- Chen, Y., Zhou, H., Zhang, H., Du, G., & Zhou, J. (2015). Urban flood risk warning under rapid urbanization. Environmental research, 139, 3-10.
- Davis, A. P. (2008). Field performance of bioretention: Hydrology impacts. Journal of Hydrologic Engineering, 13(2), 90-95.
- Davis, A. P., Traver, R. G., Hunt, W. F., Lee, R., Brown, R. A., & Olszewski, J. M. (2012). Hydrologic performance of bioretention storm-water control measures. Journal of Hydrologic Engineering, 17(5), 604-614.
- de Macedo, M. B., do Lago, C. A. F., & Mendiondo, E. M. (2019). Stormwater volume reduction and water quality improvement by bioretention: Potentials and challenges for water security in a subtropical catchment. Science of the Total Environment, 647, 923-931.
- DeBusk, K., & Wynn, T. (2011). Storm-water bioretention for runoff quality and quantity mitigation. Journal of Environmental Engineering, 137(9), 800-808.
- Eckart, K., McPhee, Z., & Bolisetti, T. (2017). Performance and implementation of low impact development–A review. Science of the Total Environment, 607, 413-432.
- Feng, B., Zhang, Y., & Bourke, R. (2021). Urbanization impacts on flood risks based on urban growth data and coupled flood models. Natural Hazards, 106(1).
- Gülbaz, S., & Kazezyılmaz-Alhan, C. M. (2017). Experimental investigation on hydrologic performance of LID with rainfall-watershed-bioretention system. Journal of Hydrologic Engineering, 22(1), D4016003.
- Hoffmann, G., Gardner, L., Espie, M., & Dunbar, J. (2020). Stormwater Management Guidebook (2nd ed.). Department of Energy and Environment.
- Huang, C.-L., Hsu, N.-S., Liu, H.-J., & Huang, Y.-H. (2018). Optimization of low impact development layout designs for megacity flood mitigation. Journal of hydrology, 564, 542-558.
- Hunt, W., Smith, J., Jadlocki, S., Hathaway, J., & Eubanks, P. (2008). Pollutant removal and peak flow mitigation by a bioretention cell in urban Charlotte, NC. Journal of Environmental Engineering, 134(5), 403-408.
- Luo, P., Luo, M., Li, F., Qi, X., Huo, A., Wang, Z., He, B., Takara, K., Nover, D., & Wang, Y. (2022). Urban flood numerical simulation: Research, methods and future perspectives. Environmental modelling & software, 156, 105478.
- Mani, M., Bozorg-Haddad, O., & Loáiciga, H. A. (2019). A new framework for the optimal management of urban runoff with low-impact development stormwater control measures considering service-performance reduction. Journal of Hydroinformatics, 21(5), 727-744.
- Movahedinia, M., Samani, J. M. V., Barakhasi, F., Taghvaeian, S., & Stepanian, R. (2019). Simulating the effects of low impact development approaches on urban flooding: a case study from Tehran, Iran. Water Science and Technology, 80(8), 1591-1600.
- PWD, C. o. P. (2014). Stormwater Management Guidance Manual (Version 2.1 ed.). Philadelphia Water Department.
- Rossman, L., & Huber, W. (2016a). SWMM Reference Manual Volume I—Hydrology. United States Environmental Protection Agency.
- Rossman, L., & Huber, W. (2016b). SWMM Reference Manual Volume III—Water Quality United States Environmental Protection Agency.
- Roy-Poirier, A., Champagne, P., & Filion, Y. (2010). Review of bioretention system research and design: past, present, and future. Journal of Environmental Engineering, 136(9), 878-889.
- Shuster, W. D., Bonta, J., Thurston, H., Warnemuende, E., & Smith, D. (2005). Impacts of impervious surface on watershed hydrology: A review. Urban Water Journal, 2(4), 263-275.
- Swathi, V., Raju, K. S., & Singh, A. P. (2018). Application of storm water management model to an urban catchment. In Hydrologic Modeling (pp. 175-184). Springer.
- Willard, L., Wynn-Thompson, T., Krometis, L., Neher, T., & Badgley, B. (2017). Does it pay to be mature? Evaluation of bioretention cell performance seven years postconstruction. Journal of Environmental Engineering, 143(9), 04017041.
- Yang, B., Zhang, T., Li, J., Feng, P., & Miao, Y. (2023). Optimal designs of LID based on LID experiments and SWMM for a small-scale community in Tianjin, north China. Journal of environmental management, 334, 117442.
- Yang, Y., & Chui, T. F. M. (2018). Optimizing surface and contributing areas of bioretention cells for stormwater runoff quality and quantity management. Journal of environmental management, 206, 1090-1103.
- Yin, D., Evans, B., Wang, Q., Chen, Z., Jia, H., Chen, A. S., & Fu, G. (2020). Integrated 1D and 2D model for better assessing runoff quantity control of low impact development facilities on community scale. Science of the Total Environment, 720, 137630.
- Zhu, Z., Chen, Z., Chen, X., & Yu, G. (2019). An assessment of the hydrologic effectiveness of low impact development (LID) practices for managing runoff with different objectives. Journal of environmental management, 231, 504-514.
- Zhuang, Q., Li, M., & Lu, Z. (2023). Assessing runoff control of low impact development in Hong Kong's dense community with reliable SWMM setup and calibration. Journal of environmental management, 345, 118599.
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