A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Integrating relative sea level rise into compound flooding hazard assessment for coastal cities
Study Region: Haikou, the capital city of Hainan Province, China. Study Focus: We develop a framework combining statistical and hydrodynamic overland inundation modeling to assess the combined effect of compound flooding and relative sea level rise (RSLR) on urban functional areas in terms of flood hazard and exposure. This framework uses maximum flood depth (MFD), maximum flood area, and maximum flood volume (MFV) as metrics for flood hazard assessment, and absolute flood exposure and relative flood exposure (RFE) metrics for evaluating flood exposure in urban areas. New Hydrological Insights for the Region: Our findings indicate that flood hazards assessed using univariate return periods (RPs) are more severe than those derived from bivariate RPs, with the univariate MFV being 90.5 % higher for the 200-year RP. RSLR significantly amplifies the compound flood effects in major inundation areas, such as Haidian Island and Jiangdong New Area. Specifically, for the 100-year RP, the MFD in these regions is projected to increase by 1.5 m by 2100 due to RSLR. Additionally, residential land is identified as the most vulnerable to RSLR, with its RFE reaching 19.8 % by 2100, which is 6.3 % higher compared to scenarios without considering RSLR. These results show the necessity of incorporating RSLR into compound flood hazard assessment to formulate flood mitigation and management measures in coastal cities.
Integrating relative sea level rise into compound flooding hazard assessment for coastal cities
Study Region: Haikou, the capital city of Hainan Province, China. Study Focus: We develop a framework combining statistical and hydrodynamic overland inundation modeling to assess the combined effect of compound flooding and relative sea level rise (RSLR) on urban functional areas in terms of flood hazard and exposure. This framework uses maximum flood depth (MFD), maximum flood area, and maximum flood volume (MFV) as metrics for flood hazard assessment, and absolute flood exposure and relative flood exposure (RFE) metrics for evaluating flood exposure in urban areas. New Hydrological Insights for the Region: Our findings indicate that flood hazards assessed using univariate return periods (RPs) are more severe than those derived from bivariate RPs, with the univariate MFV being 90.5 % higher for the 200-year RP. RSLR significantly amplifies the compound flood effects in major inundation areas, such as Haidian Island and Jiangdong New Area. Specifically, for the 100-year RP, the MFD in these regions is projected to increase by 1.5 m by 2100 due to RSLR. Additionally, residential land is identified as the most vulnerable to RSLR, with its RFE reaching 19.8 % by 2100, which is 6.3 % higher compared to scenarios without considering RSLR. These results show the necessity of incorporating RSLR into compound flood hazard assessment to formulate flood mitigation and management measures in coastal cities.
Integrating relative sea level rise into compound flooding hazard assessment for coastal cities
Qing Liu (author) / Hanqing Xu (author) / Guofeng Wu (author) / Can Lu (author) / Xuchen Wei (author) / Jun Wang (author)
2025
Article (Journal)
Electronic Resource
Unknown
Metadata by DOAJ is licensed under CC BY-SA 1.0
Integrating relative sea level rise into compound flooding hazard assessment for coastal cities
| Elsevier | 2025
Coastal Flooding Hazard Assessment in South Australia
| British Library Conference Proceedings | 1997
Coastal Flooding Hazard Assessment in South Australia
| British Library Conference Proceedings | 1997
| DOAJ | 2023