Selection, Planning, and Modelling of Nature-Based Solutions for Flood Mitigation
Abstract
:1. Introduction
2. NBS Options for Flood Mitigation
2.1. Retention and Detention Systems
2.2. Bioretention Systems
2.3. Landcover and Soil Management
2.4. River Naturalisation and Floodplain Management
2.5. Wetlands
2.5.1. Natural Wetlands
2.5.2. Constructed Wetlands
2.6. Summary of NBSs’ Strengths, Weaknesses, Opportunities, and Threats
3. Assessing Benefits, Costs, and Performance
Environmental Benefits | Social Benefits |
---|---|
Water and air quality | Noise attenuation |
Erosion/landslide attenuation | Food and raw materials |
Temperature regulation | Recreation |
Habitat connectivity | Tourism |
Soil health | Health and well-being |
Biodiversity | Job opportunities |
Carbon storage | Energy saving |
Groundwater recharge | Property values |
Flood management | Social cohesion |
Water supply |
4. Modelling NBS Hydrology
- The efficacy of NBSs for flood risk management is dependent on the placement of NBSs in relation to water sources and the drainage network, and the individual and cumulative storage of the structures prior to and during flood events.
- NBSs can be effective for reducing the impacts of localised minor floods, but they generally lack the cumulative capacity required to prevent catastrophic flooding associated with extreme rainfall events.
4.1. Model Choice
4.2. Parameterising NBSs
- By changing model parameters and boundary conditions to represent different land cover, drainage pathways, or land use practices as determined by the NBS design (e.g., imperviousness, soil drainage properties, roughness/Manning’s n).
- By adding modules to represent NBSs in existing flood modelling software. This involves adding nodes to detain or retain runoff from one or more modelled flow pathways.
- Are NBSs placed in the optimal position for maximum performance (e.g., slope, soil drainage, flow pathway, or position or in the drainage network)?
- Are NBSs correctly sized for the upstream area, and are sufficient NBSs operating to provide flood mitigation for all downstream areas?
- How will mitigation performance change with time (e.g., due to clogging or maturation of vegetation), and how will operation and level of maintenance influence performance?
5. Discussion: Challenges and Opportunities
5.1. Monitoring Hydrological Impacts for Model Validation
5.2. Evidence of Co-Benefits
5.3. Research Needs
6. Conclusions: Roadmap for Decision-Making for NBS Planning
Supplementary Materials
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Retention and Detention Systems | Bioretention Systems | Landcover and Soil Management | River Restoration and Floodplain Management | Wetlands | |
---|---|---|---|---|---|
STRENGTH: Cost effectiveness | Relatively low cost of implementation. | Relatively low cost of implementation. | Low cost if natural regeneration of vegetation is sufficient for purpose. Moderate cost if replanting and weed management required. | Can become self-maintaining and contribute to carbon sequestration. | Relatively low cost to maintain or restore existing wetlands. Natural landscape features such as swales and gullies can facilitate construction of wetlands. Relatively long operation life and low maintenance costs. |
STRENGTH: Water related benefits | Can achieve both water quantity and quality (reduced sediment, particulate and faecal microbe) control. Can be targeted to manage localised gullying, bank erosion, and flooding. | Bioretention and remediation of contaminants. Reduced sediment loads and transport. Pluvial flood regulation through volume and peak flow attenuation. | Landcover change can increase infiltration, canopy interception, and evapotranspiration, and thus reduce magnitude and temporal response of flood peaks. | Increase stormwater storage and conveyance capacity in flood plain, stream courses. Floodplain connection can decrease the magnitude and duration of downstream floods and improve water quality | Can achieve both water quantity and quality (reduced sediment, particulate, and faecal microbe) control. |
OPPORTUNITY: Socio-economic benefits, Community engagement and Indigenous knowledge | Detention systems enable productive land use between events. Retention systems provide water for stock drinking, firefighting, irrigation. | Job creation, recreational and educational opportunities. | Green spaces increase amenity value. Planting opportunities can be used to introduce culturally significant plant species. | Aesthetic value increases to open mixed-use options. | Maintain greenspace and associated cultural and aesthetic values. Restoration and construction provide job creation, recreational, cultural, and educational opportunities. |
OPPORTUNITY: Other environmental benefits | Can provide water for non-potable uses in urban areas such as for passive urban cooling. | Can improve biodiversity in urban areas. Can provide heat regulation, air quality improvement, carbon storage. | Forest cover can provide carbon sequestration. Green corridors and similar can lead to habitat creation (for birds and fish) and improvements in water quality (e.g., biodiversity, visual clarity, etc). | Opportunities to increase biodiversity and improve habitat integrity. | Opportunities to maintain or enhance biodiversity and improve habitat integrity. |
OPPORTUNITY: Implementation and integrated planning | Can be linked with constructed wetlands to improve performance across a wider range of contaminants and provide a wider range of ecosystem services. | Opportunity to develop and document guidance. | Increased vegetation cover is particularly useful in upper catchments areas or strategically targeted to areas of known high runoff and/or erosion. | Can assist flood plain wetland restoration programmes. | Opportunity to strengthen protection, restore and supplement natural wetland assets. |
Retention and Detention Systems | Bioretention Systems | Landcover and Soil Management | River Restoration and Floodplain Management | Wetlands | |
---|---|---|---|---|---|
WEAKNESS: Limits on efficiency | Limited relative storage capacity in very large events. | Fully efficient only after a “start-up” period (e.g., 8 months to 2 years). Performance of mature systems is subject to change as the systems age (e.g., clogging can happen after several years, e.g., 5–6 years). | Long start-up time related to vegetation growth period, during which space may be more vulnerable to flooding. | Susceptible to damage in the first two to four years after implementation. | Efficiency can be limited due to poor vegetation establishment; for example, in highly permeable soils (require lining) or if prolonged flood or drought conditions occur in the first year after implementation. |
WEAKNESS: Space requirement/scale | Require large numbers distributed across the landscape to moderate widespread flooding. | Can be part of a flood mitigation strategy but may not be sufficient on its own to manage flooding at a catchment scale. | Land acquisition can be challenging. Initial capital costs could be prohibitive to private landowners. | Land acquisition may be required to extend river and riparian areas. Effectiveness depends on floodplain-to-catchment size ratio | Effectiveness depends on wetland-to-catchment size ratio. Lost opportunity value of other potential land uses. |
WEAKNESS: Limited applicability | Require rolling but not-too-steep landscapes that facilitate sufficient ponding with minimal earthworks. | Potential for maladaptation if limited availability of expertise or guidance materials. | May be limited options where soil, climatic, and topographic conditions dictate. | Creation of new riverscapes can be expensive and take time to stabilise. Need surface and channel data and floodplain roughness data critical for planning. | Can be relatively expensive to construct and plant in low-gradient landscapes and where natural plant regeneration cannot be relied on. Vegetated wetlands generally require large areas of relatively shallow water (0.3–0.4 m) but will survive short periods (days) of deeper inundation. |
WEAKNESS: Maintenance and management | Require regular sediment removal to retain storage capacity and limit scouring and remobilisation of accumulated sediments during large storms. | Ongoing maintenance costs. Potential failure of the system if not properly maintained. Uncertain responsibilities for ongoing management. | Any change in land or soil management will likely come with an associated cost. | Maintenance costs for ongoing river widening, weed clearance, sediment removal, riverbank repair. Regular inspections required to check for erosion or damage. | Weed control likely needed during initial establishment. Bunds and water level control structures may be damaged by large flooding events, requiring repair. |
THREAT: Water-related disbenefits | Can increase water temperature and/or cause groundwater contamination. | Can become clogged if fine sediment accumulates in system | Use of monoculture plant assemblages increases the risk of soil erosion and flooding after harvest. | Floodplain complexity in large catchments can make dynamics hard to predict. May behave unpredictably in very large floods. | On-line constructed wetlands may impact fish passage. Wetlands may exacerbate flood risk where there is high groundwater. |
THREAT: Environmental and socio-economic disbenefits | Capture of small ephemeral flows may reduce downstream low flows and associated ecological values. | May increase vector breeding in case of stagnant water (i.e., system failure). | Forestry can be at cost of carbon-rich and biodiverse native ecosystems, and land rights. Monoculture plant assemblages could have negative impact on local biodiversity. | Increased risk of invasive species within created environments. | Risk of invasive and pest species. Open water may increase vector breeding risks in some situations (e.g., mosquitos and midges). |
Cost Effectiveness | Avoided Costs | |
---|---|---|
Project | Housing affordability | Earth working costs |
Development yield | Hard infrastructure/pipes costs | |
Public infrastructure delivery | Impervious area costs | |
Health and wellness affordability | Landscaping costs | |
Property operation costs | ||
Environment | Water quality cost effectiveness | Environmental remediation costs |
Hydrology cost effectiveness | Property remediation and storm damage costs (flooding) | |
Aquatic habitat quality cost effectiveness | Future proofing costs (climate change; resilience) | |
Terrestrial habitat quality cost effectiveness |
Tool Name * | Developer | Assessment Scale | Benefits Assessed | Type of Assessment | Monetisation of Benefits |
---|---|---|---|---|---|
Green Values Calculator (online) | Center for Neighborhood Technology, Chicago, IL, USA (greenvalues.cnt.org (accessed 9 February 2024)) | Small neighbourhood to large watershed | 22 | Qualitative for 16 benefits Quantitative for 6 benefits | Yes, for the 6 quantified benefits (life cycle valuation of the benefits) |
B£ST (2019 version) | Susdrain, London, UK (susdrain.org (accessed 9 February 2024))) | Neighbourhood to small watershed | 20 | Quantitative | Yes |
INFFEWS BCA Tool (2021 version) | Monash University, Melbourne, Australia. (crcwsc.org.au (accessed 9 February 2024))) | Neighbourhood to city scale | 20 | Quantitative | Yes |
InVEST (version 1) | Stanford University, California, CA, USA (naturalcapitalproject.stanford.edu (accessed 9 February 2024))) | Large watershed | 20 | Quantitative | Yes, for some of the benefits |
Nature Value Explorer (online) | Environment Department of the Flemish government, Brussels, Belgium (natuurwaardeverkenner.be (accessed 9 February 2024))) | Small neighbourhood to large watershed | 19 | Qualitative and Quantitative | Yes, for 17 benefits |
i-Tree (v. 2024_6.1.51) | USDA Forest Service, Washington, DC, USA (itreetools.org (accessed 9 February 2024))) | 1 tree to forest | 5 | Quantitative | Yes |
More Than Water tool (2019) | Ministry of Business, innovation and Environment, Wellington, New Zealand (landcareresearch.co.nz (accessed 9 February 2024))) | Neighbourhood | 25 | Qualitative | No |
Co-Benefits | Performance Indicators and/or Quantification Methods |
---|---|
Flood mitigation | Percentage of rainfall leaving a site as runoff; Runoff and volume for high flow events (> 20-year event); Runoff and volume during low flow; Impacts on pre-existing and neighbouring hydrology; Efficiency of site drainage; Exceedance event capacity of site; Flexibility of design to accommodate change |
Air quality Proxies: NO2, PM10, SO2, O3 | Changes in air quality by vegetation based on air pollutant deposition and estimation of leaf area index [154,156,157] or using the i-Tree tool [154]. |
Carbon Storage by vegetation | Sequestration by vegetation can be estimated based on vegetation biomass as done by the i-Tree tool. |
Carbon Storage by soil | Land cover and land use (LULC), climate regions and soil types, and urban-rural areas influence carbon storage in soil. The InVEST tool can be used to estimate such storage for different land uses/covers. |
Increased biodiversity | Extent, significance, and quality of local habitats; Extent of integration with existing biodiversity objectives; Connectivity with neighboring habitats; Resilience and sustainability of created habitats |
Noise Attenuation | Noise reduction can be estimated with average leaf biomass and canopy area of trees and hedges (i.e., Noise Attenuation Potential [157]). |
Water quality Proxies: Nitrogen, phosphorus | Stormwater pollutant retention depending on LULC can be estimated with InVEST. |
Soil health Proxy: bulk density | Bulk density, which can be a proxy for soil quality (e.g., 1.47–1.8 g/cm3 can restrict root growth [158]), is dependent on the soil type and land cover. Vandecasteele et al. [159] provides some estimates of bulk density changes due to LULC changes. |
Recreation and increased amenity value | The size of the area, the proximity to population, the accessibility in terms of transportation and the quality and aesthetic of the space all contribute to the attractiveness of a space for recreational purposes. Usage can be estimated with the travel cost method or the Recreational Opportunity Spectrum (ROS). ROS is based on recreation potential (which can be reflected by the naturalness and presence of protected areas or water bodies) and remoteness or accessibility [160]. Other aspects such as dual function of drainage for recreation, enhancements to visual character, improvements to public safety, improvements in environmental awareness, and education can be accounted for [155]. |
Job creation | Green-space maintenance can serve as a proxy for job creation. Average monthly/annual maintenance hours per unit of green space could be used as indicator. Job and/or business creation for the implementation of an NBS would also contribute to this co-benefit and should be taken into account. |
Property Values | Property costs are driven by many factors, including air quality, noise levels, thermal comfort, and the proximity to green/blue spaces. Cost can be calculated with the hedonic pricing method. Ira [69] reviewed 74 studies worldwide, including various type of NBS such as wetlands, riparian planting, river restauration etc, and reported a 6.04% average price increase for houses near NBSs/green spaces. |
Social cohesion/inclusion | Feeling of ownership, social cohesion, and inclusion can be increased by NBSs, especially during the co-creation process. Once NBSs are implemented, they also promote social contacts and inclusion. The type of NBS can imply the possible interactions (e.g., dry infiltration basins close to a playground may offer more possibilities to interact with others than a wetland). The diversity of incomes of households in proximity to NBSs can give an estimate to “equal access to green spaces”. The potential of co-creation of NBSs can be an indicator of the potential for cohesion and the feeling of ownership of the place. |
NBS Intervention | Types of Models Used | Examples |
---|---|---|
Headwater drainage management | Hydraulic models Hydrological models | Jflow |
Catchment woodland | Opportunity mapping Catchment hydrological models Multiscale models | |
Soil and land management | Catchment hydrological models | WaTEM/SEDEM; SWAT; Hype; INCA; Fieldmouse. |
Retention and detention | Desk-based studies Catchment walkovers Catchment hydrological models Hydraulic models Hydrological–hydraulic models Pond network model | HEC-RAS; Flood Modeller; Overflow; Topmodel; Topcat; 1D flood modeller; Flood modeller; Tuflow; SCIMap; CRUM4 |
Runoff pathway management | 1D and 2D models Hydraulic models | Flood modeller; Tuflow; TopModel; Jflow. |
River restoration | 1D and 2D models Hydraulic models | Flood modeller; Tuflow; Jflow; 1D Flood modeller |
Off-line storage areas | 1D and 2D models Hydrologic and hydraulic models | Excel; Flood modeller; Tuflow |
Floodplain woodland | 1D and 2D models | HEC-RAS; River2D; Overflow |
Floodplain restoration | 1D and 2D models Hydrological-hydraulic models Lumped rainfall runoff models | MIKE SHE/MIKE 11 |
1D Physics-Based cross-Section Analysis | 1D Routing Model with Limited Survey | 1D Hydrodynamic Model with Limited Survey | 1D Model and Survey | 2D Model | 2D Model with Sub-grid Hydraulic Properties | 1D-2D Linked Model | Lumped Parameter Catchment Model | Semi-Distributed Hydrological Model | Fully Distributed Model | |
---|---|---|---|---|---|---|---|---|---|---|
Landscape retention and detention features | Adjust frictional losses per cross-section | Increase attenuation parameter | Increased Manning’s n or reduce inflows | Increased Manning’s n roughness | Increase Manning’s n, or in-line storage | Change time constants in linear cascade | Adjust wave speed and treat as time constant storage | |||
Bioretention systems | ||||||||||
Landcover | Reduce wave speed in routing model | Increase overbank Manning’s n roughness | Increase distributed Manning’s n roughness and hydrological losses | Represent Manning’s n roughness in more detail in 2d areas and hydrological losses | Change maximum soil moisture, storage, Cmax, and quick flow time constants | Change transmissivity, canopy storage, evaporation, overland flow speed, and antecedent wetness. | ||||
Soil management | not applicable | Reduce inflow boundary | Modify losses: reduce rainfall inputs, increase infiltration, and surface roughness. | Changes to Cmax | Increase transmissivity | Vary soil parameters | ||||
River naturalisation | Reduce inflow boundaries | Reduce inflow boundaries, represent increased friction | Modify DTM to increase storage | Change time constants in linear cascade | Increase root-zone or other storage | |||||
Natural wetlands | ||||||||||
Constructed wetlands | ||||||||||
River floodplain and estuary management | Different shear stresses | Increase attenuation parameter in Muskingum unit | Increase storage area capacity | Modify lateral weirs and roughness overbank | Modify DTM to add storage / roughness | Modify DTM to add storage / roughness. Add / remove break-lines | Increase complexity of floodplain representation | Link with detailed hydraulic model |
NBS Intervention | Research Gaps |
---|---|
Retention and detention features |
|
Bioretention areas |
|
Landcover and soil management |
|
River naturalisation |
|
Wetlands |
|
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© 2024 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
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Griffiths, J.; Borne, K.E.; Semadeni-Davies, A.; Tanner, C.C. Selection, Planning, and Modelling of Nature-Based Solutions for Flood Mitigation. Water 2024, 16, 2802. https://doi.org/10.3390/w16192802
Griffiths J, Borne KE, Semadeni-Davies A, Tanner CC. Selection, Planning, and Modelling of Nature-Based Solutions for Flood Mitigation. Water. 2024; 16(19):2802. https://doi.org/10.3390/w16192802
Chicago/Turabian StyleGriffiths, James, Karine E. Borne, Annette Semadeni-Davies, and Chris C. Tanner. 2024. "Selection, Planning, and Modelling of Nature-Based Solutions for Flood Mitigation" Water 16, no. 19: 2802. https://doi.org/10.3390/w16192802
APA StyleGriffiths, J., Borne, K. E., Semadeni-Davies, A., & Tanner, C. C. (2024). Selection, Planning, and Modelling of Nature-Based Solutions for Flood Mitigation. Water, 16(19), 2802. https://doi.org/10.3390/w16192802