Modeling spatial dependencies of natural hazards in coastal regions: a nonstationary approach with barriers
Modeling spatial dependencies of natural hazards in coastal regions: a nonstationary approach with barriers
Natural hazards like floods, cyclones, earthquakes, or, tsunamis have deep impacts on the environment and society causing damage to both life and property. These events can cause widespread destruction and can lead to long-term socio-economic disruption often affecting the most vulnerable populations in society. Computational modeling provides an essential tool to estimate the damage by incorporating spatial uncertainties and examining global risk assessments. Classical stationary models in spatial statistics often assume isotropy and stationarity. It causes inappropriate smoothing over features having boundaries, holes, or physical barriers. Despite this, nonstationary models like barrier model have been little explored in the context of natural disasters in complex land structures. The principal objective of the current study is to evaluate the influence of barrier models compared to classical stationary models by analysing the incidence of natural disasters in complex spatial regions like islands and coastal areas. In the current study, we have used tsunami records from the island nation of Maldives. For seven atoll groups considered in our study, we have implemented three distinct categories of stochastic partial differential equation meshes, two for stationary models and one that corresponds to the barrier model concept. The results show that when assessing the spatial variance of tsunami incidence at the atoll scale, the barrier model outperforms the other two models while maintaining the same computational cost as the stationary models. In the broader picture, this research work contributes to the relatively new field of nonstationary barrier models and intends to establish a robust modeling framework to explore spatial phenomena, particularly natural hazards, in complex spatial regions having physical barriers.
4479-4498
Chaudhuri, Somnath
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Juan, Pablo
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Saurina, Laura Serra
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Varga, Diego
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Saez, Marc
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1 August 2023
Chaudhuri, Somnath
ae0507e0-f920-4438-bc9f-ecdd5ac8967a
Juan, Pablo
f3648398-5752-4dd0-9410-835566b659f4
Saurina, Laura Serra
94c89b4d-d609-4bb7-b471-80e61a6043fa
Varga, Diego
4df07421-a6e6-4a0b-b87f-7187d83c91e7
Saez, Marc
8e1a1aa0-d45d-4a7a-8de8-1ac0f8561c51
Chaudhuri, Somnath, Juan, Pablo, Saurina, Laura Serra, Varga, Diego and Saez, Marc
(2023)
Modeling spatial dependencies of natural hazards in coastal regions: a nonstationary approach with barriers.
Stochastic Environmental Research and Risk Assessment, 37, .
(doi:10.1007/s00477-023-02519-9).
Abstract
Natural hazards like floods, cyclones, earthquakes, or, tsunamis have deep impacts on the environment and society causing damage to both life and property. These events can cause widespread destruction and can lead to long-term socio-economic disruption often affecting the most vulnerable populations in society. Computational modeling provides an essential tool to estimate the damage by incorporating spatial uncertainties and examining global risk assessments. Classical stationary models in spatial statistics often assume isotropy and stationarity. It causes inappropriate smoothing over features having boundaries, holes, or physical barriers. Despite this, nonstationary models like barrier model have been little explored in the context of natural disasters in complex land structures. The principal objective of the current study is to evaluate the influence of barrier models compared to classical stationary models by analysing the incidence of natural disasters in complex spatial regions like islands and coastal areas. In the current study, we have used tsunami records from the island nation of Maldives. For seven atoll groups considered in our study, we have implemented three distinct categories of stochastic partial differential equation meshes, two for stationary models and one that corresponds to the barrier model concept. The results show that when assessing the spatial variance of tsunami incidence at the atoll scale, the barrier model outperforms the other two models while maintaining the same computational cost as the stationary models. In the broader picture, this research work contributes to the relatively new field of nonstationary barrier models and intends to establish a robust modeling framework to explore spatial phenomena, particularly natural hazards, in complex spatial regions having physical barriers.
Text
s00477-023-02519-9
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Accepted/In Press date: 9 July 2023
Published date: 1 August 2023
Identifiers
Local EPrints ID: 502881
URI: http://eprints.soton.ac.uk/id/eprint/502881
ISSN: 1436-3240
PURE UUID: f1c10e99-61a8-4451-a60d-5e206837f0d6
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Date deposited: 10 Jul 2025 17:21
Last modified: 22 Aug 2025 02:43
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Author:
Somnath Chaudhuri
Author:
Pablo Juan
Author:
Laura Serra Saurina
Author:
Diego Varga
Author:
Marc Saez
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