Earthquake vulnerability assessment of the built environment in the city of Srinagar, Kashmir Himalaya, using a geographic information system

The study investigates the earthquake vulnerability of buildings in Srinagar, an urban city in the Kashmir Himalaya, India. The city, covering an area of around 246 km2 and divided into 69 municipal wards, is situated in the tectonically active and densely populated mountain ecosystem. Given the hap...

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Bibliographic Details
Published in:Natural hazards and earth system sciences 2023-04, Vol.23 (4), p.1593-1611
Main Authors: Fayaz, Midhat, Romshoo, Shakil A, Rashid, Irfan, Chandra, Rakesh
Format: Article
Language:English
Subjects:
Analysis
Analytic hierarchy process
Building codes
Buildings
Built environment
Cities
Earthquake damage
Earthquakes
Environmental risk
Geographic information systems
Geographical information systems
Geology
India
Information systems
Masonry
Mountain ecosystems
Open spaces
Population density
Remote sensing
Retrofitting
Risk management
Risk reduction
Roads
Seismic activity
Seismic engineering
Urban environments
Vulnerability
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Summary:The study investigates the earthquake vulnerability of buildings in Srinagar, an urban city in the Kashmir Himalaya, India. The city, covering an area of around 246 km2 and divided into 69 municipal wards, is situated in the tectonically active and densely populated mountain ecosystem. Given the haphazard development and high earthquake vulnerability of the city, it is critical to assess the vulnerability of the built environment to inform policy-making for developing effective earthquake risk reduction strategies. Integrating various parameters in a geographic information system (GIS) using the analytical hierarchical process (AHP) and technique for order preference by similarity to an ideal solution (TOPSIS) approaches, the ward-wise vulnerability of the buildings revealed that a total of ∼ 17 km2 area (∼ 7 % area; 23 wards) has very high to high vulnerability, moderate vulnerability affects ∼ 69 km2 of the city area (28 % area; 19 wards), and ∼ 160 km2 area (∼ 65 % area; 27 wards) has vulnerability ranging from very low to low. Overall, the downtown wards are most vulnerable to earthquake damage due to the high risk of pounding, high building density, and narrower roads with little or no open spaces. The modern uptown wards, on the other hand, have lower earthquake vulnerability due to the relatively wider roads and low building density. To build a safe and resilient city for its 1.5 million citizens, the knowledge generated in this study would inform action plans for developing earthquake risk reduction measures, which should include strict implementation of the building codes, retrofitting of the vulnerable buildings, and creating a disaster consciousness among its citizenry.
ISSN:1684-9981
1561-8633
1684-9981
DOI:10.5194/nhess-23-1593-2023