Urban Stormwater Management: Comparative Analysis of Traditional and Sustainable Approaches for Ecological Restoration

Huxiuyuan Ma

doi:10.54097/6j6ehk57

Authors

Huxiuyuan Ma

DOI:

https://doi.org/10.54097/6j6ehk57

Keywords:

Sustainable Stormwater Management, Low Impact Development (LID), Sponge City, Urban Ecological Restoration.

Abstract

With the intensification of global urbanization and climate change, the natural hydrological cycle has been significantly disrupted, resulting in increased frequency of flooding, increased pollution from non-point sources, and degradation of ecosystems. This study systematically reviews traditional and sustainable stormwater management methods, focusing on their technical characteristics and application effects in urban ecological restoration. Through case studies, the paper discusses the application results of low impact development (LID), sponge city and intelligent stormwater management system. For example, in the Sponge City pilot in Suzhou, the nitrogen and phosphorus reduction rates in stormwater wetlands reached 62% and 46%, respectively, while the vegetation-filtered zones significantly increased biodiversity. This study found that, compared to traditional centralized management methods with rapid drainage as the goal, the sustainable approach not only significantly improves water quality, but also enhances the climate resilience of cities through ecological restoration and resource optimization. The significance of this study is to integrate nature-based solutions with advanced technologies, providing theoretical support and practical guidance for urban water management and ecological restoration. It offers innovative pathways to tackle climate challenges and directs future interdisciplinary stormwater management research and practices.

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References

[1] Chithra, S. V., Harindranathan Nair, M. V., Amarnath, A., & Anjana, N. S. (2015). Impacts of impervious surfaces on the environment. International Journal of Engineering Science Invention, 4(5), 27–31.

[2] [2] Chen, L., Zhou, X., Yu, Y., Guo, C., Zhang, X., & Shen, Z. (2023). [A joint risk assessment method of waterlogging and non-point source pollution in urban built-up areas]. Advances in Water Science, 34(1), 76–87.

[3] Westra, S., Fowler, H. J., Evans, J. P., Alexander, L. V., Berg, P., Johnson, F., Kendon, E. J., Lenderink, G., & Roberts, N. M. (2014). Future changes to the intensity and frequency of short-duration extreme rainfall. Reviews of Geophysics, 52(4), 522–555.

[4] Franco, I. B., Chatterji, T., Derbyshire, E., & Tracey, J. (Eds.). (2020). Actioning the Global Goals for Local Impact: Towards Sustainability Science, Policy, Education, and Practice. Springer.

[5] Tsihrintzis, V. A., & Hamid, R. (1997). Modeling and management of urban stormwater runoff quality: A review. Water Resources Management, 11(2), 137–164.

[6] Yang, W., Zhang, J., Mei, S., & Krebs, P. (2021). Impact of antecedent dry-weather period and rainfall magnitude on the performance of low impact development practices in urban flooding and non-point pollution mitigation. Journal of Cleaner Production, 320, 128946.

[7] Ren, X., Hong, N., Li, L., Kang, J., & Li, J. (2020). Effect of infiltration rate changes in urban soils on stormwater runoff process. Geoderma, 363, 114158.

[8] Birhanu, B., Sterk, G., Temesgen, M., Abdulkedir, A., & Stroosnijder, L. (2012). Rainwater harvesting and management in rainfed agricultural systems in sub-Saharan Africa – A review. Physics and Chemistry of the Earth, 47–48, 139–151.

[9] Jebari, S., Berndtsson, R., & Bahri, A. (2015). Challenges of traditional rainwater harvesting systems in Tunisia. Middle East Critique, 24(3), 289–306.

[10] Gee, K. D., & Hunt, W. F. (2016). Enhancing stormwater management benefits of rainwater harvesting via innovative technologies. Journal of Environmental Engineering, 142(8), 04016039.

[11] Akpinar Ferrand, E., & Cecunjanin, F. (2014). Potential of rainwater harvesting in a thirsty world: A survey of ancient and traditional rainwater harvesting applications. Geography Compass, 8(6), 395–413.

[12] Sahu, R. K., Rawat, A. K., & Rao, D. L. N. (2015). Traditional rainwater management system (‘Haveli’) in Vertisols of central India improves carbon sequestration and biological soil fertility. Agriculture, Ecosystems & Environment, 200, 94–101.

[13] Huang, Z., Nya, E. L., Rahman, M. A., Mwamila, T. B., Cao, V., Gwenzi, W., & Noubactep, C. (2021). Integrated water resource management: Rethinking the contribution of rainwater harvesting. Sustainability, 13(15), 8338.

[14] Nguyen, T. T., Ngo, H. H., Guo, W., Wang, X. C., Ren, N., Li, G., Ding, J., & Liang, H. (2019). Implementation of a specific urban water management - Sponge City. Science of the Total Environment, 652, 147–162.

[15] Li, H., Ding, L., Ren, M., Li, C., & Wang, H. (2017). Sponge city construction in China: A survey of the challenges and opportunities. Water, 9(9), 594.

[16] Xie, M., Wang, R., Yang, J., & Cheng, Y. (2021). A monitoring and control system for stormwater management of urban green infrastructure. Water, 13(11), 1438.

[17] Chang, N.-B., Lu, J.-W., Chui, T. F. M., & Hartshorn, N. (2018). Global policy analysis of low impact development for stormwater management in urban regions. Land Use Policy, 70, 368–383.

[18] Shishegar, S., Duchesne, S., Pelletier, G., & Ghorbani, R. (2021). A smart predictive framework for system-level stormwater management optimization. Journal of Environmental Management, 278, 111505.

[19] Barbosa, A. E., Fernandes, J. N., & David, L. M. (2012). Key issues for sustainable urban stormwater management. Water Research, 46(20), 6787–6798.

[20] Rosenberger, L., Leandro, J., Pauleit, S., & Erlwein, S. (2021). Sustainable stormwater management under the impact of climate change and urban densification. Journal of Hydrology, 596, 126137.

[21] Prudencio, L., & Null, S. E. (2018). Stormwater management and ecosystem services: A review. Environmental Research Letters, 13, 033002.

[22] Walsh, C. J., Fletcher, T. D., Bos, D. G., & Imberger, S. J. (2015). Restoring a stream through retention of urban stormwater runoff: A catchment-scale experiment in a social–ecological system. Freshwater Science, 34(3), 1161–1168.

[23] Flynn, C. D., & Davidson, C. I. (2016). Adapting the social-ecological system framework for urban stormwater management: The case of green infrastructure adoption. Ecology and Society, 21(4), 19.

[24] Jiang, Y., Zevenbergen, C., & Ma, Y. (2018). Urban pluvial flooding and stormwater management: A contemporary review of China’s challenges and “sponge cities” strategy. Environmental Science & Policy, 80, 132–143.