Enhancing Flood Resilience and Climate Adaptation: The State of the Art and New Directions for Spatial Planning
Abstract
:1. Introduction
2. The Four Pillars of Resilience Agendas through the Lens of Sustainability
3. The Genesis of Policies, Studies, and Practice to Address Flooding
3.1. Environmental Concerns
3.2. Disaster Management Concerns
3.3. Socio-Economic Concerns
3.4. Institutional and Governance Concerns
3.5. Summary and Discussion
4. The Development of Spatial Planning Research, Policy and Practice Across the Four Pillars of the Flood Resilience Literature
4.1. Limited Attention Paid to Environmental Concerns
4.2. A Focus on Disaster Management Concerns
4.3. A Weak But Emerging Focus on Socio-Economic Concerns
4.4. An Increasing Focus on Institutional and Governance Concerns in the Planning Literature
- Governance products: Some studies reported that policies, strategies, codes, standards, and planning rules provided legal supports and incentives for planning to be involved in flood agendas [124]. Empirically, the literature concentrated on systematic integration of resilience or adaptation agendas into planning programmes, policies, and projects [119], a necessity of functioning tools with more stringent and detailed requirements in the national and regional policies to guide policymakers and planners at lower tiers of government [122,125], and the inclusion of climate information and vulnerability assessment in long-term policy decision-making [114]. The solution to those challenges, as Wilby and Keenan [124] argued, often rests in the collaboration process between multiple stakeholders across policy sectors and levels of government.
- Collaborative process: Increasing numbers of planning studies stress the joint work between planning and extensive actors in the formulation and implementation of resilience and adaptation policies, albeit pointing out that trade-off between governments, planning agencies, hydrological engineers, scientists, civil society, and markets are difficult [114,117,122,126]. A few papers added to this line of argument and reported that mismatches in time-spans and procedures between professions could impair the transboundary cooperation between the planning sector and other sectors [118,120,127]. More research is needed to explore the reasons and solutions to overcome this mismatch.
- Start-conditions for planning to participate flood governance: A small number of studies have cast light on the complexity of the collaborative process in terms of authority, resource and organisation conditions and indicated these pre-sets could affect planning’s performance in the collaborative governance [115,116,122]. For instance, the legal certainty and flexibility of planning tools could influence legal restrictions in land use and policy changes for climatic uncertainty [115,116,122]. Also, suitable allocation of finance and access to information in relation to planning is required to deal with distributional effects of floods (fairness), information sharing between sectors, and the public’s right to be informed [122,128]. Last but not least, the establishment of technical co-working platforms, clarification of planning’s accountability (or responsibilities), and the planners’ knowledge determine the planning agencies’ capacities in flood governance [114,115,119,120,122].
- Contextual factors shaping the start conditions for planning in flood governance: This strand of research on the contextual factors that could affect the pre-conditions for planning in flood governance—from the fixed administrative structures and shared perceptions, to notions, values, and traditions embedded in history—is limited in the planning literature. Early studies reported that fragmented structures in political administration, asymmetries of powers, and persistence in the old paradigms in flood governance could hinder planning agencies in implementing a broader set of adaptation measures in flood agendas [115,119,121]. However, the means to address these challenges relating to contextual conditions remain an under-researched issue.
4.5. Summary and Discussion
5. Discussion and Concluding Remarks
Author Contributions
Funding
Conflicts of Interest
Appendix A
Stages of Floods | Before Floods | During Floods | After Floods | References |
---|---|---|---|---|
Disaster risk reduction:
| (Emergency) response: emergency measures | Recovery: relief, rehabilitation, reconstructions, event documentation and analysis | [31] | |
Prevention: avoiding construction of houses and industries; promoting appropriate land-use, agricultural and forestry practices Protection: structural and nonstructural, to reduce the likelihood of floods or the impacts of a location | Preparedness: informing the population about flood risks and what to do Emergency response: developing emergency response plans | Recovery and lessons learned: activities helping to return to normal conditions | [29] | |
Prevention: spatial planning or land-use policies, insurance Defence: dykes, dams, embankments, weirs, upstream retention | Mitigation: flood compartments, flood-proof constructions Preparedness: warning system, preparing disaster management, evacuation plans, and managing floods when they occur | Recovery: reconstruction or rebuilding plans, compensation, insurance | [88] |
Key Topics | Sub-Topics | Challenges for Resilience and Climate Adaptation | References |
---|---|---|---|
Outputs of flood governance | Official policies/strategies/discourse |
| [54,56,57,71,73] |
Collaborative process | Actors/stakeholders |
| [56,57,73] |
Networks |
| [56,57,70,71,72] | |
Pre-, Start conditions for governance | Authority conditions |
| [56,57,58,69] |
Resource conditions |
| [54,56,57,69] | |
Organisation conditions |
| [54,57,69,73] | |
Contextual roots shaping governance conditions | Institutional features by design |
| [57,71] |
History and culture embedded notions, values and traditions |
| [57,68,71,78] |
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Measures | Statements in Planning Policies/Regulations | Affected (Non-) Structural Interventions in Practice | References |
---|---|---|---|
Avoidance/prevention | Floodplain zoning plans; land acquisition and relocation plans |
| [89,94,105] |
Defence | Multi-purpose/multifunctional engineering measures to deal with coastal and fluvial floods with the consideration of leisure, landscape, and commerce |
| [91,92,93] |
Mitigation | Nature-based infrastructure for coastal flooding reduction, rainfalls detention and retention, and river discharge passage |
| [89,93,94] |
Preparation | Building codes and building controls; evacuation plans; safe havens arrangement |
| [92,95,96,97,106] |
Recovery | Post-recovery plan; critical infrastructure protection |
| [89,99,107] |
Resilience Interventions | Calculation Methods | Findings | References | |
---|---|---|---|---|
Watershed management and function arrangement | Retreating from low-lying areas * | CBA | A high benefit-to-cost ratio for hurricane protection and storm-surge; yet involving high opportunities in costs of lands, like OECD countries | [2,90] |
Zoning plan with a functional arrangement | CEA | High benefits | [110] | |
A change of cultivated lands to natural lands to mitigate loss | MCA | High acceptance of public and private stakeholders in individual risk perception | [108] | |
Building codes/controls | Mobile barriers * | CBA | A high benefit-to-cost ratio | [2] |
Houses with waterproof glass or windows * | CBA | A low benefit-to-cost ratio | [109] | |
Retrofitting building materials against floods * | CBA | High/low benefit-to-cost ratio depending on differences in risk levels, the costs of resilience, existing costs and asset lifetimes, and assumed discount rates locally | [112] | |
Residential building controls reducing severe flood loss from Hurricane Charley by 42% | CEA | High benefits | [110] | |
Multi-purpose engineering measures | Construction of dykes combined with transportation | CBA | A low benefit-to-cost ratio | [109] |
Natural coastal and waterfront buffer zones | A change of cultivated lands to ecological networks | CBA | A high benefit-to-cost ratio | [109] |
Mangroves * | CBA | A high benefit-to-cost ratio; yet an exponentially increase in costs due to land transformation and policy enforcement costs in high-income countries, like the US | [2,111] | |
Water detention base on green space | Rainfall gardens for water storage | CBA | A low benefit-to-cost ratio | [109] |
Key Topics | Sub-Topics | Challenges for Spatial Planning | References |
---|---|---|---|
Outputs of flood governance | Policies, strategies, codes, standards, planning rules |
| [114,119,122,125] |
Collaborative process | Actors/stakeholders |
| [114,117,122,126] |
Networks |
| [118,120,127] | |
Start conditions for planning to participate in flood governance | Authority condition |
| [115,116,122] |
Resource condition |
| [122,128] | |
Organisation condition |
| [114,115,119,120,122] | |
Contextual factors shaping the start conditions for planning in flood governance | Institutional design |
| [115,119] |
Notions, values, and traditions embedded in history and traditions |
| [121] |
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Meng, M.; Dabrowski, M.; Stead, D. Enhancing Flood Resilience and Climate Adaptation: The State of the Art and New Directions for Spatial Planning. Sustainability 2020, 12, 7864. https://doi.org/10.3390/su12197864
Meng M, Dabrowski M, Stead D. Enhancing Flood Resilience and Climate Adaptation: The State of the Art and New Directions for Spatial Planning. Sustainability. 2020; 12(19):7864. https://doi.org/10.3390/su12197864
Chicago/Turabian StyleMeng, Meng, Marcin Dabrowski, and Dominic Stead. 2020. "Enhancing Flood Resilience and Climate Adaptation: The State of the Art and New Directions for Spatial Planning" Sustainability 12, no. 19: 7864. https://doi.org/10.3390/su12197864
APA StyleMeng, M., Dabrowski, M., & Stead, D. (2020). Enhancing Flood Resilience and Climate Adaptation: The State of the Art and New Directions for Spatial Planning. Sustainability, 12(19), 7864. https://doi.org/10.3390/su12197864