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100-year flood

January 01, 1970

For other uses, see 100-year flood (disambiguation).

A 100-year flood is a flood event that has on average a 1 in 100 chance (1% probability) of being equaled or exceeded in any given year.[1]

Mississippi River at Kaskaskia, Illinois, during the Great Flood of 1993

The 100-year flood is also referred to as the 1% flood.[2] For coastal or lake flooding, the 100-year flood is generally expressed as a flood elevation or depth, and may include wave effects. For river systems, the 100-year flood is generally expressed as a flowrate. Based on the expected 100-year flood flow rate, the flood water level can be mapped as an area of inundation. The resulting floodplain map is referred to as the 100-year floodplain. Estimates of the 100-year flood flowrate and other streamflow statistics for any stream in the United States are available.[3] In the UK, the Environment Agency publishes a comprehensive map of all areas at risk of a 1 in 100 year flood.[4] Areas near the coast of an ocean or large lake also can be flooded by combinations of tide, storm surge, and waves.[5] Maps of the riverine or coastal 100-year floodplain may figure importantly in building permits, environmental regulations, and flood insurance. These analyses generally represent 20th-century climate.

Probability edit

A common misunderstanding is that a 100-year flood is likely to occur only once in a 100-year period. In fact, there is approximately a 63.4% chance of one or more 100-year floods occurring in any 100-year period. On the Danube River at Passau, Germany, the actual intervals between 100-year floods during 1501 to 2013 ranged from 37 to 192 years.[6] The probability Pe that one or more floods occurring during any period will exceed a given flood threshold can be expressed, using the binomial distribution, as

 

where T is the threshold return period (e.g. 100-yr, 50-yr, 25-yr, and so forth), and n is the number of years in the period. The probability of exceedance Pe is also described as the natural, inherent, or hydrologic risk of failure.[7][8] However, the expected value of the number of 100-year floods occurring in any 100-year period is 1.

Ten-year floods have a 10% chance of occurring in any given year (Pe =0.10); 500-year have a 0.2% chance of occurring in any given year (Pe =0.002); etc. The percent chance of an X-year flood occurring in a single year is 100/X. A similar analysis is commonly applied to coastal flooding or rainfall data. The recurrence interval of a storm is rarely identical to that of an associated riverine flood, because of rainfall timing and location variations among different drainage basins.

The field of extreme value theory was created to model rare events such as 100-year floods for the purposes of civil engineering. This theory is most commonly applied to the maximum or minimum observed stream flows of a given river. In desert areas where there are only ephemeral washes, this method is applied to the maximum observed rainfall over a given period of time (24-hours, 6-hours, or 3-hours). The extreme value analysis only considers the most extreme event observed in a given year. So, between the large spring runoff and a heavy summer rain storm, whichever resulted in more runoff would be considered the extreme event, while the smaller event would be ignored in the analysis (even though both may have been capable of causing terrible flooding in their own right).

Statistical assumptions edit

There are a number of assumptions that are made to complete the analysis that determines the 100-year flood. First, the extreme events observed in each year must be independent from year to year. In other words, the maximum river flow rate from 1984 cannot be found to be significantly correlated with the observed flow rate in 1985, which cannot be correlated with 1986, and so forth. The second assumption is that the observed extreme events must come from the same probability density function. The third assumption is that the probability distribution relates to the largest storm (rainfall or river flow rate measurement) that occurs in any one year. The fourth assumption is that the probability distribution function is stationary, meaning that the mean (average), standard deviation and maximum and minimum values are not increasing or decreasing over time. This concept is referred to as stationarity.[8][9]

The first assumption is often but not always valid and should be tested on a case-by-case basis. The second assumption is often valid if the extreme events are observed under similar climate conditions. For example, if the extreme events on record all come from late summer thunderstorms (as is the case in the southwest U.S.), or from snow pack melting (as is the case in north-central U.S.), then this assumption should be valid. If, however, there are some extreme events taken from thunder storms, others from snow pack melting, and others from hurricanes, then this assumption is most likely not valid. The third assumption is only a problem when trying to forecast a low, but maximum flow event (for example, an event smaller than a 2-year flood). Since this is not typically a goal in extreme analysis, or in civil engineering design, then the situation rarely presents itself.

The final assumption about stationarity is difficult to test from data for a single site because of the large uncertainties in even the longest flood records[6] (see next section). More broadly, substantial evidence of climate change strongly suggests that the probability distribution is also changing[10] and that managing flood risks in the future will become even more difficult.[11] The simplest implication of this is that most of the historical data represent 20th-century climate and might not be valid for extreme event analysis in the 21st century.

Probability uncertainty edit

When these assumptions are violated, there is an unknown amount of uncertainty introduced into the reported value of what the 100-year flood means in terms of rainfall intensity, or flood depth. When all of the inputs are known, the uncertainty can be measured in the form of a confidence interval. For example, one might say there is a 95% chance that the 100-year flood is greater than X, but less than Y.[2]

Direct statistical analysis[9][12] to estimate the 100-year riverine flood is possible only at the relatively few locations where an annual series of maximum instantaneous flood discharges has been recorded. In the United States as of 2014, taxpayers have supported such records for at least 60 years at fewer than 2,600 locations, for at least 90 years at fewer than 500, and for at least 120 years at only 11.[13] For comparison, the total area of the nation is about 3,800,000 square miles (9,800,000 km2), so there are perhaps 3,000 stream reaches that drain watersheds of 1,000 square miles (2,600 km2) and 300,000 reaches that drain 10 square miles (26 km2). In urban areas, 100-year flood estimates are needed for watersheds as small as 1 square mile (2.6 km2). For reaches without sufficient data for direct analysis, 100-year flood estimates are derived from indirect statistical analysis of flood records at other locations in a hydrologically similar region or from other hydrologic models. Similarly for coastal floods, tide gauge data exist for only about 1,450 sites worldwide, of which only about 950 added information to the global data center between January 2010 and March 2016.[14]

 
High-water scale 1501–2002 at Passau, Germany, as of September 2012

Much longer records of flood elevations exist at a few locations around the world, such as the Danube River at Passau, Germany, but they must be evaluated carefully for accuracy and completeness before any statistical interpretation.

For an individual stream reach, the uncertainties in any analysis can be large, so 100-year flood estimates have large individual uncertainties for most stream reaches.[6]: 24  For the largest recorded flood at any specific location, or any potentially larger event, the recurrence interval always is poorly known.[6]: 20, 24  Spatial variability adds more uncertainty, because a flood peak observed at different locations on the same stream during the same event commonly represents a different recurrence interval at each location.[6]: 20  If an extreme storm drops enough rain on one branch of a river to cause a 100-year flood, but no rain falls over another branch, the flood wave downstream from their junction might have a recurrence interval of only 10 years. Conversely, a storm that produces a 25-year flood simultaneously in each branch might form a 100-year flood downstream. During a time of flooding, news accounts necessarily simplify the story by reporting the greatest damage and largest recurrence interval estimated at any location. The public can easily and incorrectly conclude that the recurrence interval applies to all stream reaches in the flood area.[6]: 7, 24 

Observed intervals between floods edit

 
Observed intervals between floods at Passau, 1501–2013

Peak elevations of 14 floods as early as 1501 on the Danube River at Passau, Germany, reveal great variability in the actual intervals between floods.[6]: 16–19  Flood events greater than the 50-year flood occurred at intervals of 4 to 192 years since 1501, and the 50-year flood of 2002 was followed only 11 years later by a 500-year flood. Only half of the intervals between 50- and 100-year floods were within 50 percent of the nominal average interval. Similarly, the intervals between 5-year floods during 1955 to 2007 ranged from 5 months to 16 years, and only half were within 2.5 to 7.5 years.

Regulatory use edit

In the United States, the 100-year flood provides the risk basis for flood insurance rates. Complete information on the National Flood Insurance Program (NFIP) is available here. A regulatory flood or base flood is routinely established for river reaches through a science-based rule-making process targeted to a 100-year flood at the historical average recurrence interval. In addition to historical flood data, the process accounts for previously established regulatory values, the effects of flood-control reservoirs, and changes in land use in the watershed. Coastal flood hazards have been mapped by a similar approach that includes the relevant physical processes. Most areas where serious floods can occur in the United States have been mapped consistently in this manner. On average nationwide, those 100-year flood estimates are well sufficient for the purposes of the NFIP and offer reasonable estimates of future flood risk, if the future is like the past.[6]: 24  Approximately 3% of the U.S. population lives in areas subject to the 1% annual chance coastal flood hazard.[15]

In theory, removing homes and businesses from areas that flood repeatedly can protect people and reduce insurance losses, but in practice it is difficult for people to retreat from established neighborhoods.[16]

See also edit

References edit

  1. ^ Viessman, Warren (1977). Introduction to Hydrology. Harper & Row, Publishers, Inc. p. 160. ISBN 0-7002-2497-1.
  2. ^ a b Holmes, R.R., Jr., and Dinicola, K. (2010) 100-Year flood–it's all about chance U.S. Geological Survey General Information Product 106
  3. ^ Ries, K.G., and others (2008) StreamStats: A water resources web application U.S. Geological Survey, Fact Sheet 2008-3067 Application home page URL accessed 2015-07-12.
  4. ^ . Environment Agency. 2016. Archived from the original on 2016-09-16. Retrieved 25 August 2016.
  5. ^ . FloodSmart. National Flood Insurance Program. Archived from the original on 2016-03-08. Retrieved 7 March 2016.
  6. ^ a b c d e f g h Eychaner, J.H. (2015) Lessons from a 500-year record of flood elevations Association of State Floodplain Managers, Technical Report 7 URL accessed 2021-11-20.
  7. ^ Mays, L.W (2005) Water Resources Engineering, chapter 10, Probability, risk, and uncertainty analysis for hydrologic and hydraulic design Hoboken: J. Wiley & Sons
  8. ^ a b Maidment, D.R. ed.(1993) Handbook of Hydrology, chapter 18, Frequency analysis of extreme events New York: McGraw-Hill
  9. ^ a b England, John; and seven others (29 March 2018). "Guidelines for determining flood flow frequency — Bulletin 17C". Guidelines for determining flood flow frequency—Bulletin 17C. Techniques and Methods. U.S. Geological Survey. doi:10.3133/tm4B5. S2CID 134656108. Retrieved 2 October 2018.
  10. ^ Milly, P. C. D.; Betancourt, J.; Falkenmark, M.; Hirsch, R. M.; Kundzewicz, Z. W.; Lettenmaier, D. P.; Stouffer, R. J. (2008-02-01). "Stationarity is Dead". Science Magazine. 319 (5863). Sciencemag.org: 573–574. doi:10.1126/science.1151915. PMID 18239110. S2CID 206509974.
  11. ^ Intergovernmental Panel on Climate Change (2012) Managing the risks of extreme events and disasters to advance climate change adaptation, Summary for policymakers 2015-07-19 at the Wayback Machine Cambridge and New York: Cambridge University Press, 19 p.
  12. ^ "Bulletin 17C". Advisory Committee on Water Information. Retrieved 2 October 2018.
  13. ^ National Water Information System database U.S. Geological Survey. URL accessed 2014-01-30.
  14. ^ "Obtaining Tide Gauge Data". Permanent Service for Mean Sea Level. PSMSL. Retrieved 7 March 2016.
  15. ^ Crowell, Mark; others (2010). (PDF). Journal of Coastal Research. 26 (2): 201–211. doi:10.2112/JCOASTRES-D-09-00076.1. S2CID 9381124. Archived from the original (PDF) on 17 October 2016. Retrieved 6 March 2016.
  16. ^ Schwartz, Jen (1 August 2018). "Surrendering to rising seas". Scientific American. 319 (2): 44–55. doi:10.1038/scientificamerican0818-44. PMID 30020899. S2CID 240396828. Retrieved 2 October 2018.

External links edit

  • "What is a 100 year flood?". Boulder Area Sustainability Information Network (BASIN). URL accessed 2006-06-16.
  • "Flood Extreme Anaysis". GeoTide Extreme Analysis Software. URL accessed 2023-11-28.

January 01, 1970
year, flood, other, uses, disambiguation, flood, event, that, average, chance, probability, being, equaled, exceeded, given, year, mississippi, river, kaskaskia, illinois, during, great, flood, 1993, also, referred, flood, coastal, lake, flooding, generally, e. For other uses see 100 year flood disambiguation A 100 year flood is a flood event that has on average a 1 in 100 chance 1 probability of being equaled or exceeded in any given year 1 Mississippi River at Kaskaskia Illinois during the Great Flood of 1993 The 100 year flood is also referred to as the 1 flood 2 For coastal or lake flooding the 100 year flood is generally expressed as a flood elevation or depth and may include wave effects For river systems the 100 year flood is generally expressed as a flowrate Based on the expected 100 year flood flow rate the flood water level can be mapped as an area of inundation The resulting floodplain map is referred to as the 100 year floodplain Estimates of the 100 year flood flowrate and other streamflow statistics for any stream in the United States are available 3 In the UK the Environment Agency publishes a comprehensive map of all areas at risk of a 1 in 100 year flood 4 Areas near the coast of an ocean or large lake also can be flooded by combinations of tide storm surge and waves 5 Maps of the riverine or coastal 100 year floodplain may figure importantly in building permits environmental regulations and flood insurance These analyses generally represent 20th century climate Contents 1 Probability 2 Statistical assumptions 3 Probability uncertainty 4 Observed intervals between floods 5 Regulatory use 6 See also 7 References 8 External linksProbability editA common misunderstanding is that a 100 year flood is likely to occur only once in a 100 year period In fact there is approximately a 63 4 chance of one or more 100 year floods occurring in any 100 year period On the Danube River at Passau Germany the actual intervals between 100 year floods during 1501 to 2013 ranged from 37 to 192 years 6 The probability Pe that one or more floods occurring during any period will exceed a given flood threshold can be expressed using the binomial distribution asP e 1 1 1 T n displaystyle P e 1 left 1 left frac 1 T right right n nbsp where T is the threshold return period e g 100 yr 50 yr 25 yr and so forth and n is the number of years in the period The probability of exceedance Pe is also described as the natural inherent or hydrologic risk of failure 7 8 However the expected value of the number of 100 year floods occurring in any 100 year period is 1 Ten year floods have a 10 chance of occurring in any given year Pe 0 10 500 year have a 0 2 chance of occurring in any given year Pe 0 002 etc The percent chance of an X year flood occurring in a single year is 100 X A similar analysis is commonly applied to coastal flooding or rainfall data The recurrence interval of a storm is rarely identical to that of an associated riverine flood because of rainfall timing and location variations among different drainage basins The field of extreme value theory was created to model rare events such as 100 year floods for the purposes of civil engineering This theory is most commonly applied to the maximum or minimum observed stream flows of a given river In desert areas where there are only ephemeral washes this method is applied to the maximum observed rainfall over a given period of time 24 hours 6 hours or 3 hours The extreme value analysis only considers the most extreme event observed in a given year So between the large spring runoff and a heavy summer rain storm whichever resulted in more runoff would be considered the extreme event while the smaller event would be ignored in the analysis even though both may have been capable of causing terrible flooding in their own right Statistical assumptions editThere are a number of assumptions that are made to complete the analysis that determines the 100 year flood First the extreme events observed in each year must be independent from year to year In other words the maximum river flow rate from 1984 cannot be found to be significantly correlated with the observed flow rate in 1985 which cannot be correlated with 1986 and so forth The second assumption is that the observed extreme events must come from the same probability density function The third assumption is that the probability distribution relates to the largest storm rainfall or river flow rate measurement that occurs in any one year The fourth assumption is that the probability distribution function is stationary meaning that the mean average standard deviation and maximum and minimum values are not increasing or decreasing over time This concept is referred to as stationarity 8 9 The first assumption is often but not always valid and should be tested on a case by case basis The second assumption is often valid if the extreme events are observed under similar climate conditions For example if the extreme events on record all come from late summer thunderstorms as is the case in the southwest U S or from snow pack melting as is the case in north central U S then this assumption should be valid If however there are some extreme events taken from thunder storms others from snow pack melting and others from hurricanes then this assumption is most likely not valid The third assumption is only a problem when trying to forecast a low but maximum flow event for example an event smaller than a 2 year flood Since this is not typically a goal in extreme analysis or in civil engineering design then the situation rarely presents itself The final assumption about stationarity is difficult to test from data for a single site because of the large uncertainties in even the longest flood records 6 see next section More broadly substantial evidence of climate change strongly suggests that the probability distribution is also changing 10 and that managing flood risks in the future will become even more difficult 11 The simplest implication of this is that most of the historical data represent 20th century climate and might not be valid for extreme event analysis in the 21st century Probability uncertainty editWhen these assumptions are violated there is an unknown amount of uncertainty introduced into the reported value of what the 100 year flood means in terms of rainfall intensity or flood depth When all of the inputs are known the uncertainty can be measured in the form of a confidence interval For example one might say there is a 95 chance that the 100 year flood is greater than X but less than Y 2 Direct statistical analysis 9 12 to estimate the 100 year riverine flood is possible only at the relatively few locations where an annual series of maximum instantaneous flood discharges has been recorded In the United States as of 2014 taxpayers have supported such records for at least 60 years at fewer than 2 600 locations for at least 90 years at fewer than 500 and for at least 120 years at only 11 13 For comparison the total area of the nation is about 3 800 000 square miles 9 800 000 km2 so there are perhaps 3 000 stream reaches that drain watersheds of 1 000 square miles 2 600 km2 and 300 000 reaches that drain 10 square miles 26 km2 In urban areas 100 year flood estimates are needed for watersheds as small as 1 square mile 2 6 km2 For reaches without sufficient data for direct analysis 100 year flood estimates are derived from indirect statistical analysis of flood records at other locations in a hydrologically similar region or from other hydrologic models Similarly for coastal floods tide gauge data exist for only about 1 450 sites worldwide of which only about 950 added information to the global data center between January 2010 and March 2016 14 nbsp High water scale 1501 2002 at Passau Germany as of September 2012 Much longer records of flood elevations exist at a few locations around the world such as the Danube River at Passau Germany but they must be evaluated carefully for accuracy and completeness before any statistical interpretation For an individual stream reach the uncertainties in any analysis can be large so 100 year flood estimates have large individual uncertainties for most stream reaches 6 24 For the largest recorded flood at any specific location or any potentially larger event the recurrence interval always is poorly known 6 20 24 Spatial variability adds more uncertainty because a flood peak observed at different locations on the same stream during the same event commonly represents a different recurrence interval at each location 6 20 If an extreme storm drops enough rain on one branch of a river to cause a 100 year flood but no rain falls over another branch the flood wave downstream from their junction might have a recurrence interval of only 10 years Conversely a storm that produces a 25 year flood simultaneously in each branch might form a 100 year flood downstream During a time of flooding news accounts necessarily simplify the story by reporting the greatest damage and largest recurrence interval estimated at any location The public can easily and incorrectly conclude that the recurrence interval applies to all stream reaches in the flood area 6 7 24 Observed intervals between floods edit nbsp Observed intervals between floods at Passau 1501 2013Peak elevations of 14 floods as early as 1501 on the Danube River at Passau Germany reveal great variability in the actual intervals between floods 6 16 19 Flood events greater than the 50 year flood occurred at intervals of 4 to 192 years since 1501 and the 50 year flood of 2002 was followed only 11 years later by a 500 year flood Only half of the intervals between 50 and 100 year floods were within 50 percent of the nominal average interval Similarly the intervals between 5 year floods during 1955 to 2007 ranged from 5 months to 16 years and only half were within 2 5 to 7 5 years Regulatory use editIn the United States the 100 year flood provides the risk basis for flood insurance rates Complete information on the National Flood Insurance Program NFIP is available here A regulatory flood or base flood is routinely established for river reaches through a science based rule making process targeted to a 100 year flood at the historical average recurrence interval In addition to historical flood data the process accounts for previously established regulatory values the effects of flood control reservoirs and changes in land use in the watershed Coastal flood hazards have been mapped by a similar approach that includes the relevant physical processes Most areas where serious floods can occur in the United States have been mapped consistently in this manner On average nationwide those 100 year flood estimates are well sufficient for the purposes of the NFIP and offer reasonable estimates of future flood risk if the future is like the past 6 24 Approximately 3 of the U S population lives in areas subject to the 1 annual chance coastal flood hazard 15 In theory removing homes and businesses from areas that flood repeatedly can protect people and reduce insurance losses but in practice it is difficult for people to retreat from established neighborhoods 16 See also editExtreme value theory Extreme weather Flood forecasting Frequency of exceedance List of floods Lists of floods in the United StatesReferences edit Viessman Warren 1977 Introduction to Hydrology Harper amp Row Publishers Inc p 160 ISBN 0 7002 2497 1 a b Holmes R R Jr and Dinicola K 2010 100 Year flood it s all about chance U S Geological Survey General Information Product 106 Ries K G and others 2008 StreamStats A water resources web application U S Geological Survey Fact Sheet 2008 3067 Application home page URL accessed 2015 07 12 Flood Map for Planning Rivers and Sea Environment Agency 2016 Archived from the original on 2016 09 16 Retrieved 25 August 2016 Coastal Flooding FloodSmart National Flood Insurance Program Archived from the original on 2016 03 08 Retrieved 7 March 2016 a b c d e f g h Eychaner J H 2015 Lessons from a 500 year record of flood elevations Association of State Floodplain Managers Technical Report 7 URL accessed 2021 11 20 Mays L W 2005 Water Resources Engineering chapter 10 Probability risk and uncertainty analysis for hydrologic and hydraulic design Hoboken J Wiley amp Sons a b Maidment D R ed 1993 Handbook of Hydrology chapter 18 Frequency analysis of extreme events New York McGraw Hill a b England John and seven others 29 March 2018 Guidelines for determining flood flow frequency Bulletin 17C Guidelines for determining flood flow frequency Bulletin 17C Techniques and Methods U S Geological Survey doi 10 3133 tm4B5 S2CID 134656108 Retrieved 2 October 2018 Milly P C D Betancourt J Falkenmark M Hirsch R M Kundzewicz Z W Lettenmaier D P Stouffer R J 2008 02 01 Stationarity is Dead Science Magazine 319 5863 Sciencemag org 573 574 doi 10 1126 science 1151915 PMID 18239110 S2CID 206509974 Intergovernmental Panel on Climate Change 2012 Managing the risks of extreme events and disasters to advance climate change adaptation Summary for policymakers Archived 2015 07 19 at the Wayback Machine Cambridge and New York Cambridge University Press 19 p Bulletin 17C Advisory Committee on Water Information Retrieved 2 October 2018 National Water Information System database U S Geological Survey URL accessed 2014 01 30 Obtaining Tide Gauge Data Permanent Service for Mean Sea Level PSMSL Retrieved 7 March 2016 Crowell Mark others 2010 An estimate of the U S population living in 100 year coastal flood hazard areas PDF Journal of Coastal Research 26 2 201 211 doi 10 2112 JCOASTRES D 09 00076 1 S2CID 9381124 Archived from the original PDF on 17 October 2016 Retrieved 6 March 2016 Schwartz Jen 1 August 2018 Surrendering to rising seas Scientific American 319 2 44 55 doi 10 1038 scientificamerican0818 44 PMID 30020899 S2CID 240396828 Retrieved 2 October 2018 External links edit What is a 100 year flood Boulder Area Sustainability Information Network BASIN URL accessed 2006 06 16 Flood Extreme Anaysis GeoTide Extreme Analysis Software URL accessed 2023 11 28 Retrieved from https en wikipedia org w index php title 100 year flood amp oldid 1189858652, wikipedia, wiki, book, books, library,

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