The application of numerical debris flow modelling for the generation of physical vulnerability curves

Abstract. The assessment of the physical vulnerability of elements at risk as part of the risk analysis is an essential aspect for the development of strategies and structural measures for risk reduction. Understanding, analysing and, if possible, quantifying physical vulnerability is a prerequisite for designing strategies and adopting tools for its reduction. The most common methods for assessing physical vulnerability are vulnerability matrices, vulnerability curves and vulnerability indicators; however, in most of the cases, these methods are used in a conflicting way rather than in combination. The article focuses on two of these methods: vulnerability curves and vulnerability indicators. Vulnerability curves express physical vulnerability as a function of the intensity of the process and the degree of loss, considering, in individual cases only, some structural characteristics of the affected buildings. However, a considerable amount of studies argue that vulnerability assessment should focus on the identification of these variables that influence the vulnerability of an element at risk (vulnerability indicators). In this study, an indicator-based methodology (IBM) for mountain hazards including debris flow ) is applied to a case study for debris flows in South Tyrol, where in the past a vulnerability curve has been developed. The relatively "new" indicator-based method is being scrutinised and recommendations for its improvement are outlined. The comparison of the two methodological approaches and their results is challenging since both methodological approaches deal with vulnerability in a different way. However, it is still possible to highlight their weaknesses and strengths, show clearly that both methodologies are necessary for the assessment of physical vulnerability and provide a preliminary "holistic methodological framework" for physical vulnerability assessment showing how the two approaches may be used in combination in the future.

Section: Methods For Assessing Physical Vulnerabilitymentioning

confidence: 99%

Section: Methods For Assessing Physical Vulnerabilitymentioning

confidence: 99%

Vulnerability curves vs. vulnerability indicators: application of an indicator-based methodology for debris-flow hazards

Papathoma-Köhle

2016

“…The relationship between impact intensity and degree of loss is commonly expressed in terms of a vulnerability curve or vulnerability function (Totschnig and Fuchs, 2013), although also semi-quantitative and qualitative methods exist (Totschnig and Fuchs, 2013;Fuchs et al, 2007;Jakob et al, 2012;Kappes et al, 2012). The intensity criteria of torrent (steep stream) processes, encompassing clear water, hyperconcentrated and debris flows, has been considered in terms of impact forces Quan Luna et al, 2011;Hu et al, 2012); deposit height (Mazzorana et al, 2012;Fuchs et al, , 2007Akbas et al, 2009;Totschnig et al, 2011;Lo et al, 2012;Papathoma-Köhle et al, 2012;Totschnig and Fuchs, 2013); kinematic viscosity (Quan Luna et al, 2011;Totschnig et al, 2011); flow depth (Jakob et al, 2013;Tsao et al, 2010;Totschnig and Fuchs, 2013); flow velocity times flow depth (Totschnig and Fuchs, 2013); and velocity squared times flow depth (Jakob et al, 2012). Different types of elements at risk will show different levels of damage given the same intensity of hazard (Jha et al, 2012;Albano et al, 2014;Liu et al, 2014), therefore vulnerability curves are developed for a particular type of exposed element (such as construction type, building dimensions or road access conditions).…”

Section: Conceptualisation Of Vulnerabilitymentioning

confidence: 99%

Regional prioritisation of flood risk in mountainous areas

Rogelis

Werner

Obregón

et al. 2016

Abstract. In this paper a method is proposed to identify mountainous watersheds with the highest flood risk at the regional level. Through this, the watersheds to be subjected to more detailed risk studies can be prioritised in order to establish appropriate flood risk management strategies. The prioritisation is carried out through an index composed of a qualitative indicator of vulnerability and a qualitative flash flood/debris flow susceptibility indicator. At the regional level, vulnerability was assessed on the basis of a principal component analysis carried out with variables recognised in literature to contribute to vulnerability, using watersheds as the unit of analysis. The area exposed was obtained from a simplified flood extent analysis at the regional level, which provided a mask where vulnerability variables were extracted. The vulnerability indicator obtained from the principal component analysis was combined with an existing susceptibility indicator, thus providing an index that allows the watersheds to be prioritised in support of flood risk management at regional level. Results show that the components of vulnerability can be expressed in terms of three constituent indicators: (i) socio-economic fragility, which is composed of demography and lack of well-being; (ii) lack of resilience and coping capacity, which is composed of lack of education, lack of preparedness and response capacity, lack of rescue capacity, cohesiveness of the community; and (iii) physical exposure, which is composed of exposed infrastructure and exposed population. A sensitivity analysis shows that the classification of vulnerability is robust for watersheds with low and high values of the vulnerability indicator, while some watersheds with intermediate values of the indicator are sensitive to shifting between medium and high vulnerability.

“…residential buildings, see Papathoma-Köhle et al, 2011, for an overview). In particular, vulnerability functions for buildings impacted by debris flows (Fuchs et al, 2007b;Akbas et al, 2009;Quan Luna et al, 2011) and fluvial sediment transport (Totschnig et al, 2011) are limited. In most of these studies vulnerability was measured using an economic approach and derived from the quotient between the loss and the individual reinstatement value for each element at risk considered.…”

Section: Vulnerability Of Endangered Elementsmentioning

confidence: 99%

Towards dynamics in flood risk assessment

Mazzorana¹,

Levaggi

Keiler

et al. 2012

Abstract. As a consequence of flood impacts, communities inhabiting mountain areas are increasingly affected by considerable damage to infrastructure and property. The design of effective flood risk mitigation strategies and their subsequent implementation is crucial for a sustainable development in mountain areas. The assessment of the dynamic evolution of flood risk is the pillar of any subsequent planning process that is targeted at a reduction of the expected adverse consequences of the hazard impact. Given these premises, firstly, a comprehensive method to derive flood hazard process scenarios for well-defined areas at risk is presented. Secondly, conceptualisations of a static and dynamic flood risk assessment are provided. These are based on formal schemes to compute the risk mitigation performance of devised mitigation strategies within the framework of economic costbenefit analysis. In this context, techniques suitable to quantify the expected losses induced by the identified flood impacts are provided.