Managing Urban Flood Risk and Building Resilience in a Changing Climate

doi:10.1017/9781108787291.019

15 - Managing Urban Flood Risk and Building Resilience in a Changing Climate

from Part III - Sustainable Water Management under Future Uncertainty

Published online by Cambridge University Press: 17 March 2022

Yueling Wang ,

Qiuhong Tang and

Nigel Wright

Edited by

Qiuhong Tang and

Guoyong Leng

Show author details

Qiuhong Tang: Affiliation:
Chinese Academy of Sciences, Beijing
Guoyong Leng: Affiliation:
Oxford University Centre for the Environment

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Summary

Urban flooding disasters have increased due to climate change in recent decades. The induced casualties and economic losses are aggravated by intense urbanization. Climate change projections present high confidence in the increase of flood hazard in the future of the twenty-first century. Moreover, population growth and socio-economic development may lead to an increase of vulnerability to flood hazard. In this context, most countries have launched relevant initiatives to mitigate and adapt to urban flooding disaster, in order to improve urban resilience to flood disaster and achieve urban sustainable development goals. Structural, semi-structural and non-structural strategies have been developed and evaluated in the framework of flood risk management. Furthermore, the integrated flood modelling framework has been developed to support the integrated flood risk assessment under a changing environment. Based on projections, urban flood resilience can be estimated and applied to improve the decision-making of flood policy and regulation, and to guide the planning and design of the flood risk management strategy. In this context, this chapter reviews and discusses the natural and anthropogenic drivers of urban flooding, flood risk management in developing and developed countries and the integrated modelling framework of flood risk management.

Keywords

Climate change Natural and anthropogenic drivers of urban flood risk Flood risk management Integrated modelling framework Urban flood resilience

Type: Chapter
Information: Climate Risk and Sustainable Water Management , pp. 315 - 341

DOI: https://doi.org/10.1017/9781108787291.019 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2022

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References

Aerts, J. C., Botzen, W. J., Clarke, K. C., et al. (2018). Integrating human behaviour dynamics into flood disaster risk assessment. Nature Climate Change 8(3): 193.Google Scholar

Aitsi-Selmi, A., Murray, V., Wannous, C., et al. (2016). Reflections on a science and technology agenda for 21st century disaster risk reduction. International Journal of Disaster Risk Science 7(1): 1–29.CrossRef Google Scholar

Andoh, R. Y. G., & Iwugo, K. O. (2012). Sustainable urban drainage systems: A UK perspective. Global Solutions for Urban Drainage 1–16. DOI:10.1061/40644(2002)19.Google Scholar

Balica, S., & Wright, N. G. (2010). Reducing the complexity of the flood vulnerability index. Environmental Hazards 9(4): 321–339.CrossRef Google Scholar

Behzadian, K., & Kapelan, Z. (2015) Modelling metabolism based performance of an urban water system using Water MET 2. Resources, Conservation and Recycling 99: 84–99.CrossRef Google Scholar

Bennet, O., & Hartwell-Naquib, S. (2014). Flood defence spending in England. House of Commons library, standard note SN/SC/5755.Google Scholar

Bensona, D., Fritsch, O., Cook, H., & Schmidd, M. (2014). Evaluating participation in WFD river basin management in England and Wales: Processes, communities, outputs and outcomes. Land Use Policy 38: 213–222.CrossRef Google Scholar

Berndtsson, R., Becker, P., Persson, A., et al. (2019). Drivers of changing urban flood risk: A framework for action. Journal of Environmental Management 240: 47–56.CrossRef Google Scholar

Bertilsson, L., Wiklund, K., Tebaldi, I. D. M., et al. (2019). Urban flood resilience – A multi-criteria index to integrate flood resilience into urban planning, Journal of Hydrology 573: 970–982.Google Scholar

Beven, K. (2012). Rainfall-Runoff Modelling: The Primer (2nd ed., pp. i–xxix). Chichester: John Wiley & Sons.CrossRef Google Scholar

Bottazzi, P., Winkler, M. S., & Speranza, C. I. (2019). Flood governance for resilience in cities: The historical policy transformations in Dakar’s suburbs. Environmental Science & Policy 93: 172–180.CrossRef Google Scholar

Brown, R. R., Keath, N., & Wong, T. H. F. (2009). Urban water management in cities: Historical, current and future regimes. Water Science & Technology 59(5): 847–855.Google Scholar

Bruwier, M., Maravat, C., Mustafa, A., et al. (2020). Influence of urban forms on surface flow in urban pluvial flooding. Journal of Hydrology 582: 124493.CrossRef Google Scholar

Bubeck, P., Kreibich, H., Penning-Rowsell, E. C., Botzen, W. J. W., De Moel, H., & Klijn, F. (2015). Explaining differences in flood management approaches in Europe and in the USA – A comparative analysis. Journal of Flood Risk Management 10: 436–445.Google Scholar

Burby, R. J., Deyle, R. E., Godschalk, D. R., & Olshansky, R. B. (2000). Creating hazard resilient communities through land-use planning. Natural Hazards Review 1(2): 99–106.CrossRef Google Scholar

Cabral, P., Augusto, G., Akande, A., et al. (2017). Assessing Mozambique’s exposure to coastal climate hazards and erosion. International Journal of Disaster Risk Reduction 23: 45–52.CrossRef Google Scholar

Cai, T., Li, X., Ding, X., Wang, J., & Zhan, J. (2019). Flood risk assessment based on hydrodynamic model and fuzzy comprehensive evaluation with GIS technique. International Journal of Disaster Risk Reduction 35: 101077.CrossRef Google Scholar

Cariolet, J.-M., Vuillet, M. & Diab, Y. (2019). Mapping urban resilience to disasters – A review. Sustainable Cities and Society 51: 101746,CrossRef Google Scholar

Chan, F. K. S., Griffiths, J. A., Higgitt, D., et al. (2018). ‘Sponge City’ in China – A breakthrough of planning and flood risk management in the urban context. Land Use Policy 76: 772–778.CrossRef Google Scholar

Chang, F., Chen, P., Lu, Y., Huang, E., & Chang, K. (2014). Real-time multi-step-ahead water level forecasting by recurrent neural networks for urban flood control. Journal of Hydrology 517: 836–846.Google Scholar

Chelleri, L., Schuetze, T., & Salvati, L. (2015). Integrating resilience with urban sustainability in neglected neighbourhoods: Challenges and opportunities of transitioning to decentralized water management in Mexico City. Habitat International 48: 122–130.CrossRef Google Scholar

Chen, J., Gao, C., Zeng, X., et al. (2017). Assessing changes of river discharge under global warming of 1.5º and 2º in the upper reaches of the Yangtze River Basin: Approach by using multiple-GCMs and hydrological models. Quaternary International 453: 63–73.CrossRef Google Scholar

Chini, M., Giustarini, L., Matgen, P., Hostache, R., Pappenberger, F., & Bally, P. (2014). Flood hazard mapping combining high resolution multi-temporal SAR data and coarse resolution global hydrodynamic modelling. 2014 IEEE Geoscience and Remote Sensing Symposium, Quebec City, QC (pp. 2394–2396).CrossRef Google Scholar

Cigler, B. (2017). U.S. floods: The necessity of mitigation. State and local government Review 49(2): 127–139.Google Scholar

Cobbinah, P. B., Asibey, M. O., Opoku-Gyamfi, M., & Peprah, C. (2019). Urban planning and climate change in Ghana. Journal of Urban Management 8(2): 261–271.CrossRef Google Scholar

Cobbinah, P. B., Poku-Boansi, M., & Peprah, C. (2017). Urban environmental problems in Ghana. Environmental Development 23: 33–46.CrossRef Google Scholar

Costabile, P., Costanzo, C., De Lorenzo, G., & Macchione, F. (2020). Is local flood hazard assessment in urban areas significantly influenced by the physical complexity of the hydrodynamic inundation model? Journal of Hydrology 580: 124231.CrossRef Google Scholar

Costanza, R., Perez-Maqueo, O., Martinez, M. L., Sutton, P., Anderson, S. J., & Mulder, K. (2008). The value of coastal wetlands for hurricane protection. AMBIO: A Journal of the Human Environment 37(4): 241–248.CrossRef Google Scholar PubMed

Darabi, H., Choubin, B., Rahmati, O., Haghighi, A. T., Pradhan, B., & Kløve, B. (2019). Urban flood risk mapping using the GARP and QUEST models: A comparative study of machine learning techniques. Journal of Hydrology 569: 142–154.CrossRef Google Scholar

Dawson, R. J., Speight, L., Hall, J. W., Djordjevic, S., Savic, D., & Leandro, J. (2008). Attribution of flood risk in urban areas. Journal of Hydroinformatics 10(4): 275–288.CrossRef Google Scholar

Department for Environment Food and Rural Affairs (DEFRA) (2017). Evaluation of the Arrangements for Managing Local Flood Risk in England (p. FD2680). Final Report. London: DEFRA.Google Scholar

Diagne, K., Ndiaye, A., Pelling, M., & Wisner, B. (2012). History, governance and the millennium development goals: Flood risk reduction in Saint-Louis, Senegal. In Pelling, M. and Wisner, B. (eds.), Disaster Risk Reduction: Cases From Urban Africa. (p. 147). London: Routledge.Google Scholar

van Dijk, E., van der Meulen, J., Kluck, J., & Straatman, J. H. M. (2014). Comparing modelling techniques for analysing urban pluvial flooding. Water Science & Technology 69(2): 305–311.Google Scholar

Dixon, L., Clancy, N., Seabury, S. A., & Overton, A. (2006). The National Flood Insurance Program’s Market Penetration Rate, Estimates and Policy Implications. Arlington, VA: RAND.Google Scholar

FEMA (Federal Emergency Management) (1994). A Unified National Program for Floodplain Management. Washington, DC: FEMA. Available from www.fema.gov/media-library-data/20130726-1733-25045-0814/unp_floodplain_mgmt_1994.pdf (Last accessed 15 March 2020).Google Scholar

Fenner, R. A., O’Donnell, E., Ahilan, S., et al. (2019). Achieving urban flood resilience in an uncertain future. Water 11(5): 1082.Google Scholar

Field, C. B., Barros, V., Stocker, T. F., et al. (2012). Managing the Risks of Extreme Events and Disasters to Advance Climate Change Adaptation. A Special Report of Working Groups I and II of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press.Google Scholar

Filho, W. L., Balogun, A., Ayal, D. Y., et al. (2018). Strengthening climate change adaptation capacity in Africa – Case studies from six major African cities and policy implications. Environmental Science & Policy 86: 29–37.Google Scholar

Fletcher, T. D., Andrieu, H., & Hamel, P. (2013). Understanding, management and modelling of urban hydrology and its consequences for receiving waters: A state of the art. Advances in Water Resources 51: 261–279.CrossRef Google Scholar

Foresight (2004). Foresight: Future Flooding. Executive Summary. London: Department of Trade and Industry, The Government Office for Science.Google Scholar

Fritsch, O., & Benson, D. (2013). Integrating the principles of IWRM? River basin planning in England and Wales. International Journal of Water Governance 1(3–4): 265–284.Google Scholar

Gaitan, S., van de Giesen, N. C., & ten Veldhuis, J. A. E. (2016). Can urban pluvial flooding be predicted by open spatial data and weather data? Environmental Modelling & Software: With Environment Data News 85: 156–171.Google Scholar

Gallien, T. W., Sanders, B. F., & Flick, R. E. (2014). Urban coastal flood prediction: Integrating wave overtopping, flood defences and drainage. Coastal Engineering 91: 18–28.Google Scholar

Gebrehiwot, A., Hashemi-Beni, L., Thompson, G., Kordjamshidi, P., & Langan, T. E. (2019). Deep convolutional neural network for flood extent mapping using unmanned aerial vehicles data. Sensors 19(7): 1486.Google Scholar

Gersonius, B. (2012). The Resilience Approach to Climate Adaptation Applied for Flood Risk. PhD Thesis, UNESCO-IHE/TU Delft.Google Scholar

Gersonius, B., van Buuren, A., Zethof, M., & Kelder, E. (2016). Resilient flood risk strategies: Institutional preconditions for implementation. Ecology and Society 21(4): 28.Google Scholar

Glenis, V., Kutija, V., & Kilsby, C. G. (2018). A fully hydrodynamic urban flood modelling system representing buildings, green space and interventions. Environmental Modelling & Software 109: 272–292.Google Scholar

Griffiths, J. A., Zhu, F., Chan, F. K. S., & Higgitt, D. L. (2019). Modelling the impact of sea-level rise on urban flood probability in SE China. Geoscience Frontiers 10(2): 363–372.CrossRef Google Scholar

Grimaldi, S., Petroselli, A., Arcangeletti, E., & Nardi, F. (2013). Flood mapping in ungauged basins using fully continuous hydrologic–hydraulic modeling. Journal of Hydrology 487: 39–47.CrossRef Google Scholar

Hall, J. W., Meadowcroft, I. C., Sayers, P. B., & Bramley, M. E. (2003). Integrated flood risk management in England and Wales. Natural Hazards Review 4(3): 126–135.CrossRef Google Scholar

Hegger, D., Alexander, M., Raadgever, T., Priest, S., & Bruzzone, S. (2020). Shaping flood risk governance through science-policy interfaces: Insights from England, France and the Netherlands. Environmental Science & Policy 106: 157–165.CrossRef Google Scholar

Hirabayashi, Y., Mahendran, R., Koirala, S., et al. (2013). Global flood risk under climate change. Nature Climate Change 3: 816–821.Google Scholar

Huang, D., Zhang, R., Huo, Z., et al. (2012). An assessment of multidimensional flood vulnerability at the provincial scale in China based on the DEA method. Natural Hazards 64(2): 1575–1586.CrossRef Google Scholar

van den Hurk, M., Mastenbroek, E., & Meijerink, S. (2014). Water safety and spatial development: An institutional comparison between the United Kingdom and the Netherlands. Land Use Policy 36: 416–426.Google Scholar

Hutter, G., & Schanze, J. (2008). Learning how to deal with uncertainty of flood risk in long-term planning. Journal of River Basin Management 6(2): 175–184.Google Scholar

Imran, M., Sumra, K., Mahmood, S. A., & Sajjad, S. F. (2019). Mapping flood vulnerability from socioeconomic classes and GI data: Linking socially resilient policies to geographically sustainable neighbourhoods using PLS-SEM. International Journal of Disaster Risk Reduction 41: 101288.Google Scholar

IPCC (2012). Managing the Risks of Extreme Events and Disasters to Advance Climate Change Adaptation. A Special Report of Working Groups I and II of the Intergovernmental Panel on Climate Change, 582 pp. [Field, C. B., Barros, V., Stocker, T. F., et al. (eds.)]. Cambridge: Cambridge University Press.Google Scholar

IPCC (2014). Climate Change 2014: Synthesis Report. Contribution of Working Groups I, II and III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change, 151 pp. [Core Writing Team, Pachauri, R. K. & Meyer, L. A. (eds.)]. Geneva: IPCC.Google Scholar

IPCC-SRES (2000). Emission scenarios. In Nakićenovic, N., & Swart, R. (eds.), Special Report on Emissions Scenarios: A Special Report of Working Group III of the Intergovernmental Panel on Climate Change (pp. 239–292). Cambridge: Cambridge University Press.Google Scholar

Jenkins, K., Surminski, S., Hall, J., & Crick, F. (2017). Assessing surface water flood risk and management strategies under future climate change: Insights from an agent-based model. Science of The Total Environment 595: 159–168.Google Scholar

Ke, Y., Wang, S., Chan, A. P. C., & Lam, P. T. I. (2010). Preferred risk allocation in China’s public–private partnership (PPP) projects. International Journal of Project Management 28(5): 482–492.Google Scholar

Khan, S. (2012). Vulnerability assessments and their planning implications: A case study of the Hutt Valley, New Zealand. Natural Hazards 64(2): 1587–1607.Google Scholar

Koks, E. E., Jongman, B., Husby, T. G., & Botzen, W. J. W. (2015). Combining hazard, exposure and social vulnerability to provide lessons for flood risk management. Environmental Science & Policy 47: 42–52.CrossRef Google Scholar

Kolsky, P. (1999). Storm Drainage: An Engineering Guide to the Low-Cost Evaluation of System Performance. Rugby: Practical Action.Google Scholar

Kunreuther, H., & Roth, R. J. (1998). Paying the Price: The Status and Role of Insurance against Natural Disasters in the United States. Washington, DC: Joseph Henry.Google Scholar

Lee, S., Kim, J. C., Jung, H. S., Lee, M. J., & Lee, S. (2017). Spatial prediction of flood susceptibility using random-forest and boosted-tree models in Seoul metropolitan city, Korea. Geomatics Natural Hazards & Risk 8(2): 1185–1203.CrossRef Google Scholar

Li, Y., Li, H. X., Huang, J., & Liu, C. (2020). An approximation method for evaluating flash flooding mitigation of sponge city strategies – A case study of Central Geelong. Journal of Cleaner Production 257: 120525.CrossRef Google Scholar

Liao, K. (2012). A theory on urban resilience to floods – A basis for alternative planning practices. Ecology and Society 17(4): 48.Google Scholar

Löschner, L., & Nordbeck, R. (2019). Switzerland’s transition from flood defence to flood-adapted land use: A policy coordination perspective. Land Use Policy, 95: 103873.Google Scholar

Lu, X., & Ran, L. (2011). China flood havoc highlights poor urban planning. Natural Hazards 56: 575–576.Google Scholar

Macchione, F., Costabile, P., Costanzo, C., & De Lorenzo, G. (2019). Extracting quantitative data from non-conventional information for the hydraulic reconstruction of past urban flood events. A case study. Journal of Hydrology 576: 443–465.Google Scholar

Maheu, A. (2012). Urbanization and flood vulnerability in a peri-urban neighbourhood of Dakar, Senegal: How can participatory GIS contribute to flood management? In Filho, W. L. (ed.), Climate Change and the Sustainable Use of Water Resources. Climate Change Management (pp. 185–207). Berlin: Springer.Google Scholar

Mai, T., Mushtaq, S., Reardon-Smith, K., et al. (2020). Defining flood risk management strategies: A systems approach. International Journal of Disaster Risk Reduction 47: 101550.CrossRef Google Scholar

Meerow, S., Newell, J. P., & Stults, M. (2016). Defining urban resilience: A review. Landscape and Urban Planning 147: 38–49.Google Scholar

Mehrotra, R., & Sharma, A. (2010). Development and application of a multisite rainfall stochastic downscaling framework for climate change impact assessment. Water Resources Research 46(7): 759–768.Google Scholar

Mehrotra, R., Sharma, A., Nagesh Kumarb, D., & Reshmidevi, T. V. (2013). Assessing future rainfall projections using multiple GCMs and a multi-site stochastic downscaling model. Journal of Hydrology 488: 84–100.Google Scholar

Meinshausen, M., Smith, S. J., Calvin, K., et al. (2011). The RCP greenhouse gas concentrations and their extension from 1765 to 2300. Climate Change 109(1–2): 213–241.Google Scholar

Merz, B., Hall, J., Disse, M., & Schumann, A. (2010). Fluvial flood risk management in a changing world. Natural Hazards and Earth System Sciences 10(3): 509–727.Google Scholar

Metz, F., Angst, M., & Fischer, M. (2020). Policy integration: Do laws or actors integrate issues relevant to flood risk management in Switzerland? Global Environmental Change 61: 101945,CrossRef Google Scholar

Miguez, M. G., & Veról, A. P. (2017). A catchment scale Integrated Flood Resilience Index to support decision making in urban flood control design. Environment and Planning B: Planning and Design 44(5): 925–946.Google Scholar

Miller, J. D., & Hutchins, M. (2017). The impacts of urbanisation and climate change on urban flooding and urban water quality: A review of the evidence concerning the United Kingdom. Journal of Hydrology: Regional Studies 12: 345–362.Google Scholar

Ministry of Water Resources of the People’s Republic of China (2013). China Flood and Drought Disaster Bulletin 2013. Beijing: SinoMaps Press. Available from www.mwr.gov.cn/sj/tjgb/zgshzhgb/201612/t20161222_776091.html (Last accessed 9 March 2020).Google Scholar

Moftakhari, H. R., AghaKouchak, A., Sanders, B. F., Allaire, M., & Matthew, R. A. (2018). What is nuisance flooding? Defining and monitoring an emerging challenge. Water Resource Research 54(7): 4218–4227.Google Scholar

Mugume, S. N., Gomez, D. E., Fu, G., Farmani, R., & Butler, D. (2015). A global analysis approach for investigating structural resilience in urban drainage systems, Water Research 81: 15–26.Google Scholar

Müller, H., & Haberlandt, U. (2018). Temporal rainfall disaggregation using a multiplicative cascade model for spatial application in urban hydrology. Journal of Hydrology 556: 847–864,CrossRef Google Scholar

NatCatSERVICE Database (2019). Available from www.munichre.com/en/risks/natural-disasters-losses-are-trending-upwards/floods-and-flash-floods-underestimated-natural-hazards.html (Last accessed 20 October 2019).Google Scholar

NOAA National Centers for Environmental Information (NCEI) (2020). U.S. Billion-Dollar Weather and Climate Disasters. Available from www.ncdc.noaa.gov/billions/ (Last accessed 22 August 2021).Google Scholar

Nkhonjera, G. K. (2017). Understanding the impact of climate change on the dwindling water resources of South Africa, focusing mainly on Olifants River basin: A review. Environmental Science & Policy 71: 19–29.Google Scholar

Nkwunonwo, U. C., Whitworth, M., & Baily, B. (2020). A review of the current status of flood modelling for urban flood risk management in the developing countries. Scientific African 7: e00269.Google Scholar

Noonan, D. S., & Sadiq, A. A. (2018). Flood risk management: Exploring the impacts of the community rating system program on poverty and income inequality. Risk Analysis 38(3): 489–503.Google Scholar

O’Donnell, E. C., Lamond, J. E., & Thorne, C. R. (2018). Learning and action alliance framework to facilitate stakeholder collaboration and social learning in urban flood risk management. Environmental Science & Policy 80(Suppl C): 1–8.CrossRef Google Scholar

O’Donnell, E., Thorne, C., Ahilan, S., et al. (2019) The blue-green path to urban flood resilience. Blue-Green Systems 2(1): 28–45.Google Scholar

Pelling, M., & Wisner, B. (2012). Disaster Risk Reduction: Cases from Urban Africa. London: Routledge.CrossRef Google Scholar

Petersen, M. S. (2001). Impact of flash floods. In Gruntfest, E., & Handmer, J. (eds.), Coping with Flash Floods (pp. 11–13). Netherlands: Klumer Academic Publishers.Google Scholar

Qiao, X., Liao, K., & Randrup, T. B. (2020). Sustainable stormwater management: A qualitative case study of the Sponge Cities initiative in China. Sustainable Cities and Society 53: 101963.Google Scholar

Reshmidevi, T. V., Nagesh Kumar, D., Mehrotra, R., & Sharma, A. (2018). Estimation of the climate change impact on a catchment water balance using an ensemble of GCMs. Journal of Hydrology 556: 1192–1204.Google Scholar

Reynard, N. S., Prudhomme, C., & Crooks, S. M. (2001). The flood characteristics of large UK rivers: Potential effects of changing climate and land use. Climate Change 48: 343–359.Google Scholar

Rubinato, M., Nichols, A., Peng, Y., et al. (2019). Urban and river flooding: Comparison of flood risk management approaches in the UK and China and an assessment of future knowledge needs. Water Science and Engineering 12(4): 274–283.Google Scholar

Sadler, J. M., Goodall, J. L., Morsy, M. M., & Spencer, K. (2018). Modelling urban coastal flood severity from crowd-sourced flood reports using Poisson regression and Random Forest. Journal of Hydrology 559: 43–55.Google Scholar

Saul, A. J., Djordjevic, S., Maksimovic, C., & Blanksby, J. (2011). Integrated urban flood modelling In Pender, G., & Faulkner, H. (eds.), Flood Risk Science and Management (pp. 258–288). Hoboken, NJ: Wiley-Blackwell.Google Scholar

Sayers, P., Li, Y., Galloway, G., et al. (2013). Flood Risk Management: A Strategic Approach. Paris: UNESCO.Google Scholar

Schanze, J. (2006). Flood risk management – A basic framework. In Schanze, J., Zeman, E., & Marsalek, J. (eds.), Flood Risk Management – Hazards, Vulnerability and Mitigation Measures (pp. 1–20). Berlin: Springer.Google Scholar

Scholz, M. (2013). Water quality improvement performance of geotextiles within permeable paving systems: A critical review. Water 5(2): 462–479.Google Scholar

Schwartz, S. S., & Smith, B. (2016). Restoring hydrologic function in urban landscapes with suburban subsoiling. Journal of Hydrology 543(Part B): 770–781.Google Scholar

Sendzimir, J., Magnuszewski, P., Flachner, Z., et al. (2007). Assessing the resilience of a river management regime: Informal learning in a shadow network in the Tisza River Basin. Ecology and Society 13(1): 11.Google Scholar

Smith, L. S., & Liang, Q. (2015). A high-performance integrated hydrodynamic modelling system for urban flood simulations. Journal of Hydroinformatics 17(4): 518–533.Google Scholar

Smits, A. J. M., Nienhuis, P. H., & Saeijs, H. L. F. (2006). Changing estuaries, changing views. Hydrobiologia 565: 339–355.Google Scholar

Sörensen, J., & Mobini, S. (2017). Pluvial, urban flood mechanisms and characteristics – Assessment based on insurance claims. Journal of Hydrology 555: 51–67.Google Scholar

Sörensen, J., Persson, A., Sternudd, C., et al. (2016). Re-thinking urban flood management – Time for a regime shift. Water 8(8): 332.Google Scholar

Tang, Q. (2020). Global change hydrology: Terrestrial water cycle and global change. Science China Earth Sciences 63: 459–462.Google Scholar

Tanoue, M., Hirabayashi, Y., & Ikeuchi, H. (2016). Global-scale river flood vulnerability in the last 50 years. Scientific Reports 6: 36021.Google Scholar

Tiepolo, M. (2014). Flood risk reduction and climate change in large cities south of the Sahara. In Macchi, S., & Tiepolo, M. (eds.), Climate Change Vulnerability in Southern African Cities (pp. 19–36). Cham: Springer.Google Scholar

Trzaska, S., & Schnarr, E. (2014). A review of downscaling methods for climate change projections. United States Agency for International Development by Tetra Tech ARD (pp. 1–42).Google Scholar

UK Government (2010). Flood and Water Management Act. London: UK Government.Google Scholar

UN (2018). 68% of the world population projected to live in urban areas by 2050, says UN. Available from www.un.org/development/desa/en/news/population/2018-revision-of-world-urbanization-prospects.html (Last accessed 17 October 2019).Google Scholar

UN (United Nations, Department of Economic and Social Affairs, Population Division) (2019). World Urbanization Prospects 2018: Highlights (ST/ESA/SER.A/421).Google Scholar

Ungaro, F., Calzolari, C., Pistocchi, A., & Malucelli, F. (2014). Modelling the impact of increasing soil sealing on runoff coefficients at regional scale: A hydrogeological approach. Journal of Hydrology & Hydromechanics 62(1): 33–42.Google Scholar

UNISDR (2004). Living with risk. A Global Review of Disaster Reduction Initiatives. Geneva: UNISDR. Available from www.unisdr.org/files/657_lwr21.pdf (Last accessed 21 March 2020).Google Scholar

Vahedifard, F., AghaKouchak, A., & Jafari, N. H. (2016). Compound hazards yield Louisiana flood. Science 353(6306): 1374.Google Scholar

ten Veldhuis, J. A. E., Harder, R. C., & Loog, M. (2010). Automatic classification of municipal call data to support quantitative risk analysis of urban drainage systems. Structure and Infrastructure Engineering 9(2): 1–10.Google Scholar

Vercruysse, K., Dawson, D., & Wright, N. (2019) Interoperability: A conceptual framework to bridge the gap between multi-functional and multi-system urban flood management. Journal of Flood Risk Management 12(S2): e12535.Google Scholar

van Vuuren, D. P., Edmonds, J., Kainuma, M., et al. (2011). The representative concentration pathways: An overview. Climatic Change 109: 5–31.Google Scholar

Waghwala, R. K., & Agnihotri, P. G. (2019). Flood risk assessment and resilience strategies for flood risk management: A case study of Surat City. International Journal of Disaster Risk Reduction 40: 101155.Google Scholar

Wang, Q., Xu, Y., Wang, Y., et al. (2020). Individual and combined impacts of future land-use and climate conditions on extreme hydrological events in a representative basin of the Yangtze River Delta, China. Atmospheric Research 236: 104805.Google Scholar

Wang, Y., Sun, M., & Song, B. (2017). Public perceptions of and willingness to pay for sponge city initiatives in China. Resources, Conservation and Recycling 122: 11–0.Google Scholar

Wang, Y., Zhang, X., Tang, Q., et al. (2019). Assessing flood risk in Baiyangdian Lake area in a changing climate using an integrated hydrological-hydrodynamic modelling. Hydrological Sciences Journal 64(16): 2006–2014.Google Scholar

Wang, Z., Lai, C., Chen, X., Yang, B., Zhao, S., & Bai, X. (2015). Flood hazard risk assessment model based on random forest. Journal of Hydrology 527: 1130–1141.Google Scholar

Ward, P. J., Jongman, B., Weiland, F. S., et al. (2013). Assessing flood risk at the global scale: Model setup, results, and sensitivity. Environmental Research Letters 8(4): 044019.Google Scholar

Watson, K. M., Harwell, G. R., Wallace, D. S., Welborn, T. L., Stengel, V. G., & McDowell, J. S. (2018). Characterization of peak streamflows and flood inundation of selected areas in southeastern Texas and southwestern Louisiana from the August and September 2017 flood resulting from Hurricane Harvey: U.S. Geological Survey Scientific Investigations Report 2018-5070, 44 p., https://doi.org/10.3133/sir20185070.Google Scholar

Winsemius, H. C., Aerts, J. C. J. H., van Beek, L. P. H., et al. (2016). Global drivers of future river flood risk. Nature Climate Change 6: 381–385.Google Scholar

Wisner, B., Blaikie, P. M., Blaikie, P., Cannon, T., & Davis, I. (2004). At Risk: Natural Hazards, People’s Vulnerability and Disasters. New York: Routledge.Google Scholar

Yao, L., Wei, W., & Chen, L. (2016). How does imperviousness impact the urban rainfall-runoff process under various storm cases? Ecological Indicators 60: 893–905.Google Scholar

Yin, Y., Tang, Q., Liu, X., & Zhang, X. (2017). Water scarcity under various socio-economic pathways and its potential effects on food production in the Yellow River Basin. Hydrology and Earth System Sciences 21: 791–804.CrossRef Google Scholar

Zhang, L., Sun, X., & Xue, H. (2019). Identifying critical risks in Sponge City PPP projects using DEMATEL method: A case study of China. Journal of Cleaner Production 226: 949–958.Google Scholar

Zhao, G., Pang, B., Xu, Z., Peng, D., & Xu, L. (2019). Assessment of urban flood susceptibility using semi-supervised machine learning model. Science of the Total Environment 659: 940–949.Google Scholar

Zheng, Z., Qi, S., & Xu, Y. (2013). Questionable frequent occurrence of urban flood hazards in modern cities of China. Natural Hazards 65: 1009–1010.Google Scholar

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15 - Managing Urban Flood Risk and Building Resilience in a Changing Climate

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