TITAN2F code for lahar hazard assessment: derivation, validation and verification

Córdoba, Gustavo; Sheridan, M. F.; Pitman, B.

doi:10.18268/bsgm2018v70n3a3

Cited by 6 publications

(8 citation statements)

References 61 publications

(116 reference statements)

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“…Forecasting debris-flow speeds and inundation areas commonly entails the use of physically based, deterministic flow dynamic simulations (Iverson, 2014). Models that describe flow mechanics can incorporate probabilistic components by adopting a range of plausible values for material properties and initial conditions, computing a corresponding range of possible outcomes (Córdoba et al, 2015(Córdoba et al, , 2018. Probabilistic DF inundation forecasts can be accomplished by exploiting statistical patterns exhibited by prior events.…”

Section: Modellingmentioning

confidence: 99%

Lahars and debris flows: Characteristics and impacts

Thouret

Antoine

Magill

et al. 2020

Earth-Science Reviews

104

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Section: Modellingmentioning

confidence: 99%

Lahars and debris flows: Characteristics and impacts

Thouret

Antoine

Magill

et al. 2020

Earth-Science Reviews

104

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“…Computational models or numerical codes have become one of the most important tools for HCF/DF hazard assessment. Thouret et al (2020), their Table 4 elaborated on a list of models used for simulating lahars or HCFs/DFs, such as LAHARZ-py (Schilling, 2014), Titan2D (Pitman and Le, 2005;Williams et al, 2008) and Titan2F (Córdoba et al, 2015;Córdoba et al, 2018), FLO-2D (O'Brien et al, 1993), RAMMS (Cesca and D'Agostino, 2008), and VolcFlow (Kelfoun and Druitt, 2005). We tested three models, Titan2F, VolcFlow, and FLO-2D, all shallowwater depth-averaged models for modeling HCFs and DFs in the Qdas.…”

Section: Modeling Debris Flows and Hyperconcentrated Flowsmentioning

confidence: 99%

Modeling Tephra Fall and Sediment-Water Flows to Assess Their Impacts on a Vulnerable Building Stock in the City of Arequipa, Peru

et al. 2022

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Arequipa, Peru’s second economic center hosting c. 1,110,000 inhabitants, is the largest South American city exposed to a large variety of natural hazards. At least 200,000 live in areas likely to be affected by hazards from El Misti volcano, located 17 km to the NE. A multidisciplinary project aims to address the impacts of tephra fall and frequent mass flows on the vulnerable building stock and roofs along two ravines that cross the city, enabling decision-makers to undertake retrofitting projects and improve urban risk planning. Two recent eruptions, that is, the 1440–1470 CE Vulcanian event and c. 2070 years BP Plinian eruption, were chosen as references for probable scenarios of potential tephra fall impacts from El Misti on the building roofs. Tephra fall impacts on the city depend on the eruptive style, column height, and patterns of wind directions and velocities over south Peru and roof mechanical resistance. Estimates of potential damage levels and cost range values rely on nine structural types and four classes of vulnerable roofs. Simulation runs of hyperconcentrated flows (HCF) and debris flows (DF), using three depth-averaged flow models (Titan2F, VolcFlow, and Flo-2D) along two drainage basins on the SW flank of El Misti and across Arequipa, examined three scenarios from a database of 39 recent events and other historical lahars. Simulation results showcase the extent toward the city, inundation depths ≤4.6 m, flow velocities ≤9 m/s, and dynamic pressure up to 100 kPa from three different magnitude HCFs and DFs. In both ravines, overbank flows occurred in key urban areas due to channel sinuosity and constrictions near bridges. Potential impacts on habitat stem from ranges of flow dynamic pressure and measurements of construction material. We estimated the monetary loss of buildings according to hyperconcentrated flows and debris flows scenarios to contribute to retrofitting procedure, implementation of defense work, and relocation policy.

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“…Titan2F was developed to account for both of the phases keeping a reasonable computational cost [8], [21]. The fluid part of the flow is modeled using typical shallow water like approach, whereas the frictional behavior of the solid phase is accounted by assuming that Mohr-Coulomb law is valid in such case, as in [17] and [18].…”

Section: Modeling Lahars With Titan2fmentioning

confidence: 99%

“…The equation system is further integrated by depth averaging [17] (see [21], [8] for details), which is computationally cheap because is a 2D approach over a three dimensional topography. This approach is known as a pseudo-3D approach.…”

Section: Modeling Lahars With Titan2fmentioning

confidence: 99%

A Modeling Approach for Lahar Hazard Assessment: the Case of Tamasagra Sector in the City of Pasto, Colombia

et al. 2019

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The computational program Titan2F, a two phase flow modeling program, is used to model several hypothetical scenarios of volcanic origin mud flows (lahars) in order to estimate the spacial and temporary evolution of this potentially destructive natural phenomena at its entrance of the city of Pasto, Colombia through the Mijitayo river basin. The predictions of the program suggest that extremely high and destructive dynamic pressures at the entrance to the city can be expected. In addition, our simulations show that half of the Tamasagra and El Bosque neighbors can be inundated with lahar depths of about 1 meter thickness. The program shows to be capable to deal with the modeling of the effect of the streets and buildings on the flow behavior, showing how the streets channelizes the flow governing the path of it. In addition, our results allow to identify regions where the flow loss most of its energy, where mitigation of risk can be suggested.

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TITAN2F code for lahar hazard assessment: derivation, validation and verification

Cited by 6 publications

References 61 publications

Lahars and debris flows: Characteristics and impacts

Lahars and debris flows: Characteristics and impacts

Modeling Tephra Fall and Sediment-Water Flows to Assess Their Impacts on a Vulnerable Building Stock in the City of Arequipa, Peru

A Modeling Approach for Lahar Hazard Assessment: the Case of Tamasagra Sector in the City of Pasto, Colombia

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