Flood control
Flood control (or flood mitigation, protection or alleviation) methods are used to reduce or prevent the detrimental effects of flood waters.[1][2] Flooding can be caused by a mix of both natural processes, such as extreme weather upstream, and human changes to waterbodies and runoff. Flood control methods can be either of the structural type and of the non-structural type. Structural methods hold back floodwaters physically, while non-structural methods do not. Building hard infrastructure to prevent flooding, such as flood walls, is effective at managing flooding. However, best practice within landscape engineering is more and more to rely on soft infrastructure and natural systems, such as marshes and flood plains, for handling the increase in water.
To prevent or manage coastal flooding, coastal management practices have to handle natural processes like tides but also sea level rise due to climate change. Flood control is an important part of climate change adaptation and climate resilience.[3]
Flood control is part of environmental engineering. It involves the management of flood water movement, such as redirecting flood run-off through the use of floodwalls and flood gates, rather than trying to prevent floods altogether. It also involves the management of people, through measures such as evacuation and flood proofing properties. The prevention and mitigation of flooding can be studied on three levels: on individual properties, small communities, and whole towns or cities.
Terminology
[edit]There are a number of similar terms that are all used interchangeably: Flood control, flood mitigation, flood protection and flood alleviation are all terms that mean "the detention and/or diversion of water during flood events for the purpose of reducing discharge or downstream inundation".[4] They include methods that are used to reduce or prevent the detrimental effects of flood waters.[1]
A distinction is made between structural and non-structural flood mitigation:
- Structural flood control is the reduction of the effects of a flood using physical solutions, such as reservoirs, levees, dredging and diversions.
- Non-structural flood control include for example land-use planning, advanced warning systems and flood insurance. Further examples for this type of flood control are: "zoning ordinances and codes, flood forecasting, flood proofing, evacuation and channel clearing, flood fight activities, and upstream land treatment or management to control flood damages without physically restraining flood waters".[5]
Flood management (or flood risk management) is a broader term that includes mitigating and preparing for flooding disasters, and providing risk analysis for example through the practice of flood risk assessment.[6] In the context of natural hazards and disasters, risk management involves "plans, actions, strategies or policies to reduce the likelihood and/or magnitude of adverse potential consequences, based on assessed or perceived risks".[7]
Flood relief methods are used to reduce the effects of flood waters or high water levels.
Causes of flooding
[edit]Floods are caused by many factors or a combination of any of these generally prolonged heavy rainfall (locally concentrated or throughout a catchment area), highly accelerated snowmelt, severe winds over water, unusual high tides, tsunamis, or failure of dams, levees, retention ponds, or other structures that retained the water. Flooding can be exacerbated by increased amounts of impervious surface or by other natural hazards such as wildfires, which reduce the supply of vegetation that can absorb rainfall.
During times of rain, some of the water is retained in ponds or soil, some is absorbed by grass and vegetation, some evaporates, and the rest travels over the land as surface runoff. Floods occur when ponds, lakes, riverbeds, soil, and vegetation cannot absorb all the water.
This has been exacerbated by human activities such as draining wetlands that naturally store large amounts of water and building paved surfaces that do not absorb any water.[8] Water then runs off the land in quantities that cannot be carried within stream channels or retained in natural ponds, lakes, and human-made reservoirs. About 30 percent of all precipitation becomes runoff[9] and that amount might be increased by water from melting snow.Purposes
[edit]Reducing the impacts of floods
[edit]Flooding has many impacts. It damages property and endangers the lives of humans and other species. Rapid water runoff causes soil erosion and concomitant sediment deposition elsewhere (such as further downstream or down a coast). The spawning grounds for fish and other wildlife habitats can become polluted or completely destroyed. Some prolonged high floods can delay traffic in areas which lack elevated roadways. Floods can interfere with drainage and economical use of lands, such as interfering with farming. Structural damage can occur in bridge abutments, bank lines, sewer lines, and other structures within floodways. Waterway navigation and hydroelectric power are often impaired. Financial losses due to floods are typically millions of dollars each year, with the worst floods in recent U.S. history having cost billions of dollars.
Protection of individual properties
[edit]Property owners may fit their homes to stop water entering by blocking doors and air vents, waterproofing important areas and sandbagging the edges of the building. Private precautionary measures are increasingly important in flood risk management.[10]
Flood mitigation at the property level may also involve preventative measures focused on the building site, including scour protection for shoreline developments, improving rainwater in filtration through the use of permeable paving materials and grading away from structures, and inclusion of berms, wetlands or swales in the landscape.[11]
Protection of communities
[edit]When more homes, shops and infrastructure are threatened by the effects of flooding, then the benefits of protection are worth the additional cost. Temporary flood defenses can be constructed in certain locations which are prone to floods and provide protection from rising flood waters. Rivers running through large urban developments are often controlled and channeled. Water rising above a canal's full capacity may cause flooding to spread to other waterways and areas of the community, which causes damage. Defenses (both long-term and short-term) can be constructed to minimize damage, which involves raising the edge of the water with levees, embankments or walls. The high population and value of infrastructure at risk often justifies the high cost of mitigation in larger urban areas.
Protection of wider areas such as towns or cities
[edit]The most effective way of reducing the risk to people and property is through the production of flood risk maps. Most countries have produced maps which show areas prone to flooding based on flood data. In the UK, the Environment Agency has produced maps which show areas at risk. The map to the right shows a flood map for the City of York, including the floodplain for a 1 in 100-year flood (dark blue), the predicted floodplain for a 1 in 1000 year flood (light blue) and low-lying areas in need of flood defence (purple). The most sustainable way of reducing risk is to prevent further development in flood-prone areas and old waterways. It is important for at-risk communities to develop a comprehensive Floodplain Management plan.[12]
In the US, communities that participate in the National Flood Insurance Program must agree to regulate development in flood-prone areas.
Strategic retreat
[edit]One way of reducing the damage caused by flooding is to remove buildings from flood-prone areas, leaving them as parks or returning them to wilderness. Floodplain buyout programs have been operated in places like New Jersey (both before and after Hurricane Sandy),[13] Charlotte, North Carolina,[14] and Missouri.[15]
In the United States, FEMA produces flood insurance rate maps that identify areas of future risk, enabling local governments to apply zoning regulations to prevent or minimize property damage.
Resilience
[edit]Buildings and other urban infrastructure can be designed so that even if a flood does happen, the city can recover quickly and costs are minimized. For example, homes can be put on stilts,[16] electrical and HVAC equipment can be put on the roof instead of in the basement, and subway entrances and tunnels can have built-in movable water barriers.[17] New York City began a substantial effort to plan and build for flood resilience after Hurricane Sandy.[18] Flood resilience technologies support the fast recovery of individuals and communities affected, but their use remains limited.[19]
Climate change adaptation
[edit]Flooding can occur in cities or towns as urban flooding. It can also take place by the sea as coastal flooding. Sea level rise can make coastal flooding worse. In some areas there are also risks of glacial lake outburst floods.
There are many adaptation options for flooding:[20]
- Installing better flood defences such as flood barriers, sea walls and increased pumping capacity[21]
- Installing devices to prevent seawater from backflowing into storm drains[22]
- Rainwater storage to deal with increased run-off from rainfall. This includes reducing paved areas or changing to water-permeable pavements, adding water-buffering vegetation, adding underground storage tanks, and subsidizing household rain barrels[23][24]
- Raising pumps at wastewater treatment plants[22]
- Buying out homeowners in flood-prone areas[25]
- Raising street level to prevent flooding[21]
- Using and protecting mangroves[26]
- Glacial lakes in danger of outburst flooding can have their moraines replaced with concrete dams to provide protection. This may also provide hydroelectric power[27]
More frequent drenching rains may make it necessary to increase the capacity of stormwater systems. This separates stormwater from blackwater, so that overflows in peak periods do not contaminate rivers. One example is the SMART Tunnel in Kuala Lumpur.
New York City produced a comprehensive report for its Rebuilding and Resiliency initiative after Hurricane Sandy. It includes making buildings less prone to flooding. It also aims to make specific problems encountered during and after the storm less likely to recur. These include weeks-long fuel shortages even in unaffected areas due to legal and transportation problems, flooded health care facilities, insurance premium increases, damage to electricity and steam generation and distribution networks, and flooding of subway and roadway tunnels.[28]Structural methods
[edit]Some methods of flood control have been practiced since ancient times.[2] These methods include planting vegetation to retain extra water, terracing hillsides to slow flow downhill, and the construction of floodways (man-made channels to divert floodwater).[2] Other techniques include the construction of levees, lakes, dams, reservoirs,[2] retention ponds to hold extra water during times of flooding.
Dams
[edit]Many dams and their associated reservoirs are designed completely or partially to aid in flood protection and control. Many large dams have flood-control reservations in which the level of a reservoir must be kept below a certain elevation before the onset of the rainy/summer melt season to allow a certain amount of space in which floodwaters can fill. Other beneficial uses of dam created reservoirs include hydroelectric power generation, water conservation, and recreation. Reservoir and dam construction and design is based upon standards, typically set out by the government. In the United States, dam and reservoir design is regulated by the US Army Corps of Engineers (USACE). Design of a dam and reservoir follows guidelines set by the USACE and covers topics such as design flow rates in consideration to meteorological, topographic, streamflow, and soil data for the watershed above the structure.[29]
The term dry dam refers to a dam that serves purely for flood control without any conservation storage (e.g. Mount Morris Dam, Seven Oaks Dam).
Diversion canals
[edit]Floodplains and groundwater replenishment
[edit]Excess water can be used for groundwater replenishment by diversion onto land that can absorb the water. This technique can reduce the impact of later droughts by using the ground as a natural reservoir. It is being used in California, where orchards and vineyards can be flooded without damaging crops,[30] or in other places wilderness areas have been re-engineered to act as floodplains.[31]
River defenses
[edit]In many countries, rivers are prone to floods and are often carefully managed. Defenses such as levees, bunds, reservoirs, and weirs are used to prevent rivers from bursting their banks. A weir, also known as a lowhead dam, is most often used to create millponds, but on the Humber River in Toronto, a weir was built near Raymore Drive to prevent a recurrence of the flood damage caused by Hurricane Hazel in October 1954.
The Leeds flood alleviation scheme uses movable weirs which are lowered during periods of high water to reduce the chances of flooding upstream. Two such weirs, the first in the UK, were installed on the River Aire in October 2017 at Crown Point, Leeds city centre and Knostrop. The Knostrop weir was operated during the 2019 England floods. They are designed to reduce potential flood levels by up to one metre.[32]
Coastal defenses
[edit]Coastal flooding has been addressed with coastal defenses, such as sea walls, beach nourishment, and barrier islands.
Tide gates are used in conjunction with dykes and culverts. They can be placed at the mouth of streams or small rivers, where an estuary begins or where tributary streams, or drainage ditches connect to sloughs. Tide gates close during incoming tides to prevent tidal waters from moving upland, and open during outgoing tides to allow waters to drain out via the culvert and into the estuary side of the dike. The opening and closing of the gates is driven by a difference in water level on either side of the gate.
Flood barrier
[edit]A flood barrier, surge barrier or storm surge barrier is a specific type of floodgate, designed to prevent a storm surge or spring tide from flooding the protected area behind the barrier. A surge barrier is almost always part of a larger flood protection system consisting of floodwalls, levees (also known as dikes), and other constructions and natural geographical features.
Flood barrier may also refer to barriers placed around or at individual buildings to keep floodwaters from entering the buildings.Self-closing flood barrier
[edit]The self-closing flood barrier (SCFB) is a flood defense system designed to protect people and property from inland waterway floods caused by heavy rainfall, gales, or rapid melting snow.[citation needed] The SCFB can be built to protect residential properties and whole communities, as well as industrial or other strategic areas. The barrier system is constantly ready to deploy in a flood situation, it can be installed in any length and uses the rising flood water to deploy.
Temporary perimeter barriers
[edit]When permanent defenses fail, emergency measures such as sandbags or inflatable impermeable sacks are used.
In 1988, a method of using water to control flooding was discovered. This was accomplished by containing 2 parallel tubes within a third outer tube. When filled, this structure formed a non-rolling wall of water that can control 80 percent of its height in external water depth, with dry ground behind it. Eight foot tall water filled barriers were used to surround Fort Calhoun Nuclear Generating Station during the 2011 Missouri River Flooding. Instead of trucking in sandbag material for a flood, stacking it, then trucking it out to a hazmat disposal site, flood control can be accomplished by using the on site water. However, these are not fool proof. A 8 feet (2.4 m) high 2,000 feet (610 m) long water filled rubber flood berm that surrounded portions of the plant was punctured by a skid-steer loader and it collapsed flooding a portion of the facility.[33]
In 1999, a group of Norwegian engineers patented a transportable, removable, and reusable flood barrier which uses the water's weight against itself. This removable flood panels protect cities and public utilities.[34][promotion?]
Other solutions, such as HydroSack, are polypropylene exteriors with wood pulp within, though they are one-time use.[35]
Non-structural methods
[edit]There are several methods of non-structural flood control that form part of flood risk management strategies. These can involve policy that reduces the amount of urban structures built around floodplains or flood prone areas through land zoning regulations.[6][10] This helps to reduce the amount of mitigation needed to protect humans and buildings from flooding events. Similarly, flood warning systems are important for reducing risks.[6] Following the occurrence of flooding events, other measures such as rebuilding plans and insurance can be integrated into flood risk management plans.[6] Flood risk management strategy diversification is needed to ensure that management strategies cover several different scenarios and ensure best practices.[36]
Flood mapping
[edit]Flood mapping is a tool used by governments and policy makers to delineate the borders of potential flooding events, allowing educated decisions to prevent extreme flooding events.[37] Flood maps are useful to create documentation that allows policy makers to make informed decisions about flood hazards.[38] Flood mapping also provides conceptual models to both the public and private sectors with information about flooding hazards.[39] Flood mapping has been criticized in many areas around the world, due to the absence of public accessibility, technical writing and data, and lack of easy-to-understand information. However, revived attention towards flood mapping has renewed the interest in enhancing current flood mapping for use as a flood risk management method.[38]
Flood modelling
[edit]Flood modelling is a tool used to model flood hazard and the effects on humans and the physical environment.[40] Flood modelling takes into consideration how flood hazards, external and internal processes and factors, and the main drivers of floods interact with each other. Flood modelling combines factors such as terrain, hydrology, and urban topography to reproduce the evolution of a flood in order to identify the different levels of flooding risks associated with each element exposed.[41] The modelling can be carried out using hydraulic models,[42] conceptual models,[43] or geomorphic methods.[44] Nowadays, there is a growing attention also in the production of maps obtained with remote sensing.[45] Flood modelling is helpful for determining building development practices and hazard mitigation methods that reduce the risks associated with flooding.[46]
Stakeholder engagement
[edit]Stakeholder engagement is a useful tool for flood risk management that allows enhanced public engagement for agreements to be reached on policy discussions.[47] Different management considerations can be taken into account including emergency management and disaster risk reduction goals, interactions of land-use planning with the integration of flood risks and required policies.[38] In flood management, stakeholder engagement is seen as an important way to achieve greater cohesion and consensus.[48] Integrating stakeholder engagement into flood management often provides a more complex analysis of the situation; this generally adds more demand in determining collective solutions and increases the time it takes to determine solutions.[47]
Flood risk assessment
[edit]Flood risk management (FRM) aims to reduce the human and socio-economic losses caused by flooding and is part of the larger field of risk management. Flood risk management analyzes the relationships between physical systems and socio-economic environments through flood risk assessment and tries to create understanding and action about the risks posed by flooding. The relationships cover a wide range of topics, from drivers and natural processes, to models and socio-economic consequences. [vague]
This relationship examines management methods which includes a wide range of flood management methods including but are not limited to flood mapping and physical implication measures.[49] FRM looks at how to reduce flood risk and how to appropriately manage risks that are associated with flooding. Flood risk management includes mitigating and preparing for flooding disasters, analyzing risk, and providing a risk analysis system to mitigate the negative impacts caused by flooding.[49]
Flooding and flood risk are especially important with more extreme weather and sea level rise caused by climate change as more areas will be effected by flood risk.[50]
Costs
[edit]The costs of flood protection rise as more people and property are to be protected. The US FEMA, for example, estimates that for every $1.00 spent on mitigation, $4.00 is saved.[51]
Examples by country
[edit]North America
[edit]Canada
[edit]An elaborate system of flood way defenses can be found in the Canadian province of Manitoba. The Red River flows northward from the United States, passing through the city of Winnipeg (where it meets the Assiniboine River) and into Lake Winnipeg. As is the case with all north-flowing rivers in the temperate zone of the Northern Hemisphere, snow melt in southern sections may cause river levels to rise before northern sections have had a chance to completely thaw. This can lead to devastating flooding, as occurred in Winnipeg during the spring of 1950. To protect the city from future floods, the Manitoba government undertook the construction of a massive system of diversions, dikes, and flood ways (including the Red River Floodway and the Portage Diversion). The system kept Winnipeg safe during the 1997 flood which devastated many communities upriver from Winnipeg, including Grand Forks, North Dakota and Ste. Agathe, Manitoba.[citation needed]
United States
[edit]In the United States, the U.S. Army Corps of Engineers is the lead flood control agency.[52] After Hurricane Sandy, New York City's Metropolitan Transportation Authority (MTA) initiated multiple flood barrier projects to protect the transit assets in Manhattan. In one case, the MTA's New York City Transit Authority (NYCT) sealed subway entrances in lower Manhattan using a deployable fabric cover system called Flex-Gate,[53] a system that protects the subway entrances against 14 feet (4.3 m) of water.[54] Extreme storm flood protection levels have been revised based on new Federal Emergency Management Agency guidelines for 100-year and 500-year design flood elevations.[55][56]
In the New Orleans Metropolitan Area, 35 percent of which sits below sea level, is protected by hundreds of miles of levees and flood gates. This system failed catastrophically, with numerous breaks, during Hurricane Katrina (2005) in the city proper and in eastern sections of the Metro Area, resulting in the inundation of approximately 50 percent of the metropolitan area, ranging from a few inches to twenty feet in coastal communities.
The Morganza Spillway provides a method of diverting water from the Mississippi River when a river flood threatens New Orleans, Baton Rouge and other major cities on the lower Mississippi. It is the largest of a system of spillways and floodways along the Mississippi. Completed in 1954, the spillway has been opened twice, in 1973 and in 2011.[citation needed]
In an act of successful flood prevention, the federal government offered to buy out flood-prone properties in the United States in order to prevent repeated disasters after the 1993 flood across the Midwest. Several communities accepted and the government, in partnership with the state, bought 25,000 properties which they converted into wetlands. These wetlands act as a sponge in storms and in 1995, when the floods returned, the government did not have to expend resources in those areas.[57]
Asia
[edit]In Kyoto, Japan, the Hata clan successfully controlled floods on the Katsura River in around 500 A.D and also constructed a sluice on the Kazuno River.[58]
In China flood diversion areas are rural areas that are deliberately flooded in emergencies in order to protect cities.[59]
The consequences of deforestation and changing land use on the risk and severity of flooding are subjects of discussion. In assessing the impacts of Himalayan deforestation on the Ganges-Brahmaputra Lowlands, it was found that forests would not have prevented or significantly reduced flooding in the case of an extreme weather event.[60] However, more general or overview studies agree on the negative impacts that deforestation has on flood safety - and the positive effects of wise land use and reforestation.[61][62]
Many have proposed that loss of vegetation (deforestation) will lead to an increased risk of flooding. With natural forest cover the flood duration should decrease. Reducing the rate of deforestation should improve the incidents and severity of floods.[63]
Africa
[edit]In Egypt, both the Aswan Low Dam (1902) and the Aswan High Dam (1976) have controlled various amounts of flooding along the Nile River.
Europe
[edit]France
[edit]Following the misery and destruction caused by the 1910 Great Flood of Paris, the French government built a series of reservoirs called Les Grands Lacs de Seine (or Great Lakes) which helps remove pressure from the Seine during floods, especially the regular winter flooding.[64]
United Kingdom
[edit]London is protected from flooding by Thames Barrier, a huge mechanical barrier across the River Thames, which is raised when the water level reaches a certain point. This project has been operational since 1982 and was designed to protect against a surge of water such as the North Sea flood of 1953.
In 2023 it was found that over 4,000 flood defence schemes in England were ‘almost useless’ with many of them in areas hit by Storm Babet.[65]
Russia
[edit]The Saint Petersburg Dam was completed in 2008 to protect Saint Petersburg from storm surges. It also has a main traffic function, as it completes a ring road around Saint Petersburg. Eleven dams extend for 25.4 kilometres (15.8 mi) and stand 8 metres (26 ft) above water level.
The Netherlands
[edit]The Netherlands has one of the best flood control systems in the world, notably through its construction of dykes. The country faces high flooding risk due to the country's low-lying landscapes.[66] The largest and most elaborate flood defenses are referred to as the Delta Works with the Oosterscheldekering as its crowning achievement. These works in the southwestern part of the country were built in response to the North Sea flood of 1953. The Dutch had already built one of the world's largest dams in the north of the country. The Afsluitdijk closing occurred in 1932.
New ways to deal with water are constantly being developed and tested, such as the underground storage of water, storing water in reservoirs in large parking garages or on playgrounds,[67][68] Rotterdam started a project to construct a floating housing development of 120 acres (0.49 km2) to deal with rising sea levels.[69] Several approaches, from high-tech sensors detecting imminent levee failure to movable semi-circular structures closing an entire river, are being developed or used around the world. Regular maintenance of hydraulic structures, however, is another crucial part of flood control.[70]
Oceania
[edit]Flooding is the greatest natural hazard in New Zealand (Aotearoa),[71] and its control is primarily managed and funded by local councils.[72] Throughout the country there is a network of more than 5284 km of levees,[73] while gravel extraction to lower river water levels is also a popular flood control technique.[74][75] The management of flooding in the country is shifting towards nature based solutions,[76] such as the widening of the Hutt River channel in Wellington.[77]
See also
[edit]References
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(help) - ^ Abebe, Yared Abayneh; Ghorbani, Amineh; Nikolic, Igor; Vojinovic, Zoran; Sanchez, Arlex (2019-01-01). "A coupled flood-agent-institution modelling (CLAIM) framework for urban flood risk management". Environmental Modelling & Software. 111: 483–492. doi:10.1016/j.envsoft.2018.10.015. ISSN 1364-8152. S2CID 54459631.
- ^ Almeida, Gustavo De; Bates, Paul; Ozdemir, Hasan (2016-11-07). "Modeling urban floods at submeter resolution: challenges or opportunities for flood risk management?". Journal of Flood Risk Management. 11: S855–S865. doi:10.1111/jfr3.12276. ISSN 1753-318X. S2CID 59940176.
- ^ Şen, Zekâi (2018). Flood modeling, prediction and mitigation. Cham, Switzerland. ISBN 978-3-319-52356-9. OCLC 1011501335.
{{cite book}}
: CS1 maint: location missing publisher (link) - ^ Gomes Miguez, Marcelo; Peres Battemarco, Bruna; Martins De Sousa, Matheus; Moura Rezende, Osvaldo; Pires Veról, Aline; Gusmaroli, Giancarlo (2017-06-21). "Urban Flood Simulation Using MODCEL—An Alternative Quasi-2D Conceptual Model". Water. 9 (6): 445. doi:10.3390/w9060445. ISSN 2073-4441.
- ^ Manfreda, Salvatore; Di Leo, Margherita; Sole, Aurelia (October 2011). "Detection of Flood-Prone Areas Using Digital Elevation Models". Journal of Hydrologic Engineering. 16 (10): 781–790. doi:10.1061/(ASCE)HE.1943-5584.0000367. ISSN 1084-0699.
- ^ Ajmar, Andrea; Boccardo, Piero; Broglia, Marco; Kucera, Jan; Giulio-Tonolo, Fabio; Wania, Annett (2017-07-07), Molinari, Daniela; Menoni, Scira; Ballio, Francesco (eds.), "Response to Flood Events: The Role of Satellite-based Emergency Mapping and the Experience of the Copernicus Emergency Management Service", Geophysical Monograph Series, Hoboken, NJ, USA: John Wiley & Sons, Inc., pp. 211–228, doi:10.1002/9781119217930.ch14, ISBN 978-1-119-21793-0, retrieved 2023-02-15
- ^ Abebe, Yared Abayneh; Ghorbani, Amineh; Nikolic, Igor; Vojinovic, Zoran; Sanchez, Arlex (2019-10-15). "Flood risk management in Sint Maarten – A coupled agent-based and flood modelling method". Journal of Environmental Management. 248: 109317. doi:10.1016/j.jenvman.2019.109317. ISSN 0301-4797. PMID 31394474. S2CID 199507673.
- ^ a b Thaler, Thomas; Levin-Keitel, Meike (2016-01-01). "Multi-level stakeholder engagement in flood risk management—A question of roles and power: Lessons from England". Environmental Science & Policy. Participatory and Collaborative Governance for Sustainable Flood Risk Management: An emerging research agenda. 55: 292–301. doi:10.1016/j.envsci.2015.04.007. ISSN 1462-9011.
- ^ Thale, Thomas; Priest, Sally (2016). "Partnership Funding in flood risk management: multi-level stakeholder engagement – a question of roles and power". E3S Web of Conferences. 7: 20009. doi:10.1051/e3sconf/20160720009. ISSN 2267-1242.
- ^ a b Plate, Erich J. (2002-10-01). "Flood risk and flood management". Journal of Hydrology. Advances in Flood Research. 267 (1): 2–11. Bibcode:2002JHyd..267....2P. doi:10.1016/S0022-1694(02)00135-X. ISSN 0022-1694.
- ^ da Silva, Lucas Borges Leal; Alencar, Marcelo Hazin; de Almeida, Adiel Teixeira (2020-11-01). "Multidimensional flood risk management under climate changes: Bibliometric analysis, trends and strategic guidelines for decision-making in urban dynamics". International Journal of Disaster Risk Reduction. 50: 101865. Bibcode:2020IJDRR..5001865D. doi:10.1016/j.ijdrr.2020.101865. ISSN 2212-4209. S2CID 224900317.
- ^ "What is Hazard Mitigation?". Pennsylvania Emergency Management Agency. Retrieved 2014-04-07.
- ^ U.S. Army Corps of Engineers, Washington, DC."Civil Works." Accessed 2014-01-24.
- ^ Schlossberg, Tatiana (October 29, 2015). "New York Today: In Hurricane Sandy's Wake". The New York Times. Retrieved December 3, 2015.
- ^ "Anti-flood system rolled out in a lower Manhattan subway". Reuters. November 19, 2015. Archived from the original on December 8, 2015. Retrieved December 3, 2015.
- ^ "Flood Maps". Retrieved December 3, 2015.
- ^ "How to Read a Flood Map". Retrieved December 3, 2015.
- ^ Ripley, Amanda (2006-08-28). "Floods, Tornadoes, Hurricanes, Wildfires, Earthquakes... Why We Don't Prepare." Time.
- ^ "History of Kyoto". Kyoto City Council. 2004. Retrieved 11 January 2018.
- ^ "China blows up seventh dike to divert flooding." China Daily. 2003-07-07.
- ^ Hamilton, Lawrence S (1987). "What Are the Impacts of Himalayan Deforestation on the Ganges-Brahmaputra Lowlands and Delta? Assumptions and Facts". Mountain Research and Development. 7 (3). Bern: International Mountain Society: 256–263. doi:10.2307/3673202. JSTOR 3673202.
- ^ Semi, Naginder S (1989). "The Hydrology of Disastrous floods in Asia: An Overview" (PDF). Hydrology and Water Resources Department. London: James & James Science Publishers. Archived from the original (PDF) on 24 July 2011. Retrieved 15 September 2010.
- ^ Bradshaw, CJ; Sodhi, NS; Peh, SH; Brook, BW (2007). "Global evidence that deforestation amplifies flood risk and severity in the developing world". Global Change Biology. 13 (11): 2379–2395. Bibcode:2007GCBio..13.2379B. doi:10.1111/j.1365-2486.2007.01446.x. S2CID 53608837.
- ^ Bradshaw, CJ; Sodhi, NS; Peh, SH; Brook, BW (2007). "Global evidence that deforestation amplifies flood risk and severity in the developing. Also a flood has recently hit Pakistan which is said to be more devastating than the Tsunami of 2005". Global Change Biology. 13 (11): 2379–2395. Bibcode:2007GCBio..13.2379B. doi:10.1111/j.1365-2486.2007.01446.x. S2CID 53608837.
- ^ See Jeffrey H. Jackson, Paris Under Water: How the City of Light Survived the Great Flood of 1910 (New York: Palgrave Macmillan, 2010).
- ^ Halliday, Josh (30 October 2023). "More than 4,000 English flood defences 'almost useless', analysis finds". The Guardian. ISSN 0261-3077. Archived from the original on 30 October 2023. Retrieved 30 October 2023.
- ^ Eijgenraam, Carel; Brekelmans, Ruud; Hertog, Dick den; Roos, Kees (2017). "Optimal Strategies for Flood Prevention". Management Science. 63 (5): 1644–1656. doi:10.1287/mnsc.2015.2395.
- ^ "In pictures: Rotterdam strengthens sea defences". BBC News. 27 November 2009.
- ^ http://water.dhv.com/EN/Water_management/Documents/2008%20Leaflet%20Innovative%20water%20storage%20techniques.pdf[permanent dead link]
- ^ Palca, Joe (2008-01-28). "Dutch Architects Plan for a Floating Future." National Public Radio, Washington, DC.
- ^ Broad, William J. (6 September 2005). "In Europe, High-Tech Flood Control, With Nature's Help". The New York Times.
- ^ Meeting the Challenges of Future Flooding in New Zealand (PDF) (Report). Ministry for the Environment (New Zealand). 2008. p. v.
- ^ Ko Tatou LGNZ (6 April 2022). "$1.5 billion urgently needed to protect New Zealanders from floods – investment support from government falling woefully short". Retrieved 3 March 2023.
- ^ Crawford-Flett, Kaley; Blake, Daniel M.; Pascoal, Eduardo; Wilson, Matthew; Wotherspoon, Liam (2022). "A standardised inventory for New Zealand's stopbank (levee) network and its application for natural hazard exposure assessments". Journal of Flood Risk Management. 15 (2): e12777. Bibcode:2022JFRM...15E2777C. doi:10.1111/jfr3.12777. S2CID 244541176.
- ^ McSaveney, E (12 June 2006). "'Floods'- Flood control". Te Ara the Encyclopedia of New Zealand. Retrieved 3 March 2023.
- ^ Kelly, D.; McKerchar, A.; Hicks, M. (2005). "Making concrete: ecological implications of gravel extraction in New Zealand rivers". Water & Atmosphere. 13 (1): 20–21.
- ^ Ministry for the Environment (2022). Aotearoa New Zealand's first emissions reduction plan: Chapter 4: Working with Nature. The New Zealand Government.
- ^ Tukua Ngā Awa Kei Rere [Making Room for Rivers] (PDF). Forest and Bird. 2022. p. 3.
External links
[edit]- Flood articles – BBC News