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{{Tropicalcyclone}}
{{Tropicalcyclone}}
A '''tropical cyclone rainfall climatology''' is developed to fukn ass determine rainfall characteristics of past tropical cyclones. A tropical cyclone rainfall climatology can be used to help forecast current or upcoming tropical cyclone impacts. The degree of a tropical cyclone rainfall impact depends upon speed of movement, storm size, and degree of vertical wind shear. One of the most significant threats from [[tropical cyclone]]s is heavy rainfall. Large, slow moving, and non-sheared tropical cyclones produce the heaviest rains. The intensity of a tropical cyclone appears to have little bearing on its potential for rainfall over land, but satellite measurements over the last several years show that more intense tropical cyclones produce noticeably more rainfall over water. Flooding from tropical cyclones remains a significant cause of fatalities, particularly in low-lying areas.
A '''tropical cyclone rainfall climatology''' is developed to determine rainfall characteristics of past tropical cyclones. A tropical cyclone rainfall climatology can be used to help forecast current or upcoming tropical cyclone impacts. The degree of a tropical cyclone rainfall impact depends upon speed of movement, storm size, and degree of vertical wind shear. One of the most significant threats from [[tropical cyclone]]s is heavy rainfall. Large, slow moving, and non-sheared tropical cyclones produce the heaviest rains. The intensity of a tropical cyclone appears to have little bearing on its potential for rainfall over land, but satellite measurements over the last several years show that more intense tropical cyclones produce noticeably more rainfall over water. Flooding from tropical cyclones remains a significant cause of fatalities, particularly in low-lying areas.


==Anticipating a flood event==
==Anticipating a flood event==
{{See also|Tropical cyclone rainfall forecasting}}
{{See also|Tropical cyclone rainfall forecasting}}


While inland [[flood]]ing is common to tropical cyclones, there are factors which lead to excessive rainfall from tropical cyclones. Slow motion, as was seen during [[Hurricane Danny (1997)]] and [[Hurricane Wilma]], can lead to high amounts of rainfall. The presence of mountains/hills near the coast, like across much of [[Mexico]], [[Haiti]], the [[Dominican Republic]], [[Central America]], [[Madagascar]], [[Réunion]], [[China]], and [[Japan]] acts to magnify rainfall potential due to forced upslope flow into the mountains. Strong upper level forcing from a trough moving through the Westerlies and its associated [[cold front]], as was the case during [[Hurricane Floyd]], can lead to high amounts even from systems moving at an average forward motion. Larger tropical cyclones drop more rainfall as they precipitate upon one spot for a longer time frame than average or small tropical cyclones. A combination of two of these factors could be especially crippling, as was seen during [[Hurricane Mitch]] in [[Central America]].<ref name="Are You Ready?">{{cite web|url=http://www.fema.gov/areyouready/hurricanes.shtm |title= Are You Ready?|accessdate=2006-06-24 |date=2006-04-05 |publisher=[[Federal Emergency Management Agency]]}}</ref> During the 2005 season, flooding related to slow-moving [[Hurricane Stan]]'s broad circulation led to 1,662–2,000 deaths.<ref name="Standeaths">"[http://www.noaanews.noaa.gov/stories2006/s2607.htm Dennis, Katrina, Rita, Stan, and Wilma "Retired" from List of Storm Names]." ''[[NOAA]].'' Retrieved on June 14, 2008.</ref>
While inland [[flood]]ing is common to tropical cyclones, there are factors which lead to excessive rainfall from tropical cyclones. Slow motion, as was seen during [[Hurricane Danny (1997)]] and [[Hurricane Wilma]], can lead to high amounts of rainfall. The presence of mountains/hills near the coast, like across much of [[Mexico]], [[Haiti]], the [[Dominican Republic]], [[Central America]], [[Madagascar]], [[Réunion]], [[China]], and [[Japan]] acts to magnify rainfall potential due to forced upslope flow into the mountains. Strong upper level forcing from a trough moving through the Westerlies and its associated [[cold front]], as was the case during [[Hurricane Floyd]], can lead to high amounts even from systems moving at an average forward motion. Larger tropical cyclones drop more rainfall as they precipitate upon one spot for a longer time frame than average or small tropical cyclones. A combination of two of these factors could be especially crippling, as was seen during [[Hurricane Mitch]] in [[Central America]].<ref name="Are You Ready?">{{cite web |url=http://www.fema.gov/areyouready/hurricanes.shtm |title=Are You Ready? |access-date=2006-06-24 |date=2006-04-05 |publisher=[[Federal Emergency Management Agency]] |url-status=dead |archive-url=https://web.archive.org/web/20060629081031/http://www.fema.gov/areyouready/hurricanes.shtm |archive-date=2006-06-29 }}</ref> During the 2005 season, flooding related to slow-moving [[Hurricane Stan]]'s broad circulation led to 1,662–2,000 deaths.<ref name="Standeaths">"[http://www.noaanews.noaa.gov/stories2006/s2607.htm Dennis, Katrina, Rita, Stan, and Wilma "Retired" from List of Storm Names] {{Webarchive|url=https://web.archive.org/web/20171224105328/http://www.noaanews.noaa.gov/stories2006/s2607.htm |date=2017-12-24 }}." ''[[NOAA]].'' Retrieved on June 14, 2008.</ref>


==General distribution within a tropical cyclone==
==General distribution within a tropical cyclone==
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[[Isaac Cline]] was the first to investigate [[rain]]fall distribution around tropical cyclones in the early 1900s. He found that a larger proportion of rainfall falls in advance of the center (or eye) than after the center's passage, with the highest percentage falling in the right front quadrant. Father Viñes of [[Cuba]] found that some tropical cyclones have their highest rainfall rates in the rear quadrant within a training (non-moving) inflow band.<ref>[[Ivan Ray Tannehill|Tannehill]] 1942</ref> Normally, as a tropical cyclone intensifies, its heavier rainfall rates become more concentrated around its center.<ref>E.B. Rodgers and R.F. Adler. [http://ams.allenpress.com/perlserv/?request=get-abstract&doi=10.1175%2F1520-0493(1981)109%3C0506%3ATCRCAD%3E2.0.CO%3B2 Tropical Cyclone Rainfall Characteristics as Determined from a Satellite Passive Microwave Radiometer.] Retrieved on 2008-04-16.</ref> Rainfall is found to be heaviest in tropical cyclone's inner core, whether it be the [[eyewall]] or [[central dense overcast]], within a degree latitude of the center, with lesser amounts farther away from the center.<ref>[[Herbert Riehl|Riehl]] 1954</ref> Most of the rainfall in tropical cyclones is concentrated within its radius of gale-force (34&nbsp;knots/39&nbsp;mph/63&nbsp;km/h) winds.<ref name="CORENE">Corene J. Matyas. [http://ams.confex.com/ams/pdfpapers/108831.pdf Relating Tropical Cyclone Rainfall Patterns to Storm Size.] Retrieved on 2007-02-14.</ref> Rainfall is more common near the center of tropical cyclones overnight. Over land, outer bands are more active during the heating of the day, which can act to restrict inflow into the center of the cyclone. Recent studies have shown that half of the rainfall within a tropical cyclone is stratiform in nature.<ref name="DR072007">David M. Roth. [http://www.hpc.ncep.noaa.gov/research/roth/TC_QPF_talk072007.ppt Tropical Cyclone Rainfall Presentation (July 2007).] Retrieved on 2007-07-19.</ref> The chart to the right was developed by Riehl in 1954 using meteorological equations that assume a gale radius of about {{convert|140|mi|km}}, a fairly symmetric cyclone, and does not consider topographic effects or vertical wind shear. Local amounts can exceed this chart by a factor of two due to topography. Wind shear tends to lessen the amounts below what is shown on the table.
[[Isaac Cline]] was the first to investigate [[rain]]fall distribution around tropical cyclones in the early 1900s. He found that a larger proportion of rainfall falls in advance of the center (or eye) than after the center's passage, with the highest percentage falling in the right front quadrant. Father Viñes of [[Cuba]] found that some tropical cyclones have their highest rainfall rates in the rear quadrant within a training (non-moving) inflow band.<ref>[[Ivan Ray Tannehill|Tannehill]] 1942</ref> Normally, as a tropical cyclone intensifies, its heavier rainfall rates become more concentrated around its center.<ref>E.B. Rodgers and R.F. Adler. [http://ams.allenpress.com/perlserv/?request=get-abstract&doi=10.1175%2F1520-0493(1981)109%3C0506%3ATCRCAD%3E2.0.CO%3B2 Tropical Cyclone Rainfall Characteristics as Determined from a Satellite Passive Microwave Radiometer.]{{Dead link|date=August 2024 |bot=InternetArchiveBot |fix-attempted=yes }} Retrieved on 2008-04-16.</ref> Rainfall is found to be heaviest in tropical cyclone's inner core, whether it be the [[eyewall]] or [[central dense overcast]], within a degree latitude of the center, with lesser amounts farther away from the center.<ref>[[Herbert Riehl|Riehl]] 1954</ref> Most of the rainfall in tropical cyclones is concentrated within its radius of gale-force ({{convert|34|kn|mph km/h|disp=x|/|}}) winds.<ref name="CORENE">Corene J. Matyas. [http://ams.confex.com/ams/pdfpapers/108831.pdf Relating Tropical Cyclone Rainfall Patterns to Storm Size.] {{Webarchive|url=https://web.archive.org/web/20061025121109/http://ams.confex.com/ams/pdfpapers/108831.pdf |date=2006-10-25 }} Retrieved on 2007-02-14.</ref> Rainfall is more common near the center of tropical cyclones overnight. Over land, outer bands are more active during the heating of the day, which can act to restrict inflow into the center of the cyclone. Recent studies have shown that half of the rainfall within a tropical cyclone is stratiform in nature.<ref name="DR072007">David M. Roth. [http://www.wpc.ncep.noaa.gov/research/roth/TC_QPF_talk072007.ppt Tropical Cyclone Rainfall Presentation (July 2007).] {{Webarchive|url=https://web.archive.org/web/20160304074131/http://www.wpc.ncep.noaa.gov/research/roth/TC_QPF_talk072007.ppt |date=2016-03-04 }} Retrieved on 2007-07-19.</ref> The chart to the right was developed by Riehl in 1954 using meteorological equations that assume a gale radius of about {{convert|140|mi|km}}, a fairly symmetric cyclone, and does not consider topographic effects or vertical wind shear. Local amounts can exceed this chart by a factor of two due to topography. Wind shear tends to lessen the amounts below what is shown on the table.


==Relation to storm size==
==Relation to storm size==
[[Image:Typhoonsizes.jpg|right|frame|The relative sizes of [[Typhoon Tip]], [[Cyclone Tracy]], and the United States.]]
[[File:Typhoonsizes.svg|right|thumb|The relative sizes of [[Typhoon Tip]], [[Cyclone Tracy]], and the United States.]]
Larger tropical cyclones have larger rain shields, which can lead to higher rainfall amounts farther from the cyclone's center.<ref name="CORENE"/> This is generally due to the longer time frame rainfall falls at any one spot in a larger system, when compared to a smaller system. Some of the difference seen concerning rainfall between larger and small storms could be the increased sampling of rainfall within a larger tropical cyclone when compared to that of a compact cyclone; in other words, the difference could be the result of a statistical problem.
Larger tropical cyclones have larger rain shields, which can lead to higher rainfall amounts farther from the cyclone's center.<ref name="CORENE"/> This is generally due to the longer time frame rainfall falls at any one spot in a larger system, when compared to a smaller system. Some of the difference seen concerning rainfall between larger and small storms could be the increased sampling of rainfall within a larger tropical cyclone when compared to that of a compact cyclone; in other words, the difference could be the result of a statistical problem.


==Slow/looping motion on rainfall magnitude==
==Slow/looping motion on rainfall magnitude==
Storms which have moved slowly, or loop, over a succession of days lead to the highest rainfall amounts for several countries. Riehl calculated that 33.97&nbsp;inches (863&nbsp;mm) of rainfall per day can be expected within one-half degree, or 35&nbsp;miles (56&nbsp;km), of the center of a mature tropical cyclone. Many tropical cyclones progress at a forward motion of 10&nbsp;knots, which would limit the duration of this excessive rainfall to around one-quarter of a day, which would yield about 8.50&nbsp;inches (216&nbsp;mm) of rainfall. This would be true over water, within 100&nbsp;miles (160&nbsp;km) of the coastline,<ref>Russell Pfost. [http://www.srh.noaa.gov/mfl/newpage/tampa/index.htm Tropical Cyclone Quantitative Precipitation Forecasting.] Retrieved on 2007-02-25.</ref> and outside topographic features. As a cyclone moves farther inland and is cut off from its supply of warmth and moisture (the ocean), rainfall amounts from tropical cyclones and their remains decrease quickly.{{US States Tropical Cyclone Point Maxima}}
Storms which have moved slowly, or loop, over a succession of days lead to the highest rainfall amounts for several countries. Riehl calculated that {{convert|33.97|in|mm}} of rainfall per day can be expected within one-half degree, or {{convert|35|mi|km}}, of the center of a mature tropical cyclone. Many tropical cyclones progress at a forward motion of 10&nbsp;knots, which would limit the duration of this excessive rainfall to around one-quarter of a day, which would yield about {{convert|8.50|in|mm}} of rainfall. This would be true over water, within {{convert|100|mi|km}} of the coastline,<ref>Russell Pfost. [http://www.srh.noaa.gov/mfl/newpage/tampa/index.htm Tropical Cyclone Quantitative Precipitation Forecasting.] {{Webarchive|url=https://web.archive.org/web/20061231124107/http://www.srh.noaa.gov/mfl/newpage/tampa/index.htm |date=2006-12-31 }} Retrieved on 2007-02-25.</ref> and outside topographic features. As a cyclone moves farther inland and is cut off from its supply of warmth and moisture (the ocean), rainfall amounts from tropical cyclones and their remains decrease quickly.{{US States Tropical Cyclone Point Maxima}}


==Vertical wind shear impact on rainfall shield==
==Vertical wind shear impact on rainfall shield==
Vertical [[wind shear]] forces the rainfall pattern around a tropical cyclone to become highly asymmetric, with most of the precipitation falling to the left and downwind of the shear vector, or downshear left. In other words, southwesterly shear forces the bulk of the rainfall north-northeast of the center.<ref>Shuyi S. Chen, John A. Knaff, and Frank D. Marks, Jr. [http://rammb.cira.colostate.edu/resources/docs/chen_etal_2006.pdf Effects of Vertical Wind Shear and Storm Motion on Tropical Cyclone Rainfall Asymmetries Deduced from TRMM.] Retrieved on 2007-03-28.</ref> If the wind shear is strong enough, the bulk of the rainfall will move away from the center leading to what is known as an exposed circulation center. When this occurs, the potential magnitude of rainfall with the tropical cyclone will be significantly reduced.
Vertical [[wind shear]] forces the rainfall pattern around a tropical cyclone to become highly asymmetric, with most of the precipitation falling to the left and downwind of the shear vector, or downshear left. In other words, southwesterly shear forces the bulk of the rainfall north-northeast of the center.<ref>Shuyi S. Chen, John A. Knaff, and Frank D. Marks, Jr. [http://rammb.cira.colostate.edu/resources/docs/chen_etal_2006.pdf Effects of Vertical Wind Shear and Storm Motion on Tropical Cyclone Rainfall Asymmetries Deduced from TRMM.] {{Webarchive|url=https://web.archive.org/web/20071129132638/http://rammb.cira.colostate.edu/resources/docs/chen_etal_2006.pdf |date=2007-11-29 }} Retrieved on 2007-03-28.</ref> If the wind shear is strong enough, the bulk of the rainfall will move away from the center leading to what is known as an exposed circulation center. When this occurs, the potential magnitude of rainfall with the tropical cyclone will be significantly reduced.


===Effect of interaction with frontal boundaries/upper level troughs===
===Effect of interaction with frontal boundaries/upper level troughs===
As a [[tropical cyclone]] interacts with an upper-level [[trough (meteorology)|trough]] and the related [[Surface weather analysis|surface front]], a distinct northern area of precipitation is seen along the front ahead of the axis of the upper level trough. This type of interaction can lead to the appearance of the heaviest rainfall falling along and to the left of the tropical cyclone track, with the precipitation streaking hundreds of miles or kilometers downwind from the tropical cyclone.<ref name="WES">Norman. W. Junker. [http://www.hpc.ncep.noaa.gov/research/mcs_web_test_test_files/page0024.htm Hurricanes and extreme rainfall.] Retrieved on 2006-02-13.</ref> The stronger the upper trough picking up the tropical cyclone, the more significant the left of track shift in the rainfall distribution tends to be.<ref name="DR072007"/>
As a [[tropical cyclone]] interacts with an upper-level [[trough (meteorology)|trough]] and the related [[Surface weather analysis|surface front]], a distinct northern area of precipitation is seen along the front ahead of the axis of the upper-level trough. This type of interaction can lead to the appearance of the heaviest rainfall falling along and to the left of the tropical cyclone track, with the precipitation streaking hundreds of miles or kilometers downwind from the tropical cyclone.<ref name="WES">Norman. W. Junker. [http://www.wpc.ncep.noaa.gov/research/mcs_web_test_test_files/page0024.htm Hurricanes and extreme rainfall.] Retrieved on 2006-02-13.</ref> The stronger the upper trough picking up the tropical cyclone, the more significant the left of track shift in the rainfall distribution tends to be.<ref name="DR072007"/>


==Mountains==
==Mountains==
Moist air forced up the slopes of coastal hills and mountain chains can lead to much heavier rainfall than in the coastal plain. This heavy rainfall can lead to landslides, which still cause significant loss of life such as seen during [[Hurricane Mitch]] in [[Central America]].
Moist air forced up the slopes of coastal hills and mountain chains can lead to much heavier rainfall than in the coastal plain. This heavy rainfall can lead to landslides, which still cause significant loss of life such as seen during [[Hurricane Mitch]] in [[Central America]].


==Global distribution==
==Global distribution==
[[Image:Globaltcrainfalldistribution2005.jpg|thumb|right|250 px|Global tropical cyclone rainfall in 2005]]
[[Image:Globaltcrainfalldistribution2005.jpg|thumb|right|250 px|Global tropical cyclone rainfall in 2005]]
Globally, tropical cyclone rainfall is more common across the northern hemisphere than across the southern hemisphere. This is mainly due to the normal annual tropical cyclone distribution, as between half and two-thirds of all tropical cyclones form north of the equator. Rainfall is concentrated near the 15th parallel in both hemispheres, with a less steep dropoff seen with latitude across the northern hemisphere, due to the stronger warm water currents seen in that hemisphere which allow tropical cyclones to remain tropical in nature at higher latitudes than south of the equator. In the southern hemisphere, rainfall impacts will be most common between January and March, while north of the equator, tropical cyclone rainfall impacts are more common between June and November.<ref name="DR072007"/> [[Japan]] receives over half of its rainfall from typhoons.<ref name="Whipple 54">{{cite book | author = Whipple, Addison | year = 1982 | title = Storm | location = [[Alexandria, Virginia|Alexandria, VA]] | publisher = [[Time Life|Time Life Books]] | isbn = 0-8094-4312-0 | page = 54}}</ref>
Globally, tropical cyclone rainfall is more common across the northern hemisphere than across the southern hemisphere. This is mainly due to the normal annual tropical cyclone distribution, as between half and two-thirds of all tropical cyclones form north of the equator. Rainfall is concentrated near the 15th parallel in both hemispheres, with a less steep dropoff seen with latitude across the northern hemisphere, due to the stronger warm water currents seen in that hemisphere which allow tropical cyclones to remain tropical in nature at higher latitudes than south of the equator.<ref>{{cite journal |last1=Dominguez |first1=Christian |last2=Magaña |first2=Victor |title=The Role of Tropical Cyclones in Precipitation Over the Tropical and Subtropical North America |journal=Frontiers in Earth Science |date=6 March 2018 |volume=6 |pages=19 |doi=10.3389/feart.2018.00019|bibcode=2018FrEaS...6...19D |doi-access=free }}</ref> In the southern hemisphere, rainfall impacts will be most common between January and March, while north of the equator, tropical cyclone rainfall impacts are more common between June and November.<ref name="DR072007"/> [[Japan]] receives over half of its rainfall from typhoons.<ref name="Whipple 54">{{cite book | author = Whipple, Addison | year = 1982 | title = Storm | url = https://archive.org/details/storm00whip | url-access = registration | location = [[Alexandria, Virginia|Alexandria, VA]] | publisher = [[Time Life|Time Life Books]] | isbn = 0-8094-4312-0 | page = [https://archive.org/details/storm00whip/page/54 54]}}</ref>


==United States tropical cyclone rainfall statistics==
==United States tropical cyclone rainfall statistics==
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{{See also|United States tropical cyclone rainfall climatology}}
{{See also|United States tropical cyclone rainfall climatology}}
Between 1970-2004, inland flooding from tropical cyclones caused a majority of the fatalities in the [[United States]].<ref name="Inland Flooding">{{cite web|url=http://www.nhc.noaa.gov/HAW2/english/inland_flood.shtml |title=Inland Flooding |accessdate=2006-06-24 |date= |author=Ed Rappaport |publisher=[[National Oceanic & Atmospheric Administration]]}}</ref> This statistic changed in 2005, when [[Hurricane Katrina]]'s impact alone shifted the most deadly aspect of tropical cyclones back to [[storm surge]], which has historically been the most deadly aspect of strong tropical cyclones.<ref name="The Deadliest, Costliest, and Most Intense United States Tropical Cyclones From 1851 to 2004">{{cite web|url=http://www.nhc.noaa.gov/Deadliest_Costliest.shtml |title=The Deadliest, Costliest, and Most Intense United States Tropical Cyclones From 1851 to 2004 |accessdate=2006-06-24 |date= |author=Eric S. Blake |coauthors=Jerry D. Jarrell, Edward N. Rappaport, Christopher W. Landsea |publisher=[[National Oceanic & Atmospheric Administration]]}}</ref>
Between 1970 and 2004, inland flooding caused a majority of the tropical cyclone-related fatalities in the [[United States]].<ref name="Inland Flooding">{{cite web |url=http://www.nhc.noaa.gov/HAW2/english/inland_flood.shtml |title=Inland Flooding |access-date=2006-06-24 |author=Ed Rappaport |publisher=[[National Oceanic & Atmospheric Administration]] |archive-date=2012-01-11 |archive-url=https://web.archive.org/web/20120111073439/http://www.nhc.noaa.gov/HAW2/english/inland_flood.shtml |url-status=live }}</ref> This statistic changed in 2005, when [[Hurricane Katrina]]'s impact alone shifted the most deadly aspect of tropical cyclones back to [[storm surge]], which has historically been the most deadly aspect of strong tropical cyclones.<ref name="The Deadliest, Costliest, and Most Intense United States Tropical Cyclones From 1851 to 2004">{{cite web |url=http://www.nhc.noaa.gov/Deadliest_Costliest.shtml |title=The Deadliest, Costliest, and Most Intense United States Tropical Cyclones From 1851 to 2004 |access-date=2006-06-24 |author=Eric S. Blake |author2=Jerry D. Jarrell |author3=Edward N. Rappaport |author4=Christopher W. Landsea |publisher=[[National Oceanic & Atmospheric Administration]] |archive-date=2009-05-06 |archive-url=https://web.archive.org/web/20090506025453/http://www.nhc.noaa.gov/Deadliest_Costliest.shtml |url-status=live }}</ref>
On average, five tropical cyclones of at least tropical depression strength lead to rainfall across the contiguous United States annually, contributing around a quarter of the annual rainfall to the southeast United States. While many of these storms form in the Atlantic Basin, some systems or their remnants move through Mexico from the Eastern Pacific Basin. The average storm total rainfall for a tropical cyclone impacting the lower 48 from the Atlantic Basin is about 16&nbsp;inches (406&nbsp;mm), with 70–75 percent of the storm total falling within a 24-hour period. The highest point total was seen during [[Tropical Storm Amelia (1978)|Amelia 1978]], when 48&nbsp;inches (1,218&nbsp;mm) fell upon central [[Texas]].{{Tropical Cyclone Point Maxima}}
On average, five tropical cyclones of at least tropical depression strength lead to rainfall across the contiguous United States annually, contributing around a quarter of the annual rainfall to the southeast United States. While many of these storms form in the Atlantic basin, some systems or their remnants move through Mexico from the Eastern Pacific basin. The average storm total rainfall for a tropical cyclone impacting the lower 48 from the Atlantic basin is about {{convert|16|in|mm}}, with 70–75 percent of the storm total falling within a 24-hour period. The highest point total was seen during [[Hurricane Harvey]] in [[2017 Atlantic hurricane season|2017]], when {{convert|60.58|in|mm}} fell in southeast [[Texas]].{{Tropical Cyclone Point Maxima}}


==See also==
==See also==
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*[[China tropical cyclone rainfall climatology]]
*[[China tropical cyclone rainfall climatology]]
*[[Extratropical cyclone]]
*[[Extratropical cyclone]]
*[[List of wettest tropical cyclones]]
*[[List of wettest tropical cyclones by country]]
*[[List of wettest tropical cyclones by country]]
*[[Tropical cyclone]]
*[[Tropical cyclone]]
*[[Tropical cyclone rainfall forecasting]]
*[[Tropical cyclone rainfall forecasting]]
*[[Tropical cyclogenesis]]
*[[Tropical cyclogenesis]]
*[[United States tropical cyclone rainfall climatology]]


==References==
==Printed media==
#Ivan Ray Tannehill. '''Hurricanes.''' Princeton University Press: Princeton, 1942.
===Printed media===
#Herbert Riehl. '''Tropical Meteorology.''' McGraw-Hill Book Company, Inc.: New York, 1954.
#Ivan Ray Tannehill. '''Hurricanes.''' Princeton University Press: Princeton, 1942.
#Terry Tucker. '''Beware the Hurricane!''' Hamilton Press: Bermuda, 1966.
#Herbert Riehl. '''Tropical Meteorology.''' McGraw-Hill Book Company, Inc.: New York, 1954.
#Terry Tucker. '''Beware the Hurricane!''' Hamilton Press: Bermuda, 1966.


===References===
==References==
{{Reflist}}
{{Reflist}}


==Related external links==
==Related external links==
*[http://www.hpc.ncep.noaa.gov/tropical/rain/tcrainfall.html Individual Tropical Cyclone Rainfall Pages for the United States and Mexico]
*[http://www.wpc.ncep.noaa.gov/tropical/rain/tcrainfall.html Individual Tropical Cyclone Rainfall Pages for the United States and Mexico]
*[http://www.hpc.ncep.noaa.gov/tropical/rain/tcpr.html Individual Tropical Cyclone Rainfall Pages for Puerto Rico/U.S. Virgin Islands]
*[http://www.wpc.ncep.noaa.gov/tropical/rain/tcpr.html Individual Tropical Cyclone Rainfall Pages for Puerto Rico/U.S. Virgin Islands]
*[http://www.hpc.ncep.noaa.gov/tropical/rain/tcstatemaxima.gif Maximum amounts in the lower 48 United States by state]
*[http://www.wpc.ncep.noaa.gov/tropical/rain/tcstatemaxima.gif Maximum amounts in the lower 48 United States by state]
*[http://www.aoml.noaa.gov/hrd/iwtc/ChenLianshou2-1.html Typhoon Rainfall Statistics and Forecasting (China)]
*[http://www.aoml.noaa.gov/hrd/iwtc/ChenLianshou2-1.html Typhoon Rainfall Statistics and Forecasting (China)]
*[http://www.nhc.noaa.gov/Deadliest_Costliest.shtml Deadliest, Costliest, and Most Intense United States Tropical Cyclones From 1851 to 2004]
*[http://www.nhc.noaa.gov/Deadliest_Costliest.shtml Deadliest, Costliest, and Most Intense United States Tropical Cyclones From 1851 to 2004]
*[http://www.fema.gov/areyouready/hurricanes.shtm Are You Ready? Hurricanes]
*[https://web.archive.org/web/20060629081031/http://www.fema.gov/areyouready/hurricanes.shtm Are You Ready? Hurricanes]


{{Good article}}
{{Good article}}

Latest revision as of 14:16, 22 August 2024

A tropical cyclone rainfall climatology is developed to determine rainfall characteristics of past tropical cyclones. A tropical cyclone rainfall climatology can be used to help forecast current or upcoming tropical cyclone impacts. The degree of a tropical cyclone rainfall impact depends upon speed of movement, storm size, and degree of vertical wind shear. One of the most significant threats from tropical cyclones is heavy rainfall. Large, slow moving, and non-sheared tropical cyclones produce the heaviest rains. The intensity of a tropical cyclone appears to have little bearing on its potential for rainfall over land, but satellite measurements over the last several years show that more intense tropical cyclones produce noticeably more rainfall over water. Flooding from tropical cyclones remains a significant cause of fatalities, particularly in low-lying areas.

Anticipating a flood event

[edit]

While inland flooding is common to tropical cyclones, there are factors which lead to excessive rainfall from tropical cyclones. Slow motion, as was seen during Hurricane Danny (1997) and Hurricane Wilma, can lead to high amounts of rainfall. The presence of mountains/hills near the coast, like across much of Mexico, Haiti, the Dominican Republic, Central America, Madagascar, Réunion, China, and Japan acts to magnify rainfall potential due to forced upslope flow into the mountains. Strong upper level forcing from a trough moving through the Westerlies and its associated cold front, as was the case during Hurricane Floyd, can lead to high amounts even from systems moving at an average forward motion. Larger tropical cyclones drop more rainfall as they precipitate upon one spot for a longer time frame than average or small tropical cyclones. A combination of two of these factors could be especially crippling, as was seen during Hurricane Mitch in Central America.[1] During the 2005 season, flooding related to slow-moving Hurricane Stan's broad circulation led to 1,662–2,000 deaths.[2]

General distribution within a tropical cyclone

[edit]
Rainfall Rate per day within radius of the center (Riehl)
Radius (mi) Radius (km) Amount (in) Amount (mm)
35 56 33.98 863
70 112 13.27 337
140 224 4.25 108
280 448 1.18 30

Isaac Cline was the first to investigate rainfall distribution around tropical cyclones in the early 1900s. He found that a larger proportion of rainfall falls in advance of the center (or eye) than after the center's passage, with the highest percentage falling in the right front quadrant. Father Viñes of Cuba found that some tropical cyclones have their highest rainfall rates in the rear quadrant within a training (non-moving) inflow band.[3] Normally, as a tropical cyclone intensifies, its heavier rainfall rates become more concentrated around its center.[4] Rainfall is found to be heaviest in tropical cyclone's inner core, whether it be the eyewall or central dense overcast, within a degree latitude of the center, with lesser amounts farther away from the center.[5] Most of the rainfall in tropical cyclones is concentrated within its radius of gale-force (34 knots/39 mph; 63 km/h) winds.[6] Rainfall is more common near the center of tropical cyclones overnight. Over land, outer bands are more active during the heating of the day, which can act to restrict inflow into the center of the cyclone. Recent studies have shown that half of the rainfall within a tropical cyclone is stratiform in nature.[7] The chart to the right was developed by Riehl in 1954 using meteorological equations that assume a gale radius of about 140 miles (230 km), a fairly symmetric cyclone, and does not consider topographic effects or vertical wind shear. Local amounts can exceed this chart by a factor of two due to topography. Wind shear tends to lessen the amounts below what is shown on the table.

Relation to storm size

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The relative sizes of Typhoon Tip, Cyclone Tracy, and the United States.

Larger tropical cyclones have larger rain shields, which can lead to higher rainfall amounts farther from the cyclone's center.[6] This is generally due to the longer time frame rainfall falls at any one spot in a larger system, when compared to a smaller system. Some of the difference seen concerning rainfall between larger and small storms could be the increased sampling of rainfall within a larger tropical cyclone when compared to that of a compact cyclone; in other words, the difference could be the result of a statistical problem.

Slow/looping motion on rainfall magnitude

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Storms which have moved slowly, or loop, over a succession of days lead to the highest rainfall amounts for several countries. Riehl calculated that 33.97 inches (863 mm) of rainfall per day can be expected within one-half degree, or 35 miles (56 km), of the center of a mature tropical cyclone. Many tropical cyclones progress at a forward motion of 10 knots, which would limit the duration of this excessive rainfall to around one-quarter of a day, which would yield about 8.50 inches (216 mm) of rainfall. This would be true over water, within 100 miles (160 km) of the coastline,[8] and outside topographic features. As a cyclone moves farther inland and is cut off from its supply of warmth and moisture (the ocean), rainfall amounts from tropical cyclones and their remains decrease quickly.[9]

Vertical wind shear impact on rainfall shield

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Vertical wind shear forces the rainfall pattern around a tropical cyclone to become highly asymmetric, with most of the precipitation falling to the left and downwind of the shear vector, or downshear left. In other words, southwesterly shear forces the bulk of the rainfall north-northeast of the center.[10] If the wind shear is strong enough, the bulk of the rainfall will move away from the center leading to what is known as an exposed circulation center. When this occurs, the potential magnitude of rainfall with the tropical cyclone will be significantly reduced.

Effect of interaction with frontal boundaries/upper level troughs

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As a tropical cyclone interacts with an upper-level trough and the related surface front, a distinct northern area of precipitation is seen along the front ahead of the axis of the upper-level trough. This type of interaction can lead to the appearance of the heaviest rainfall falling along and to the left of the tropical cyclone track, with the precipitation streaking hundreds of miles or kilometers downwind from the tropical cyclone.[11] The stronger the upper trough picking up the tropical cyclone, the more significant the left of track shift in the rainfall distribution tends to be.[7]

Mountains

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Moist air forced up the slopes of coastal hills and mountain chains can lead to much heavier rainfall than in the coastal plain. This heavy rainfall can lead to landslides, which still cause significant loss of life such as seen during Hurricane Mitch in Central America.

Global distribution

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Global tropical cyclone rainfall in 2005

Globally, tropical cyclone rainfall is more common across the northern hemisphere than across the southern hemisphere. This is mainly due to the normal annual tropical cyclone distribution, as between half and two-thirds of all tropical cyclones form north of the equator. Rainfall is concentrated near the 15th parallel in both hemispheres, with a less steep dropoff seen with latitude across the northern hemisphere, due to the stronger warm water currents seen in that hemisphere which allow tropical cyclones to remain tropical in nature at higher latitudes than south of the equator.[12] In the southern hemisphere, rainfall impacts will be most common between January and March, while north of the equator, tropical cyclone rainfall impacts are more common between June and November.[7] Japan receives over half of its rainfall from typhoons.[13]

United States tropical cyclone rainfall statistics

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U.S. Tropical Cyclone Rainfall Accumulations per time frame

Between 1970 and 2004, inland flooding caused a majority of the tropical cyclone-related fatalities in the United States.[14] This statistic changed in 2005, when Hurricane Katrina's impact alone shifted the most deadly aspect of tropical cyclones back to storm surge, which has historically been the most deadly aspect of strong tropical cyclones.[15] On average, five tropical cyclones of at least tropical depression strength lead to rainfall across the contiguous United States annually, contributing around a quarter of the annual rainfall to the southeast United States. While many of these storms form in the Atlantic basin, some systems or their remnants move through Mexico from the Eastern Pacific basin. The average storm total rainfall for a tropical cyclone impacting the lower 48 from the Atlantic basin is about 16 inches (410 mm), with 70–75 percent of the storm total falling within a 24-hour period. The highest point total was seen during Hurricane Harvey in 2017, when 60.58 inches (1,539 mm) fell in southeast Texas.[16]

See also

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Printed media

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  1. Ivan Ray Tannehill. Hurricanes. Princeton University Press: Princeton, 1942.
  2. Herbert Riehl. Tropical Meteorology. McGraw-Hill Book Company, Inc.: New York, 1954.
  3. Terry Tucker. Beware the Hurricane! Hamilton Press: Bermuda, 1966.

References

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  1. ^ "Are You Ready?". Federal Emergency Management Agency. 2006-04-05. Archived from the original on 2006-06-29. Retrieved 2006-06-24.
  2. ^ "Dennis, Katrina, Rita, Stan, and Wilma "Retired" from List of Storm Names Archived 2017-12-24 at the Wayback Machine." NOAA. Retrieved on June 14, 2008.
  3. ^ Tannehill 1942
  4. ^ E.B. Rodgers and R.F. Adler. Tropical Cyclone Rainfall Characteristics as Determined from a Satellite Passive Microwave Radiometer.[permanent dead link] Retrieved on 2008-04-16.
  5. ^ Riehl 1954
  6. ^ a b Corene J. Matyas. Relating Tropical Cyclone Rainfall Patterns to Storm Size. Archived 2006-10-25 at the Wayback Machine Retrieved on 2007-02-14.
  7. ^ a b c David M. Roth. Tropical Cyclone Rainfall Presentation (July 2007). Archived 2016-03-04 at the Wayback Machine Retrieved on 2007-07-19.
  8. ^ Russell Pfost. Tropical Cyclone Quantitative Precipitation Forecasting. Archived 2006-12-31 at the Wayback Machine Retrieved on 2007-02-25.
  9. ^ Roth, David M (May 12, 2022). "Maximum Rainfall caused by North Atlantic and Northeast Pacific Tropical Cyclones and their remnants Per State (1950–2020)". Tropical Cyclone Rainfall. United States Weather Prediction Center. Retrieved January 6, 2023. Public Domain This article incorporates text from this source, which is in the public domain.
  10. ^ Shuyi S. Chen, John A. Knaff, and Frank D. Marks, Jr. Effects of Vertical Wind Shear and Storm Motion on Tropical Cyclone Rainfall Asymmetries Deduced from TRMM. Archived 2007-11-29 at the Wayback Machine Retrieved on 2007-03-28.
  11. ^ Norman. W. Junker. Hurricanes and extreme rainfall. Retrieved on 2006-02-13.
  12. ^ Dominguez, Christian; Magaña, Victor (6 March 2018). "The Role of Tropical Cyclones in Precipitation Over the Tropical and Subtropical North America". Frontiers in Earth Science. 6: 19. Bibcode:2018FrEaS...6...19D. doi:10.3389/feart.2018.00019.
  13. ^ Whipple, Addison (1982). Storm. Alexandria, VA: Time Life Books. p. 54. ISBN 0-8094-4312-0.
  14. ^ Ed Rappaport. "Inland Flooding". National Oceanic & Atmospheric Administration. Archived from the original on 2012-01-11. Retrieved 2006-06-24.
  15. ^ Eric S. Blake; Jerry D. Jarrell; Edward N. Rappaport; Christopher W. Landsea. "The Deadliest, Costliest, and Most Intense United States Tropical Cyclones From 1851 to 2004". National Oceanic & Atmospheric Administration. Archived from the original on 2009-05-06. Retrieved 2006-06-24.
  16. ^ Roth, David M. (January 3, 2023). "Tropical Cyclone Point Maxima". Tropical Cyclone Rainfall Data. United States Weather Prediction Center. Retrieved January 6, 2023. Public Domain This article incorporates text from this source, which is in the public domain.
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