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Resilience of Critical Infrastructure Systems to Floods: A Coupled Probabilistic Network Flow and LISFLOOD-FP Model

Resilience of Critical Infrastructure Systems to Floods: A Coupled Probabilistic Network Flow and LISFLOOD-FP Model
Resilience of Critical Infrastructure Systems to Floods: A Coupled Probabilistic Network Flow and LISFLOOD-FP Model

In this paper, a network-flow model was constructed to simulate the performance of interdependent critical infrastructure systems during flood hazards, when there is shortage of commodities such as electrical power and water. The model enabled us to control the distribution of commodities among different consumers whose demand cannot be fully met. Incorporating time-variance in the model allowed for evaluating the time evolution of the functional level of the infrastructure systems and quantifying their resilience. As a demonstration of the model’s capability, the network model was coupled with a raster-based hydraulic flooding model in the way of Monte Carlo simulations. It was then used to investigate the cascading effects of flood-related failures of individual infrastructure assets on the performance of the critical infrastructure systems of a coastal community under different flooding scenarios and future climate impacts. The coupled modelling framework is essential for correctly assessing the interdependences and cascading effects in the infrastructure systems in the case of flood hazards. While in the considered example, the extent of inundation becomes less severe with a changing climate, the risk to infrastructure does not recede because of the cascading effects. This behaviour could not be captured by the flood model alone.

Cascading effects, Climate changes, Flood modelling, Infrastructure networks, LISFLOOD-FP, Natural hazard, Network flow model, Sea level rise, Urban flood, Urban resilience
2073-4441
Yin, Yunzhu
54721b64-4e80-4290-a074-f5038a34e294
Val, Dimitri V.
6b622b53-6081-406b-b85e-d03d2839d18d
Zou, Qingping
76cb6288-7f3f-4115-9b9b-a9219baf36fa
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8
Yin, Yunzhu
54721b64-4e80-4290-a074-f5038a34e294
Val, Dimitri V.
6b622b53-6081-406b-b85e-d03d2839d18d
Zou, Qingping
76cb6288-7f3f-4115-9b9b-a9219baf36fa
Yurchenko, Daniil
51a2896b-281e-4977-bb72-5f96e891fbf8

Yin, Yunzhu, Val, Dimitri V., Zou, Qingping and Yurchenko, Daniil (2022) Resilience of Critical Infrastructure Systems to Floods: A Coupled Probabilistic Network Flow and LISFLOOD-FP Model. Water, 14 (5), [683]. (doi:10.3390/w14050683).

Record type: Article

Abstract

In this paper, a network-flow model was constructed to simulate the performance of interdependent critical infrastructure systems during flood hazards, when there is shortage of commodities such as electrical power and water. The model enabled us to control the distribution of commodities among different consumers whose demand cannot be fully met. Incorporating time-variance in the model allowed for evaluating the time evolution of the functional level of the infrastructure systems and quantifying their resilience. As a demonstration of the model’s capability, the network model was coupled with a raster-based hydraulic flooding model in the way of Monte Carlo simulations. It was then used to investigate the cascading effects of flood-related failures of individual infrastructure assets on the performance of the critical infrastructure systems of a coastal community under different flooding scenarios and future climate impacts. The coupled modelling framework is essential for correctly assessing the interdependences and cascading effects in the infrastructure systems in the case of flood hazards. While in the considered example, the extent of inundation becomes less severe with a changing climate, the risk to infrastructure does not recede because of the cascading effects. This behaviour could not be captured by the flood model alone.

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water-14-00683-v2 - Version of Record
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More information

Accepted/In Press date: 15 February 2022
Published date: 1 March 2022
Additional Information: Funding Information: Funding: This research was funded by EPSRC UK. Funding Information: Acknowledgments: The project is supported by the EPSRC Impact Acceleration Account Project Publisher Copyright: © 2022 by the authors. Licensee MDPI, Basel, Switzerland.
Keywords: Cascading effects, Climate changes, Flood modelling, Infrastructure networks, LISFLOOD-FP, Natural hazard, Network flow model, Sea level rise, Urban flood, Urban resilience

Identifiers

Local EPrints ID: 468135
URI: http://eprints.soton.ac.uk/id/eprint/468135
DOI: doi:10.3390/w14050683
ISSN: 2073-4441
PURE UUID: 2e7ea669-5fb3-458e-aba1-ff4533e1a9c0
ORCID for Daniil Yurchenko: ORCID iD orcid.org/0000-0002-4989-3634

Catalogue record

Date deposited: 03 Aug 2022 16:45
Last modified: 17 Mar 2024 04:11

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Contributors

Author: Yunzhu Yin
Author: Dimitri V. Val
Author: Qingping Zou
Author: Daniil Yurchenko ORCID iD

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