Comparison of Flood Resilience Between Low-Carbon and Traditional Communities: A Case Study of Kunming, China

Comparison of Flood Resilience Between Low-Carbon and Traditional Communities: A Case Study of Kunming, China

Under China’s dual carbon strategy, low-carbon city construction is expected to help reduce urban flood risks. However, the flood resilience of low-carbon communities remains unclear, limiting effective disaster prevention. This study examines traditional and newly built low-carbon communities in Ku...

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Bibliographic Details
Main Authors: Zheng Zhang, Dingjie Zhou, Ling Zhu, Zhiqiang Xie, Wei Cheng, Qijia Yang, Junxiao Wang, Zhiyong Yuan, Yifei Liu, Yufei Li, Ping Wen, Shihan Bai, Sidong Zhao
Format: Article
Language:English
Published: MDPI AG 2025-06-01
Series:Land
Subjects:
low-carbon development
urban flooding
resilience measurement
coupling coordination
GIS
Online Access:https://www.mdpi.com/2073-445X/14/7/1368
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Summary:Under China’s dual carbon strategy, low-carbon city construction is expected to help reduce urban flood risks. However, the flood resilience of low-carbon communities remains unclear, limiting effective disaster prevention. This study examines traditional and newly built low-carbon communities in Kunming, establishing indices for community flood resilience and low-carbon development according to current national and local standards. Flood resilience (UFR) and low-carbon development level (ULC) were measured using the critic–entropy weight and TOPSIS methods, and a coupling coordination analysis model was used to analyze their correlation and coordination. The results are as follows: (1) The two communities exhibit marked spatial heterogeneity in both UFR and ULC. On average, the UFR in traditional communities is 21.53% higher than in low-carbon communities, while the ULCs are 4.33% higher in low-carbon communities compared to traditional ones. (2) UFR and ULC showed a high coupling level in both communities (over 98%), indicating a strong correlation. (3) The Moran’s I index of 0.664 for coupling coordination indicates notable spatial dependence. These results suggest that, initially, low-carbon communities in Kunming may not exhibit stronger flood resilience, but low-carbon development can significantly improve flood resilience over time. This paper also provides recommendations for enhancing flood resilience in urban low-carbon communities.
ISSN:2073-445X

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