both reconstruction of historical events and the modeling of scenarios as part of a hazard analysis.

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“…A remarkable application of the family of these CAs is presented by Truno [2] where a model is presented to simulate the evolution of forest res and Hernández Encinas et al [3] where they introduce a new mathematical model for predicting the spread of a re front in homogeneous and inhomogeneous environments. Also, in [4], debris ows are simulated and modeled by two-dimensional hexagonal cellular automata. These families of cellular automata are also applied to design discrete models of chemical reaction-diusion systems [5].…”

Section: Introductionmentioning

confidence: 99%

2-Dimensional Reversible Hexagonal Cellular Automata with Periodic Boundary

2013

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Simulating debris flows through a hexagonal cellular automata model: SCIDDICA S<sub>3–hex</sub>

Cited by 87 publications

References 29 publications

The importance of entrainment and bulking on debris flow runout modeling: examples from the Swiss Alps

The importance of entrainment and bulking on debris flow runout modeling: examples from the Swiss Alps

Debris-flow modeling at Meretschibach and Bondasca catchments, Switzerland: sensitivity testing of field-data-based entrainment model

2-Dimensional Reversible Hexagonal Cellular Automata with Periodic Boundary

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