Severe Thunderstorms and Tornadoes in the United States

^Pr^ep^ar^{ed f}^o^r^M^e^m^b^ers^an^d^Com^mⁱ^t^t^ees^of^C^ong^r^e^ss

Severe thunderstorms and tornadoes affect communities across the United States every year,
causing fatalities, destroying property and crops, and disrupting businesses. Tornadoes are the
most destructive products of severe thunderstorms, and second only to flash flooding as the cause
for most thunderstorm-related fatalities. Damages from violent tornadoes seem to be increasing,
similar to the trend for other natural hazards, and some analysts indicate that losses of $1 billion
or more from single tornado events are becoming more frequent. Insurance industry analysts state
that tornadoes, severe thunderstorms, and related weather events have caused nearly 57%, on
average, of all insured losses in the United States in any given year since 1953.
Policies that could reduce U.S. vulnerability to severe thunderstorms and tornadoes include
improvements in the capability to accurately detect storms and to effectively warn those in harm’s
way. The National Weather Service (NWS) has the legal authority to forecast weather and issue
warnings. Some researchers suggest that there are limits to the effectiveness of improvements in
forecasting ability and warning systems for reducing losses and saving lives from severe weather.
The research suggests that, for example, social, behavioral, and demographic factors now play an
increasingly important role in tornado-related fatalities.
At issue for Congress is its role in mitigating damages, injuries, and fatalities from severe
thunderstorms and tornadoes. The National Science and Technology Council has recommended
that communities implement hazard mitigation strategies and technologies, some of which—such
as conducting weather-related research and development and disseminating results—Congress
has supported through annual appropriations for federal agencies such as the National Oceanic
and Atmospheric Administration, the National Science Foundation, the Federal Emergency
Management Agency, NASA, and others. Other recommended strategies include land use and
zoning changes, which are typically not in the purview of Congress.
Congress attempted to clarify the federal role in mitigating damages from windstorms (including
tornadoes and thunderstorms) by passing the National Windstorm Impact Reduction Act of 2004
(P.L. 108-360). It is not evident whether the program made progress toward its objective:
achievement of major measurable reductions in the losses of life and property from windstorms.
Authorization for the program expired at the end of FY2008. It is also unclear whether changes to
climate over the past half-century have increased the frequency or intensity of thunderstorms and
tornadoes. At issue for Congress is whether future climate change will lead to more frequent and
more intense thunderstorms and tornadoes, and whether efforts by Congress to mitigate long-term
global warming will also reduce future losses from thunderstorms and tornadoes.

Overvi ew ....................................................................................................................... .................. 1
Issues for Congress..........................................................................................................................1
Focus on Short-Term Detection and Warning...........................................................................2
Mitigation ..................................................................................................................... ............. 3
The National Windstorm Impact Reduction Program.........................................................4
Climate Change and Severe Weather........................................................................................5
Risk, Forecasting, and Warning.......................................................................................................6
Severe Thunderstorms...............................................................................................................7
Risks from Severe Thunderstorms............................................................................................7
Lightning ............................................................................................................................. 7
High Winds.........................................................................................................................8
Hail........................................................................................................................... ........... 8
Flash Floods........................................................................................................................8
Where and When Severe Thunderstorms Form........................................................................9
How and Why Thunderstorms Form.......................................................................................10
Squall Line........................................................................................................................10
Multicell Storm.................................................................................................................10
Supercell Storm.................................................................................................................10
Tornadoes ................................................................................................................................. 11
Risks from Tornadoes...............................................................................................................11
Where and When Tornadoes Form..........................................................................................13
How and Why Tornadoes Form..............................................................................................13
Forecasting and Warning: The Role of the National Weather Service....................................14
Convective Outlook..........................................................................................................15
Mesoscale Discussion.......................................................................................................15
Watch ................................................................................................................................ 16
Warning ............................................................................................................................. 16
Communicating the Severe Weather Risk...............................................................................16
Summary and Conclusions............................................................................................................17
Figure 1. Map Showing the Number of Recorded Tornadoes Greater than F3 in the
United States Between 1950 and 1998.......................................................................................14
Table 1. NWS and NOAA Funding from FY2004 to FY2008........................................................3
Table A-1. F-Scale and Enhanced F-Scale for Tornado Damage..................................................19

Appendix. Classifying Tornadoes: The F-Scale............................................................................19
Author Contact Information..........................................................................................................19

Severe thunderstorms and tornadoes affect communities across the United States every year,
causing fatalities, destroying property and crops, and disrupting businesses. State and local
governments are typically the first to respond to the consequences of extreme weather events, but
the federal government has responsibilities for forecasting and issuing warnings to citizens and
communities lying in harm’s way. When severe weather catastrophes overwhelm the resources of
state and local governments, the Stafford Act authorizes the President to issue major disaster or
emergency declarations, resulting in the distribution of a wide range of federal aid to those ¹
affected. Also, U.S. Department of Agriculture programs, such as federal crop insurance and
emergency disaster loans, can help farmers recover financially from severe weather disasters even ²
without a presidential disaster declaration.
Many observers note that although the number of lives lost each year to natural hazards in the ³
United States has decreased, the costs of major disasters continues to rise. According to the
National Science and Technology Council: “Due to changes in population demographics and
more complex weather-sensitive infrastructure, Americans today are more vulnerable than ever to
severe weather events caused by tornadoes, hurricanes, severe storms, heat waves, and winter ⁴
weather.”
This report first discusses issues that may be of interest to Congress in three general categories:
(1) forecasting and issuing warnings for severe thunderstorms and tornadoes; (2) the role of
mitigation; and (3) the effect of climate change. The second part of the report describes in more
detail the risk these hazards pose to communities and individuals; where, when, how, and why
they occur in the United States; and what damage they may cause. It also describes the role of the
National Weather Service in forecasting severe weather and communicating the risk to
communities and individuals at risk.

This report focuses on the risk from severe thunderstorms and tornadoes to U.S. citizens and
infrastructure, the federally sponsored forecast and warning systems, federally backed efforts to
improve the scientific understanding of severe weather phenomena, and efforts to mitigate the
risk of catastrophe. Congress has oversight and funding responsibilities for the federal agencies
charged with these tasks. At issue is whether those programs are effective at reducing damage,
injuries, and loss of life from severe thunderstorms and tornadoes.

¹^F^o^{r m}^o^{re i}ⁿ^f^o^rm^atⁱ^oⁿ^ab^ou^t^t^h^e^Ro^b^e^rt^T^.^S^t^af^f^o^rd^Di^sast^{er Rel}ⁱ^e^{f an}^d^E^m^ergen^c^y^A^s^si^st^an^ce^A^c^t^(t^h^e^S^t^af^f^o^rd^Act⁾^,
^s^e^e^C^R^S^R^e^por^{t R}^L³³⁰⁵^3,^Fe^de^{ral S}^t^aff^o^rd^Ac^{t Disaste}^r^Assistaⁿ^c^e^:^Pre^s^ideⁿ^tial^De^c^l^arati^ons,^Elig^ible^Ac^tiv^itie^s,^an^d
^Fun^dⁱⁿ^g^,^by^K^e^{ith Be}^a^.
²^F^o^{r m}^o^{re i}ⁿ^f^o^rm^atⁱ^oⁿ^on^f^e^d^e^ral^agri^cu^l^t^u^ral^assi^st^an^ce,^{see CRS}^Rep^o^r^t^RS²¹²¹²^,^Ag^ricu^l^t^u^r^a^l^Di^sa^{ster Assista}ⁿ^c^e^,
^by^R^a^{lph M. C}^h^ite^.
³^N^a^tiona^l^Sc^ie^nc^e^a^{nd T}^e^c^hnol^og^y^Counc^{il, Com}^m^ittee^{on E}ⁿ^vⁱ^ron^m^eⁿ^{t a}^{nd N}^a^tura^l^Re^s^ourc^e^s^{, S}^u^b^c^om^m^ittee^on
^Dⁱ^s^a^s^t^e^r^R^e^duc^tion,^“^G^r^a^{nd C}^h^a^l^l^e^ng^e^s^f^o^r^Dⁱ^s^a^s^t^e^r^R^e^duc^tion”⁽^W^a^s^hing^ton^,^D^C^{, J}^u^ne²⁰⁰⁵⁾^,^p.^1.^H^e^r^e^af^te^r^r^e^f^e^r^r^e^d
^{to a}^s^G^r^a^{nd C}^h^a^lle^ng^e^s^f^o^r^Dⁱ^s^a^s^t^e^r^R^e^duc^tio^{n (}²⁰⁰⁵⁾^.
⁴^Ibid^{., p. 4.}

Also at issue is the concept of disaster resilience; namely, those precautions and strategies—such
as improved building materials and structural systems—that decrease the vulnerability of
communities and individuals to severe thunderstorms and tornadoes. The federal role in
supporting programs of hazard mitigation, such as those included in the National Windstorm
Impact Reduction Act of 2004 (P.L. 108-360), is a concern for Congress. Authorization for the
Windstorm Impact Reduction Program expired at the end of FY2008, and it is not clear whether
the program achieved any of the goals specified in the legislation.
Projections of a changing climate for the United States and the possibility of a more intense
hydrologic cycle (e.g., more intense storms, rainfall, heat waves, and other phenomena) have
raised questions about whether the costs of severe weather disasters will continue to rise in the
future. Observers note that extreme events, more than shifts in average climate conditions, drive ⁵
changes in natural and human systems. According to the U.S. Climate Change Research
Program:
^Iⁿ^t^h^e^f^u^t^u^r^e^,^wⁱ^t^h^c^o^ntⁱⁿ^ue^d^gl^o^b^a^l^w^a^r^mⁱ^ng,^he^a^t^w^a^ve^{s a}ⁿ^d^he^a^v^{y d}^o^wⁿ^p^o^u^r^s^a^r^e^ve^r^y
^lik^el^y^to^fu^rth^e^rⁱⁿ^creas^eⁱⁿ^f^r^equ^eⁿ^c^y^aⁿ^{d i}ⁿ^tens^it^y^.^S^u^bs^taⁿ^t^{ial areas}^o^f^North^Am^{erica are}
^lⁱ^k^e^l^y^t^o^ha^ve^m^o^r^e^fr^e^q^ue^nt^d^r^o^ugh^t^s^o^f^gr^e^a^t^e^r^se^ve^rⁱ^t^y^.^H^u^r^rⁱ^c^aⁿ^e^wⁱ^nd^sp^e^e^d^s,^r^aⁱⁿ^fa^l^l
ⁱⁿ^teⁿ^s^it^y^,^an^d^sto^r^m^s^u^r^g^{e le}^v^e^{ls ar}^{e lik}^el^y^toⁱⁿ^crea^s^e^{. T}^h^{e s}^t^ron^g^e^s^t^{cold s}^eas^on^s^t^or^m^s^are⁶
^lⁱ^k^e^l^{y t}^o^b^e^c^o^m^e^mo^r^e^fr^e^q^ueⁿ^t^,^wⁱ^t^h^st^r^o^nge^r^wⁱ^nd^{s a}ⁿ^d^m^o^r^e^e^x^t^r^e^m^e^w^a^ve^heⁱ^g^ht^s.
Distinguishing between increased frequency and intensity of extreme weather events due to
global warming and other factors that contribute to higher costs from disasters—such as changing
demographics in hazard-prone regions—also may be an important issue for Congress.
Policies that reduce U.S. vulnerability to severe thunderstorms and tornadoes will likely include
improvements in the capability to accurately detect storms and to effectively warn those in harm’s
way. The National Weather Service (NWS) is authorized by law to forecast weather and issue
warnings. How Congress chooses to fund NWS and conduct oversight of its activities bears
directly on the agency’s effectiveness.
In its strategic plan for 2005-2010, the NWS cited several preferred outcomes for the nation,
including (1) reduced loss of life, injury, and damage to the economy; and (2) better, quicker, and ⁷
more valuable weather and water information to support improved decisions. To achieve these
outcomes, NWS would employ a strategy to “improve the reliability, lead-time, and
understanding of weather and water information and services that predict changes in ⁸
environmental conditions.” Improving the lead-time and reliability of severe thunderstorm and
tornado forecasts could provide communities and individuals with information to help them better
prepare and thus reduce their vulnerability.

⁵^C.^S^.^P^a^rm^es^an^et^al^.^,^“Im^p^act^{s o}^f^e^x^t^r^e^m^e^w^e^at^h^e^{r an}^d^clⁱ^m^at^{e o}ⁿ^t^e^rrest^ri^al^bⁱ^o^t^a,^”^B^u^lle^ti^{n o}^f^the^A^m^e^r^ic^an
^M^e^te^or^ologic^a^{l S}^o^cⁱ^e^t^y^{, v}^o^l.⁸³⁽²⁰⁰⁰⁾^,^p^p^{. 4}⁴³^-⁴^50.
⁶^U^.^{S. C}^lim^a^t^e^C^h^aⁿ^g^e^Sc^ie^nc^e^P^r^og^r^a^m^,^Sy^nthe^sⁱ^s^a^{nd A}^s^s^e^s^s^m^e^nt^P^r^o^duc^t^3.3^,^“^W^e^a^t^he^r^a^{nd C}^lim^ate^Ex^tr^em^e^s^{in a}
^Ch^an^giⁿ^g^Clⁱ^m^at^{e” (}^W^ashⁱⁿ^g^t^oⁿ^,^DC,^Juⁿ^e²⁰⁰⁸⁾^,^p.^V^II.^Hereaf^t^e^{r ref}^e^rr^ed^t^o^{as CCS}^P^,^W^eat^h^e^{r an}^d^Clⁱ^m^at^e
^E^x^t^r^e^m^{es i}ⁿ^{a Ch}^an^giⁿ^g^Clⁱ^m^at^{e (}²⁰⁰⁸⁾^.
⁷^NOAA^,^Natioⁿ^a^{l W}^eath^e^{r S}^e^rvic^{e S}^t^{rategic P}^l^{an f}^o^{r 2}⁰⁰⁵^-²⁰¹⁰^(Jan^.³^,²⁰⁰⁵^),^p^.¹³^;^{at h}^t^tp^:/^/www^.ⁿ^w^s^.ⁿ^o^aa.^go^v/sp^/.
⁸^Ibid^.

NWS receives the most funding of any agency or program within NOAA’s budget, and the local
warnings and forecasts (LW&F) program receives approximately 70% of the NWS funding each
year. Table 1 shows appropriations for the LW&F program, NWS, and overall NOAA
appropriations since FY2004.
Table 1. NWS and NOAA Funding from FY2004 to FY2008
^{(millions of}^doll^ars)
^{FY04 FY05 FY06 FY07}^a^FY08^{Change FY04-08}^{FY09 Request}
^LW&F^$57^{6.1 $56}^{0.5 $59}^{1.4 $61}^6.5^$65^{9.3 14.4%}^$66^3.2
^NWS^$82^{4.9 $78}^{2.3 $84}^{8.2 $88}^4.4^$91^{1.4 10.5%}^$93^0.7
^NOAA^b^$3,73^{1.7 $3,91}^{8.7 $3,91}^{1.5 $3,68}^4.1^$3,90^{7.3 4.7%}^$4,10^9.8
^{Source: NOAA, Blue Book (Budg}^{et Summary) for}^{fiscal years}²⁰⁰⁴^throug^{h 2}⁰⁰^9.
^{Notes: LW&F is the local warnin}^{gs and forecasts}^program^within^{NWS. Funding values u}^{sed as re}^p^{orted in the}
^{Control Tables chapter of}^the^bu^{dget summaries (not adjusted for}^inflation).
^a.^{Values reflect the FY2}⁰⁰⁷^budget^req^uest.
^b.^{Values reflect the total ap}^prop^{riated amounts, as re}^{ported in th}^e^{Control Tables chapter of}^the^bu^dget
^summaries.
As Table 1 shows, the NWS budget has increased at a higher percentage than the total NOAA
budget over the five-year period, and the LW&F program within NWS has increased at a higher
percentage than NWS itself. The LW&F program averages nearly three-quarters of the NWS
budget each year, indicating that short-term weather prediction and warning is a high priority for
NWS and for NOAA, in accord with its statutory authority. Reports from RAND and other
research organizations suggest, however, that reorienting research and development funding
toward longer-term loss reduction efforts—particularly for weather-related hazards—might ⁹
provide the nation with more long-lasting solutions to reducing natural disaster losses. These
recommendations favor increased focus on mitigation techniques and R&D to reduce loss of life
and property from severe weather hazards.
The National Science and Technology Council (NSTC) noted that the nation’s primary focus on
disaster response and recovery is “an impractical and inefficient strategy for dealing with these
ongoing threats. Instead, communities must break the cycle of destruction and recovery by ¹⁰
enhancing their disaster resilience” (italics added). Among the six “Grand Challenges”
identified in its report, the NSTC recommended that communities implement hazard mitigation
strategies and technologies, such as development of advanced construction materials and ¹¹
structural systems that allow facilities to “remain robust in the face of all potential hazards.” The

⁹^Ch^arl^e^{s M}^ead^{e an}^{d M}^e^gan^A^b^b^o^t^t^,^“A^sses^sⁱⁿ^{g fed}^e^ral^resear^ch^an^d^d^e^vel^o^p^m^en^t^f^o^{r h}^azard^l^o^{ss re}^du^ctⁱ^oⁿ^,^{” p}^r^ep^ared
^f^o^{r t}^h^{e Off}ⁱ^{ce o}^f^S^cⁱ^eⁿ^{ce an}^d^T^e^c^hⁿ^o^l^o^gy^P^o^lⁱ^c^y^(RA^N^D,^A^r^lⁱⁿ^gt^oⁿ^,^V^A^.⁾^,²⁰⁰³^,⁶⁵^p^.^S^{ee al}^{so “A}^d^vⁱ^{ce t}^o^t^h^{e New}
^A^d^mⁱ^nistra^{tion a}ⁿ^{d Co}^ng^re^{ss: A}^c^tions^to^Ma^k^e^{our Na}^tio^{n Re}^silieⁿ^t^to^Se^v^e^re^We^a^t^he^{r a}^{nd Clim}^a^t^e^Chaⁿ^g^e^,”^a
^doc^um^eⁿ^{t pr}^o^duc^e^d^by^the^Uⁿ^iv^e^r^s^ity^C^o^r^por^a^tion^f^o^r^A^t^m^o^s^phe^rⁱ^c^R^e^s^e^a^r^c^h^a^{nd s}^e^v^e^{n othe}^r^s^t^a^k^e^hol^de^r
^org^a^niz^a^{tions; a}^t^htt^p^://w^ww^.uc^a^r^.e^du/^td/.
¹⁰^G^r^a^{nd C}^h^a^lle^ng^e^s^f^o^r^Dⁱ^s^a^s^t^e^r^R^e^duc^tio^{n (}²⁰⁰⁵⁾^,^p.^1.
¹¹^Ibid^{., p. 8.}

report also recommended nonstructural mitigation measures, such as land use and zoning
regulations that recognize the risk of natural hazards. Land use measures, such as zoning laws and
building codes, are typically prerogatives of state and local governments, and thus the federal role ¹²
in that aspect of hazard mitigation is limited.
The federal role in developing disaster-resilient materials and structures, and evaluating their
relative effectiveness in mitigating damages from severe thunderstorms and tornadoes, has been
unclear. Congress attempted to clarify the federal role in mitigating damages from windstorms
(including tornadoes and thunderstorms) by passing the National Windstorm Impact Reduction
Act of 2004 (P.L. 108-360). The legislation identified three primary mitigation components: (1)
improved understanding of windstorms; (2) windstorm impact assessment; and (3) windstorm
impact reduction.
Authorization for the National Windstorm Impact Reduction Program expired on September 30,
2008, and it is not clear whether the program made progress toward its objective: achievement of
major measurable reductions in the losses of life and property from windstorms. That lofty goal
may have been difficult to achieve within the three-year authorization, even if appropriations for
the program matched authorization levels, and the program was well implemented. On these
points, the House Science and Technology Committee found that spending on the program by the
four agencies responsible for program implementation—the National Science Foundation, the
National Institutes of Standards and Technology (NIST), NOAA, and FEMA—was far below ¹³
authorized levels, and that the program had not been well implemented.
The Administration cites many research activities and other programs underway within each of
the four agencies that contribute to goals of the windstorm program and to the need to incorporate ¹⁴
wind hazards reduction measures into an “all-hazards view.” A biennial progress report
discussed the importance of aspects of the program—specifically the goal of increasing the ¹⁵
effectiveness of existing program efforts through better coordination among agencies. The
report indicated that interagency coordination is improving through the work of the Interagency ¹⁶
Working Group, established under §204 of P.L. 108-360. However, it is difficult to assess the
effect of improved interagency coordination on the broader goals of the program—to achieve
measurable reductions in loss of life and property—or whether the law has compelled the

¹²^S^{ee al}^so^t^e^stⁱ^m^oⁿ^y^gi^ven^b^y^S^h^ar^oⁿ^Hay^s^,^A^sso^ci^at^{e Di}^rect^o^r^an^d^Dep^u^t^y^Di^rect^o^r^f^o^{r S}^cⁱ^eⁿ^ce,^Offⁱ^{ce o}^f^S^cⁱ^eⁿ^{ce an}^d
^T^e^c^hnolog^y^P^o^lic^y^,^{to the}^Su^bc^o^m^m^itte^e^{on T}^e^c^hnolog^y^a^{nd In}^no^v^a^{tion, H}^o^us^e^Sc^ie^nc^e^aⁿ^d^T^e^c^hnolog^y^Com^m^itte^e^,
^Heariⁿ^g:^The^N^a^ti^on^{al W}ⁱⁿ^d^s^t^or^m^I^m^pac^{t Re}^duc^ti^on^Pr^ogr^am^:^Str^e^ngt^heⁿⁱ^{ng W}ⁱⁿ^d^s^t^or^m^H^a^z^a^r^d^Mⁱ^tⁱ^gati^oⁿ⁽^J^uly^24,
²⁰⁰⁸⁾^.
¹³^Su^bc^om^m^itte^e^{on T}^e^c^hnolog^y^a^{nd In}^nov^a^tio^{n, H}^ous^e^Sc^ie^nc^e^aⁿ^d^T^e^c^hnolog^y^Co^m^m^itte^e^,^H^e^a^r^ing^:^The^Na^tio^nal
^Wⁱ^nds^tor^m^I^m^p^a^c^t^Re^d^u^c^tio^{n Pr}^o^g^r^a^m^:^S^t^r^e^ngt^heⁿⁱ^{ng W}ⁱ^nds^tor^m^H^a^z^a^r^d^M^iti^gat^ioⁿ⁽^J^uly^24,²⁰⁰⁸⁾^,^H^e^a^r^ing^C^h^a^r^te^r^.
^T^h^e^subc^om^m^itte^e^e^s^ti^m^a^te^{d tha}^t^NO^AA^{, NIST}^{, a}^{nd FEMA}^speⁿ^{t a}^ppr^ox^im^a^t^e^l^y^$7.4⁵^m^illion^be^tw^e^e^{n FY2}⁰⁰⁴^aⁿ^d
^FY²⁰^08,^a^ppr^ox^im^a^t^e^l^y^17%^of^auth^or^iz^e^d^a^m^ounts^f^o^r^t^h^e^thr^e^e^a^g^eⁿ^cⁱ^e^s^{. Spe}^ndi^ng^f^o^r^N^{SF u}^nde^r^the^pr^og^r^a^m^is
^m^o^re^diff^ic^{ult to e}^s^tim^a^t^e^,^a^lthoug^{h N}^{SF re}^porte^dly^w^{ill s}^p^e^{nd a}^p^pr^ox^im^a^t^e^l^y^{$6.7 m}^illio^{n o}ⁿ^re^s^e^a^r^c^h^re^la^te^{d t}^o^t^h^e
^wⁱ^nds^tor^m^r^e^duc^tion^pr^og^r^a^m^{in FY}²⁰^08.
¹⁴^Sha^r^oⁿ^H^a^y^s^,^A^s^s^o^cⁱ^a^t^e^Dⁱ^r^e^c^t^or^a^{nd D}^e^pu^ty^Dⁱ^r^e^c^t^or^f^o^r^Sc^ie^nc^e^,^O^f^fⁱ^ce^of^Sc^ie^nc^e^a^{nd T}^e^c^hnolog^y^P^o^lic^y^,^{to the}
^Subc^om^m^itte^e^{on T}^e^c^hnolog^y^aⁿ^{d In}^nov^a^tio^{n, H}^ous^e^Sc^ie^nc^e^aⁿ^d^T^e^c^hnolog^y^Co^m^m^itte^e^,^he^a^r^ing^:^The^N^a^tⁱ^o^nal
^Wⁱ^nds^tor^m^I^m^p^a^c^t^Re^d^u^c^tio^{n Pr}^o^g^r^a^m^:^S^t^r^e^ngt^heⁿⁱ^{ng W}ⁱ^nds^tor^m^H^a^z^a^r^d^M^iti^gat^ioⁿ⁽^J^uly^24,²⁰⁰⁸⁾^.
¹⁵^Wⁱ^nds^tor^m^I^m^pa^c^t^R^e^duc^tion^P^r^og^r^a^m^Bⁱ^e^nnia^l^P^r^og^r^e^s^s^R^e^por^{t f}^o^r^Fis^c^a^l^Y^e^a^r^s²⁰^05-²⁰^06.
¹⁶^Ibid^.

agencies to do more than what they had already been trying to achieve without passage of the
National Windstorm Impact Reduction Act. The Administration further concludes that the
benefits of an improved understanding of severe wind hazards will not be fully realized until that ¹⁷
understanding is incorporated more completely into actions at the state and local level.
Senator Bill Nelson introduced S. 3638 on September 26, 2008, to reauthorize the National
Windstorm Impact Reduction Program through FY2013 and to expand the agencies involved
under an interagency working group to also include the U.S. Department of Transportation
(DOT), the U.S. Army Corps of Engineers (Corps), NASA, and the Office of Management and
Budget (OMB). The bill would have designated NIST as lead agency for the interagency working
group, similar to its role as lead agency for the National Earthquake Hazards Reduction ¹⁸
Program. The bill was referred to the Senate Commerce, Science, and Transportation
Committee. The committee did not act on the legislation.
According to several reports that synthesize recent findings in the scientific literature, there will
likely be changes in the intensity, duration, frequency, and geographic extent of weather and ¹⁹
climate extremes as the Earth continues to warm. These changes may continue upward trends
that have already been observed, such as the frequency of unusually warm nights, frequency and ²⁰
intensity of extreme precipitation events, and the length of the frost-free season. However, the
evidence is unclear as to whether the frequency and intensity of severe thunderstorms and
tornadoes has increased or will increase in the future due to climate change.
Part of the difficulty in sorting out trends in frequency and intensity of severe thunderstorms and
tornadoes lies in the way they have been observed and reported. For example, the number of ²¹
annual reported tornado occurrences has doubled between 1954 and 2003. Some studies indicate
that the doubling reflects changes in observing and reporting. When the artificial trend produced
by these changes is removed, the adjusted data show little or no trend in the number of reported ²²
tornadoes since the 1950s.
Reports of severe thunderstorms without associated tornadoes increased by a factor of 20 between ²³
1955 and 2004. However, researchers indicate that the increase is mainly in reports of
marginally severe thunderstorms, and suggest that the evidence for a change in the long-term ²⁴
trend of severe thunderstorms is lacking. In studies that reanalyze environmental conditions that
could have produced severe thunderstorms, changes in the frequency of those environmental

¹⁷^Sha^r^oⁿ^H^a^y^s^te^s^tⁱ^m^on^y⁽^J^ul^y^24,²⁰⁰⁸⁾^.
¹⁸^A^l^{so k}^now^{n a}^s^NEHRP^,^a^m^u^ltia^g^e^nc^y^prog^ra^m^re^a^u^thoriz^e^d^u^nde^r^P^.^L^.¹⁰^8-3⁶⁰^to^re^duc^e^t^h^e^na^ti^oⁿ^a^l^risk^f^r^om
^e^a^r^thqua^k^e^dis^a^s^t^e^r^s^.^For^m^o^r^e^inf^o^r^m^a^{tion, s}^e^e^C^R^S^R^e^por^{t R}^L³³⁸^61,^Eart^hq^uak^e^s^{: Risk}^{, M}^o^nitoriⁿ^g^{, No}^tific^at^io^n,
^and^Re^s^e^ar^c^h^,^by^P^e^te^{r Folg}^e^r^.
¹⁹^C^C^S^P^,^W^e^a^t^he^r^a^{nd C}^lim^a^t^e^Ex^t^r^em^e^s^{in a}^C^h^aⁿ^gⁱ^ng^C^lim^a^t^e⁽²⁰⁰⁸⁾^{; I}^P^C^C^,^C^lim^ate^C^h^an^ge²⁰⁰⁷^:^Sy^nt^he^sⁱ^s
^Re^por^{t. C}^ontrⁱ^bu^tioⁿ^{of W}^o^r^kⁱⁿ^g^G^r^oups^I,^II,^an^{d III t}^o^t^h^e^F^our^th^As^s^e^s^s^m^eⁿ^{t Re}^por^{t o}^f^t^h^e^Inte^r^g^o^v^e^r^nm^eⁿ^{tal P}^ane^l
^{on C}^l^im^ate^C^h^an^ge^(G^en^eva,^S^wⁱ^t^zerl^aⁿ^d⁾^,²⁰⁰⁷^,¹⁰⁴^p^.
²⁰^C^C^S^P^,^W^e^a^t^he^r^a^{nd C}^lim^a^t^e^Ex^t^r^em^e^s^{in a}^C^h^aⁿ^gⁱ^ng^C^lim^a^t^e⁽²⁰⁰⁸⁾^,^p.³⁵^.
²¹^I^b^id^{., p. 76.}
²²^Ibid^{., F}ⁱ^g^u^re^2.25^.
²³^I^b^id^{., p. 77.}
²⁴^Ibid^.

conditions are observed. However, the record of observations may not be long enough to ²⁵
determine the range of natural variability. Given the uncertainty, it is not yet possible to
determine if these changes are due to natural variability or changing climatic conditions from
greenhouse warming.
Excessive rainfall from severe thunderstorms may trigger flash floods, which are typically
responsible for most flood-related deaths in the United States each year. According to researchers,
one of the clearest trends over the last 30 years has been an increase in the frequency and ²⁶
intensity of heavy precipitation events. Despite this clear trend, the relationship between these
heavy precipitation events and the frequency and intensity of severe thunderstorms is not clear,
nor do scientists agree on the relationship between increased precipitation and streamflow ²⁷
extremes, such as flooding. As a further complication, studies of trends in streamflow using ²⁸
similar data have produced different results. Also, human influences on streamflow, such as ²⁹
building dams and creating large reservoirs, may mask climatic changes.
Climate model predictions suggest that with continued global warming due to increasing ³⁰
concentrations of atmospheric greenhouse gases, precipitation intensity is projected to increase.
However, it is unclear whether this intensification of precipitation is or will be linked in the future
to more severe thunderstorms, and to more severe or more frequent flash floods.
The section below discusses why severe thunderstorms and tornadoes are threats to some areas of
the country and not others, and why they occur during some parts of the year and not others. The
following section also describes the role of the National Weather Service in forecasting and
issuing warnings, and its relationship to private forecasters and the news media in providing clear
and consistent messages to the public at risk.

Thunderstorms and tornadoes affect U.S. citizens and communities every year, albeit only rarely
with the same level of widespread destruction as a major hurricane or flood. Although floods are
one consequence of severe thunderstorms, floods that cause widespread and prolonged
destruction are typically not annual events in the United States. Major floods, such as those that
affected parts of the Mississippi River region in the Midwest in 2008 and in 1993, are the result ³¹
of many factors and are not solely caused by heavy rains from severe thunderstorms.

²⁵^C^C^S^P^,^W^e^a^t^he^r^a^{nd C}^lim^a^t^e^Ex^t^r^em^e^s^{in a}^C^h^aⁿ^gⁱ^ng^C^lim^a^t^e⁽²⁰⁰⁸⁾^,^p.⁷⁷^.
²⁶^Ibid^.,^pp.⁴⁶^-4^7.
²⁷^P^e^r^s^ona^{l c}^o^m^m^unic^a^{tion, K}^eⁿⁿ^e^t^{h K}^u^nk^e^l^{, Ex}^e^c^u^tiv^e^Dⁱ^r^e^c^t^or^of^the^Dⁱ^vⁱ^sⁱ^on^of^A^t^m^o^s^phe^rⁱ^c^Sc^ie^nc^e^,^D^e^s^e^r^t
^Re^se^a^r^c^h^Institute^{, Re}ⁿ^o^{, N}^V^,^Se^pt,^22,²⁰⁰⁹^.
²⁸^S^ee,^f^o^{r exa}^m^p^l^e,^H.^F^.^Lⁱⁿ^s^an^d^J.^R.^S^l^ack,^“S^t^r^eamf^l^o^w^t^r^en^d^sⁱⁿ^t^h^{e Un}ⁱ^t^ed^S^t^at^es,^”^G^e^o^phy^sⁱ^c^a^{l Re}^s^e^ar^c^h
^Le^tte^rs^{, v}^o^{l. 2}⁶⁽¹⁹⁹⁹⁾^,^p^p^.²²^7-²^{30; a}^nd^{P. Y}^a^{. G}^r^ois^m^aⁿ^e^t^a^l^{., “}^H^e^a^v^y^pr^e^cⁱ^pita^tion^aⁿ^d^hig^h^s^t^r^e^am^f^l^ow^{in the}^th
^c^ontig^u^ous^Uⁿ^ite^{d S}^t^a^t^e^s^{: tr}^e^ndsⁱⁿ^the²⁰^cen^t^u^ry^,^”^Bulle^ti^{n of}^the^Ame^r^ic^{an M}^e^te^orolo^g^ic^al^S^o^cⁱ^e^t^y^,^vo^l^.⁸²⁽²⁰⁰¹⁾^,
^{pp. 21}^9-²⁴⁶^.
²⁹^C^C^S^P^,^W^e^a^t^he^r^a^{nd C}^lim^a^t^e^Ex^t^r^em^e^s^{in a}^C^h^aⁿ^gⁱ^ng^C^lim^a^t^e⁽²⁰⁰⁸⁾^,^p.⁵³^.
³⁰^I^b^id^{., p. 10}^2.
³¹^{For a}^lⁱ^s^t^of^{CRS e}^x^pe^rts^oⁿ^t^h^e^Midw^e^s^{t f}^l^ooding^of²⁰⁰⁸^{, s}^e^e^htt^p^://w^w^w^.^c^rs^.g^ov^/^e^x^p^e^r^ts^/W^E040^10.s^h^tm^l.

Compared to tropical storms such as hurricanes, thunderstorms are small and short-lived, but can
still be dangerous. An average thunderstorm is 15 miles in diameter and lasts an average of 30
minutes. Thunderstorms also occur much more frequently than large tropical storms. There are an ³²
estimated 100,000 thunderstorms in the world each year, of which 10% are severe. A severe
thunderstorm is defined by the NWS as one that produces hail at least three-quarters of an inch in ³³
diameter, has winds of 58 miles per hour or higher, or produces a tornado.
Severe thunderstorms may produce lightning, high winds, hail, flash floods, and tornadoes, any of
which may be a hazard to people and property. Lightning can cause fires as well as deaths when
people are directly struck. Heavy rainfall from thunderstorms can cause flash floods, which can
change small creeks into raging torrents in minutes. Hail can cause crop damage, and large hail
can damage cars, roofs, and windows. Strong, straight-line winds can knock down trees and ³⁴
power lines, and can sometimes cause damage equal to that caused by many tornadoes.
Downbursts—outward bursts of damaging winds on or near the ground—can cause wind shear
and lead to aircraft accidents. Tornadoes, the most destructive phenomenon associated with ³⁵
thunderstorms, can destroy structures and cause fatalities. (Tornadoes are discussed separately
below.)
Severe thunderstorms can produce lightning, high winds, hail, and heavy rainfall which may lead
to flash flooding. All of these phenomena may pose a risk to people and property depending on
their location and the storm’s intensity.
Lightning is commonly considered the most dangerous and most frequently encountered weather
hazard. Between 1977 and 2006, an average of 62 people were killed each year by lightning in ³⁶
the United States. Lightning-caused fatalities are often highest each year in Florida. Lightning is
also the primary cause of wildfires, which threaten natural resources, homes, businesses, and
lives, particularly in the West. The National Oceanic and Atmospheric Administration (NOAA)
National Severe Storms Laboratory estimates that lighting causes approximately $4-$5 billion in

³²^N^a^tiona^l^Se^v^e^r^e^Stor^m^s^L^a^bor^a^t^or^y^,^“^S^ev^e^r^e^W^e^a^t^he^r^P^r^im^e^r^{: T}^hunde^r^s^tor^m^s^,^”^a^t^http:^//w^w^w^.ns^s^l^.n^oa^a^.^g^o^v^/^pr^im^e^r^/
^tstorm^/^t^st_^b^a^s^ic^s.htm^l^.
³³^NW^{S, “}^A^Co^m^p^re^he^nsiv^e^G^l^ossa^ry^o^f^We^a^t^he^{r T}^e^r^m^s^f^o^{r Storm}^Spotte^rs,”^a^t^http^://w^ww^.srh.noa^a^.^gov^/ouⁿ^/
^s^e^v^e^r^e^w^x^/^g^los^s^a^r^y^4.php.
³⁴^S^t^rai^g^h^t^-lⁱⁿ^{e w}ⁱⁿ^d^s^{are st}^roⁿ^g^wⁱⁿ^d^s^p^r^od^u^ced^b^y^{a t}^h^uⁿ^d^e^rst^o^rm^t^h^at^{are n}^o^t^asso^ci^at^ed^wⁱ^t^h^ro^t^a^tⁱ^on^,^as
^dis^ting^u^is^he^{d f}^r^om^torⁿ^a^d^oe^s^,^w^h^ic^{h a}^r^e^na^r^r^o^w^,^vⁱ^oleⁿ^tly^r^o^ta^ting^c^o^lumⁿ^s^of^aⁱ^r^e^x^te^nding^f^r^om^{the ba}^s^e^of^a
^thu^nde^r^s^tor^m^{to t}^h^e^g^r^ou^nd^.
³⁵^N^a^tiona^l^Se^v^e^r^e^Stor^m^s^L^a^bor^a^t^or^y^,^“^S^ev^e^r^e^W^e^a^t^he^r^P^r^im^e^r^{: T}^hunde^r^s^tor^m^s^,^”^a^t^http:^//w^w^w^.ns^s^l^.n^oa^a^.^g^o^v^/^pr^im^e^r^/
^tstorm^/^t^st_^d^a^m^a^g^e^.^ht^m^l^.
³⁶^Florⁱ^d^a^ha^s^m^o^r^e^lig^htni^ng^s^t^rⁱ^k^e^s^thaⁿ^aⁿ^y^othe^r^s^t^a^t^e^aⁿ^d^ha^s^the^f^our^{th h}ⁱ^g^h^e^s^{t p}^o^p^u^la^tio^{n i}ⁿ^t^h^e^Uⁿ^ite^d^Sta^t^e^s^{. O}ⁿ
^avera^g^e,¹⁰^p^e^op^l^e^di^{e each}^y^e^{ar i}ⁿ^F^l^o^rⁱ^d^{a f}^r^o^m^lⁱ^g^h^tⁿⁱⁿ^g^.^Natⁱ^oⁿ^a^l^W^eat^h^e^{r S}^e^rvi^ce,^“N^at^u^r^al^Hazar^d^S^t^atⁱ^s^tⁱ^c^s,^{” at}
^http:^//w^w^w^.^w^e^a^t^he^r^.^g^o^v^/^os^/^h^a^z^s^t^a^ts^.s^htm^l^#.

damage each year, affecting buildings, communications systems, power lines, and electrical ³⁷
systems.
Damage caused by severe straight-line winds during thunderstorms occurs more commonly than ³⁸
damage caused from tornadoes. Straight-line wind speeds that can occur during severe
thunderstorms may reach up to 100 miles per hour (although damaging winds are classified as ³⁹
those exceeding 50-60 mph). Estimates for the annual amount of damage caused by high winds
are not provided in this report because wind damage from tropical storms, thunderstorms, and
tornadoes are often reported together.
Damaging winds can develop with little or no advanced warning. Microbursts—one category of
damaging winds—are dangerous to aviation and can occur in an isolated rain shower or ⁴⁰
thunderstorm. Downbursts or microbursts may produce wind shear—a variation in wind speed
and/or direction over a short distance—which can slow airspeed and cause an aircraft to lose
altitude when a plane is taking off or landing and is near the ground.
Although Florida typically experiences the most thunderstorms in the United States each year, ⁴¹
Nebraska, Colorado, and Wyoming normally experience the most hail storms. Crops are
particularly vulnerable to hail damage; even relatively small hail can severely damage plants in
minutes. Hail greater than three-quarters of an inch in diameter is considered severe and
potentially damaging to aircraft. Hail also damages vehicles, roofs of buildings and homes, and ⁴²
landscaping. Damage from hail approaches $1 billion in the United States each year. Hail has
been known to cause injury to humans, and occasionally has been fatal.
Floods are a common and widespread natural hazard in the United States.⁴³ Flash floods as
discussed in this report can also cause significant damage and fatalities, but they result from

³⁷^Na^tiona^l^Se^v^e^re^Storm^s^L^a^bora^t^ory^,^“^S^e^v^e^r^e^W^e^a^t^he^r^P^r^im^e^r^{: L}ⁱ^g^h^tning^,^”^a^t^h^ttp^://w^ww^.nssl.noa^a^.^gov^/prim^e^r/
^lig^htni^ng^/ltg^_da^m^a^ge^.htm^{l. T}^h^e^Na^tiona^{l L}ⁱ^g^h^tniⁿ^g^Sa^f^e^t^y^Institute^indic^a^t^e^s^tha^t^losse^{s f}^r^om^lig^htning^m^a^y^be^$5-$6
^billi^on^pe^{r y}^e^a^r^{. Se}^e^http://w^w^w^.l^ig^htning^s^a^f^e^t^y^.c^o^m^/ⁿ^ls^i_l^l^s^/^nlsⁱ^_a^nnua^l^_us^a^_^los^s^e^s^.^htm^.
³⁸^Na^tiona^l^Se^v^e^re^Storm^s^L^a^bora^t^ory^,^“^S^e^v^e^r^e^W^e^a^t^he^{r P}^r^im^e^r^{: Da}^m^a^gⁱ^ng^Wⁱ^nds,”^a^t^http^://w^ww^.nssl.^noa^a^.^g^o^v^/
^pr^im^e^r^/^w^ind/wⁱ^nd_ba^sⁱ^c^s^.htm^l.
³⁹^Ibid^.
⁴⁰^Mⁱ^cro^b^u^r^st^{s are sm}^al^l^,^coⁿ^cen^t^r^at^ed^dow^nb^ur^s^t^s^f^r^om^a^thunde^r^s^t^o^r^m^{, us}^ua^ll^y^le^s^s^thaⁿ^{4 k}ⁱ^l^o^m^e^te^r^s^a^c^r^os^s^,^tha^t
^p^r^od^u^{ce an}^o^u^t^w^a^rd^bu^rst^o^f^d^a^magiⁿ^g^wⁱⁿ^d^s^at^t^h^{e grou}^nd^su^rf^ace.^Do^w^nbur^s^t^s^a^r^e^sⁱ^m^ila^r^{to m}ⁱ^c^r^obur^s^t^s^but^la^r^g^e^r^,
^us^ua^lly^g^r^e^a^t^e^r^thaⁿ⁴^k^ilom^e^te^r^s^a^c^r^os^s^.^Se^e^http:^//w^w^w^.ns^s^l^.noa^a^.^g^o^v^/^pr^im^e^r^/^w^ind/wⁱ^nd_ba^sⁱ^c^s^.ht^m^l.
⁴¹^In^t^h^{e h}ⁱ^{gh p}^l^aiⁿ^s^o^f^t^h^{ese t}^h^{ree s}^t^at^{es t}^h^{e f}^r^eeziⁿ^g^l^e^vel^s^ar^e^m^u^ch^cl^o^s^{er t}^o^t^h^{e gro}^uⁿ^d^t^h^{an at}^{sea l}^e^vel^.^A^t^se^{a l}^e^vel
^t^h^{e h}^aⁱ^l^h^a^{s m}^o^{re t}ⁱ^m^{e t}^o^m^e^l^t^b^e^fo^{re reach}ⁱⁿ^{g t}^h^{e grou}^nd^.^S^{ee Nat}ⁱ^oⁿ^a^l^S^e^{vere S}^t^o^r^m^s^L^a^b^o^r^at^o^r^y^,^“^S^evere^W^eat^h^e^r
^P^r^im^e^r^{: Ha}^il,”^a^t^htt^p^://w^ww^.nssl.noa^a^.^g^o^v^/^prim^e^r^/ha^il/ha^il_^da^m^a^ge^.htm^l.
⁴²^Ibid^.
⁴³^Slow^ly^de^ve^loping^aⁿ^{d w}ⁱ^de^s^p^r^e^a^d^f^l^oods^{, s}^u^c^h^a^s^t^h^e²⁰⁰⁸^aⁿ^{d 1}⁹⁹³^f^l^oods^a^l^ong^t^h^e^Mis^sⁱ^s^sⁱ^p^pⁱ^Rⁱ^v^e^r^,^c^aⁿ^c^a^u^s^e
^billi^ons^of^dolla^rsⁱⁿ^f^l^oo^d-re^la^te^d^da^m^a^g^e^s^,^a^lthoug^{h t}^h^eⁿ^u^m^b^e^r^{of de}^a^t^hs^f^r^om^f^l^oods^is^s^m^a^{ll in t}^h^e^Uⁿ^ite^d^Sta^t^e^s
^r^e^la^tiv^e^{to s}^o^m^e^othe^r^c^o^uⁿ^tr^ie^s^.^For^e^x^a^m^ple^,^{in 19}⁹⁸^f^l^oods^r^e^s^u^l^ting^f^r^om^H^u^r^rⁱ^c^aⁿ^e^Mitc^{h r}^e^s^u^lte^{d in}^ov^e^r^9,⁰⁰⁰
⁽^c^onti^nue^d.^..)

short-lived thunderstorms, and not from a prolonged weather pattern that produces higher than ⁴⁴
normal amounts of precipitation over several days or weeks.
Flash floods are short in duration.⁴⁵ They are most commonly associated with thunderstorms,
severe weather, and melting snow or ice. Flash floods can occur within minutes or a few hours of
excessive rainfall, such as that from a severe thunderstorm or a series of thunderstorms occurring
over the same location. Because flash floods can occur suddenly and with little warning, they are
the most dangerous types of floods; typically most flood-related deaths each year in the United ⁴⁶
States are caused by flash floods. It is difficult to assess the costs of actual damage from flash
floods each year; cost estimates may vary widely, and the actual costs may not consistently ⁴⁷
correlate to preliminary estimates.
Thunderstorms occur most frequently over the Florida peninsula and in other parts of the
Southeast, although the most severe weather threat from thunderstorms extends from Texas to ⁴⁸
southern Minnesota along the Great Plains and midwestern United States. Thunderstorms are
most likely to occur in the spring and summer and during the afternoon and evening. In the Great
Plains, most thunderstorms occur in the afternoon and at night; and along the Gulf Coast, ⁴⁹
southeastern United States, and western states they occur most frequently in the afternoon.
The greatest potential for severe weather develops in geographical regions that are subject to
warm, humid air at low levels while dry, conditionally unstable air prevails aloft. Thunderstorms
form during the summer in the southern Great Plains when a southerly flow of warm, very moist
air from the Gulf of Mexico meets with a dry, westerly current aloft. The thunderstorms that form
in Colorado, Arizona, and New Mexico are due to orographic lifting—ascending airflow caused
by the Rocky Mountains. Few thunderstorms occur along the west coast of the United States
because this region is frequently influenced by cooler, maritime air masses that suppress ⁵⁰
convectional uplift over land.

^(...c^on^tin^ue^d)
^d^eat^h^sⁱⁿ^Cen^t^ral^A^m^eri^ca,^al^t^h^o^ugh^so^m^e^so^u^r^{ces est}ⁱ^m^a^t^e^a^s^m^aⁿ^y^{as 1}⁸^,⁰⁰⁰^d^eat^h^s^f^r^o^m^Hu^rri^can^{e M}ⁱ^t^c^h^.^S^{ee Ro}^ger
^A^.^Pⁱ^e^l^k^e^{, J}^r^{. a}ⁿ^d^Ma^r^y^W^.^D^o^wⁿ^ton,^“^P^r^e^cⁱ^pita^ti^{on a}^nd^da^m^a^gⁱ^ng^f^l^oods^{: T}^r^e^ndsⁱⁿ^the^Uⁿ^ite^d^Sta^t^e^s^{, 19}^32-⁹⁷^,”
^Jo^u^r^na^l^of^C^lⁱ^m^at^e^,^v^o^{l. 13}⁽^O^c^t^{. 15, 20}⁰⁰⁾^,^p^p^{. 36}²⁵^-³⁶³⁷^.
⁴⁴^Sigⁿ^if^ic^aⁿ^{t f}^l^oodi^ng^a^l^ong^t^h^e^m^a^{in s}^t^e^m^s^of^la^r^g^e^rⁱ^v^e^r^ba^sⁱ^ns^{, s}^u^c^h^a^s^the^Mis^sⁱ^s^sⁱ^p^p^{i R}ⁱ^v^e^r^,^r^e^s^u^lt^s^f^r^o^m^e^x^c^e^s^sⁱ^v^e
^pr^e^cⁱ^pita^tioⁿ^ov^e^r^w^e^e^k^s^or^m^ont^hs^{. Se}^e^C^C^S^{P, W}^e^a^t^he^r^a^{nd C}^lim^a^t^e^Ex^tr^em^e^s^{in a}^C^h^aⁿ^gⁱ^ng^C^lim^a^t^e⁽²⁰⁰⁸⁾^,^p.⁵⁰^.
⁴⁵^A^N^a^tiona^{l W}^e^a^t^he^{r Se}^rv^ic^e^defⁱ^nitioⁿ^of^f^l^a^s^h^f^l^ood^is^a^f^l^{ood c}^a^u^s^e^{d by}^he^a^v^y^{or e}^x^c^e^s^sⁱ^v^e^ra^infa^{ll in a}^s^h^ort^pe^rio^d
^of^tim^e^,^g^e^ne^ra^ll^y^le^{ss tha}ⁿ^six^ho^urs.
⁴⁶^Deat^h^s^d^u^e^t^o^f^l^o^o^dⁱⁿ^g^creat^ed^by^Hu^rri^can^{e Kat}^rⁱⁿ^{a i}ⁿ²⁰⁰⁵^f^a^{r e}^x^ceed^ed^t^h^{e a}^nnua^l^a^v^e^r^a^g^e^num^be^r^of^f^l^as^{h f}^l^ood-
^rel^a^t^e^d^d^eat^h^s^;^h^o^w^ever,^m^aⁿ^y^co^m^p^lⁱ^catⁱⁿ^g^f^act^o^r^s^m^a^k^e^co^m^p^ari^s^oⁿ^b^e^t^w^een^h^u^rri^can^e-iⁿ^d^u^ced^f^l^oo^dⁱⁿ^g^an^d^f^l^ash
^f^l^oods^dif^fⁱ^c^u^{lt, s}^u^c^h^a^s^t^h^e^r^o^le^o^f^le^ve^e^s^{, s}^t^or^m^s^u^r^g^e^,^tide^s^{, a}ⁿ^d^ot^he^r^f^a^c^t^or^s^.
⁴⁷^M^a^ry^W^.^Do^wⁿ^t^oⁿ^and^Ro^{ger A}^.^Pⁱ^el^ke,^Jr.^,^“Ho^w^accu^rat^e^{are d}ⁱ^sast^{er l}^o^{ss d}^a^t^{a? T}^h^{e case o}^f^U.^S^.^fl^o^o^d^d^a^m^a^ge,^”
^Natura^{l Hazar}^d^s^{, v}^o^l^.³⁵⁽²⁰⁰⁵⁾^,^pp.²¹^1-²²⁸^.
⁴⁸^NOAA^N^a^tioⁿ^a^{l Sev}^e^{re Sto}^r^m^s^L^a^b^o^r^ato^r^y^,^{at h}^ttp^://w^ww^.n^ssl.n^o^aa.g^o^v^/^p^r^im^er/tsto^rm^/^t^st_^c^lim^ato^l^o^g^y^.h^tm^l.
⁴⁹^Ibid^.
⁵⁰^P^h^y^s^ic^a^l^G^e^og^r^a^phy^.ne^t^{, “}^T^hunde^r^s^tor^m^s^a^{nd T}^o^rⁿ^a^doe^s^,^”^a^t^h^ttp:^/^/^w^w^w^.ph^y^sⁱ^c^a^l^g^e^og^r^a^ph^y^.^ne^t/f^und^am^eⁿ^ta^ls^/
^7t.h^tm^l.

A thunderstorm forms when moist, unstable air is vertically lifted in the area by unequal warming
of the Earth’s surface, orographic lifting due to a topographic obstruction (such as a mountain or
mountain range), or the presence of a weather front. Three types of thunderstorms can produce ⁵¹
severe weather: a squall line, a multicell storm, and a supercell storm.
A squall line is a line of storms with a continuous, well developed gust front—a boundary that
separates a cold downdraft of a thunderstorm from warm, humid surface air—at the leading edge
of the line. Severe weather frequently occurs near the updraft/downdraft interface at the storm’s
leading edge. Downburst winds are the main threat. Hail as large as golf balls along with
gustnadoes—weak and short lived tornadoes—can occur. Flash flooding can occur when the
squall line slows down or even becomes stationary, with thunderstorms forming parallel to the
line and repeatedly moving across the same area.
A multicell storm consists of a group of cells moving as a single unit, with each cell in a different ⁵²
stage of the thunderstorm life cycle. As the multicell storm evolves, individual cells take turns at
being the most dominant. New cells tend to form along the upwind (typically western or
southwestern) edge of the cluster, with mature cells located at the center and dissipating cells
found along the downwind (eastern or northeastern) portion of the cluster. Multicell storms come ⁵³
in a variety of shapes, sizes, and intensities. They are stronger than single cell thunderstorms,
but less severe than supercell storms. Each cell in a multicell storm lasts about 20 minutes;
however, the multicell cluster may persist for several hours. Most flash floods occur during ⁵⁴
multicell storm events.
A supercell storm is defined as a storm with a persistent rotating updraft in which the entire storm ⁵⁵
behaves as a single entity, rather than as a group of cells. These supercell storms are the most
dangerous and rarest of the thunderstorms; they produce strong downbursts of 80 mph or more
and damaging hail, and they can last for hours. Some are very prolific precipitation producers,
whereas others produce very little precipitation that reaches the ground. The leading edge of the
precipitation from a supercell is usually light rain. Heavier rain falls closer to the updraft with

⁵¹^Jo^hn^M^.^W^a^l^l^{ace an}^d^P^e^t^e^r^V^.^H^obbs^,^Atm^o^s^phe^rⁱ^c^Sc^ie^nc^e^:^Aⁿ^Iⁿ^tr^oduc^t^o^r^y^S^u^r^v^e^y^(S^an^Di^ego^,^C^A^:^A^c^ad^e^mⁱ^c
^P^r^e^s^s^,¹⁹⁷⁷⁾^,^p.²^40.
⁵²^A^cel^l^{in m}^e^t^e^or^olog^y^r^e^f^e^r^s^{to a}ⁿ^u^pdr^a^f^{t or}^dow^ndr^a^f^{t or}^c^o^m^bⁱⁿ^a^tion^of^bot^{h. U}^pdr^a^f^ts^a^{nd d}^o^w^ndr^a^f^ts^{, or}^theⁱ^r
^c^o^m^b^ina^{tion r}^e^pr^e^s^eⁿ^{t ty}^pe^s^of^c^onv^e^c^{tion i}ⁿ^aⁿ^uns^ta^ble^a^t^m^o^s^phe^r^e^{. T}^h^e^te^r^m^s^c^onv^e^c^{tion a}ⁿ^d^th^u^nde^r^s^tor^m^a^r^e^of^teⁿ
^us^e^dⁱⁿ^te^r^c^ha^ng^e^a^b^ly^{, a}^lthoug^{h t}^h^unde^r^s^t^o^r^m^s^a^r^e^only^one^f^o^r^m^of^c^onv^e^c^tion.^For^m^o^r^e^inf^o^r^m^a^{tion o}ⁿ
^m^e^te^or^olog^ic^a^l^te^r^m^inolog^y^,^s^e^e^http:^//w^w^w^.s^r^h^.noa^a^.^g^o^v^/^ou^n/^s^e^ve^r^e^w^x^/^g^los^s^a^r^y^.php.
⁵³^W^a^l^l^{ace an}^d^H^obbs^,^pp^{. 2}⁴⁴^-²⁴⁵^.
⁵⁴^T^h^e^W^e^a^t^he^r^W^o^r^l^{d 2}⁰¹⁰^P^r^oje^c^t^{, U}ⁿ^iv^e^r^s^ity^of^I^llinois^,^M^u^ltic^e^ll^C^l^us^te^r^St^or^m^s^{, a}^t^http://w^w^2010.^a^t^m^o^s^.^uiuc^.e^du/
^(G^h)/g^uide^s/m^t^r/^sv^r/^ty^pe^/^c^lstr/ho^m^e^.^rxm^l^.
⁵⁵^W^a^l^l^{ace an}^d^H^obbs^{, pp}^.²^45-²⁴⁸^.

torrential rain and/or large hail immediately north and east of the main updraft. Severe weather ⁵⁶
prefers to form near the main updraft, typically towards the rear of the storm. Most large and
violent tornadoes come from supercell storms.
Tornadoes—the most violent storms on Earth—can sometimes produce winds that exceed 300
mph. They are the destructive products of severe thunderstorms, and second only to flash
flooding as the cause for convective storm related fatalities.
Damages from violent tornadoes seem to be increasing, similar to the trend for other natural
hazards. According to some insurance industry analysts, losses of $1 billion or more from single ⁵⁷
tornado events are becoming more frequent. For example, the so-called Super Tuesday Tornado
Outbreak during February 5-6, 2008, in several southern states (including Arkansas, Mississippi, ⁵⁸
and Tennessee) caused approximately $850 million in insured losses. Insurance industry
analysts indicate that tornadoes, severe thunderstorms, and related weather events (such as
hailstorms, but not hurricanes or earthquakes) have caused nearly 57%, on average, of all insured ⁵⁹
losses in the United States in any given year since 1953.
Fatalities caused by tornadoes have declined significantly since the 1930s, generally because of
improved forecasting, warning systems, and increased public awareness of the tornado risk.
However, some researchers suggest that the decline is unlikely to continue and may have already ⁶⁰
stopped. These findings attribute the stalled decline to increasing vulnerability due to ⁶¹
demographic factors, rather than shortcomings in tornado forecasts and warnings. The results
would suggest that there are limits to the number of potential lives saved by improvements in
forecasting ability and warning systems, and that social, behavioral, and demographic factors may ⁶²
play an increasingly important role in tornado-related fatalities. Other stakeholders, however,
emphasize the need for increased investment in observations, computing power, research and ⁶³
weather modeling to improve the nation’s resilience to severe weather.

⁵⁶^NOAA^N^a^tioⁿ^a^{l Sev}^e^{re Sto}^r^m^s^L^a^b^o^r^ato^r^y^,^{at h}^ttp^://w^ww^.n^ssl.n^o^aa.g^o^v^/^p^r^im^er/tsto^rm^/^t^st_^b^a^sics.h^t^m^l.
⁵⁷^A^.^{M. Be}^s^t^Com^p^aⁿ^y^,^Inc^.^{, Tor}ⁿ^ado^L^o^s^s^e^s^Appr^o^a^c^h^Th^os^e^{of H}^u^r^rⁱ^c^ane^s^(O^ldwⁱ^c^k^{, N}^J^{: A}^.^{M. Be}^s^t^Com^p^aⁿ^y^,
²⁰⁰⁸⁾^,^p.^1.
⁵⁸^A^.^{M. B}^e^s^t^C^o^m^p^aⁿ^y^,^Iⁿ^c^{., p.}^{1 a}^{nd Ex}^hⁱ^bit^4.^A^c^c^o^r^d^ing^{to t}^h^e^r^e^por^t,^the^c^o^s^t^lie^s^t^th^un^de^r^s^tor^m^/w^ind/t^o^rⁿ^a^{do e}^v^eⁿ^t
^oc^c^u^r^r^e^{d be}^tw^e^eⁿ^Ma^y^{2 a}^{nd Ma}^y^{11, 20}^03,^a^f^f^e^c^ting^{18 s}^t^a^t^e^s^aⁿ^{d r}^e^s^u^lti^ngⁱⁿ^ov^e^r^$3^.2^bill^io^{n in}^ins^u^r^e^d^da^m^a^ge^s^.
⁵⁹^Ibid^{., p. 7.}
⁶⁰^W^a^lk^e^r^S.^A^s^hle^y^{, “}^S^pa^tia^{l a}^{nd T}^e^m^pora^l^Aⁿ^a^l^y^s^{is of}^T^o^rna^{do Fa}^t^a^litie^{s in t}^h^e^Unite^{d Sta}^t^e^s^{: 1}⁸⁸⁰^-²⁰^05,”^W^e^at^he^r
^and^For^e^c^a^s^tⁱⁿ^g^{, v}^o^l.²²^(D^e^c^e^m^b^e^r²⁰⁰⁷⁾^{, p}^.¹²¹⁶^.
⁶¹^Ibid^.
⁶²^S^ee,^f^o^{r exa}^m^p^l^e,^Denⁿⁱ^{s S}^.^Mⁱ^l^e^tⁱ^,^Disa^{sters b}^y^Design^{: A}^Rea^ssessmen^{t o}^f^Natu^{ral Ha}^za^r^d^{s in}^the^Uⁿ^ite^{d State}^s
⁽^W^a^s^hing^{ton, D}^C^{: J}^o^s^e^{ph H}^e^nr^y^P^r^e^s^s^,¹⁹⁹⁹⁾^,^p.²^26.
⁶³^Se^e^,^f^o^{r e}^x^a^m^ple^,^“^A^dv^ic^e^{to the}^Ne^w^A^d^mⁱ^nistra^{tion a}ⁿ^d^Co^ng^re^{ss: A}^c^{tions to Ma}^k^e^o^u^{r Na}^tio^{n Re}^silie^{nt t}^o^Se^v^e^re
^W^eat^h^e^{r an}^d^Clⁱ^m^at^{e Ch}^an^ge,^”^a^d^o^c^u^m^en^t^p^r^od^u^{ced b}^y^t^h^{e Un}ⁱ^v^ersi^t^y^Co^rp^o^r^atⁱ^o^{n f}^o^{r A}^t^m^o^sp^h^e^ri^{c Research}^an^d
^se^v^e^{n othe}^{r sta}^k^e^holde^r^org^a^niz^a^{tions; a}^t^htt^p^://w^ww^.uc^a^r^.e^du/td/.

Most tornado fatalities occur within housing structures, unlike fatalities from floods which occur
in vehicles. This indicates that people are more likely to seek shelter during tornadic events;
however, the risk of injury or death seems to depend on what type of housing stock in which they
choose to seek shelter. For example, one study indicated that manufactured houses, such as
mobile homes, are particularly vulnerable to tornadoes. Mobile home deaths accounted for an
average of 44% of all deaths caused by tornadoes between 1985 and 2005, and showed an ⁶⁴
increasing trend over the 20-year period. During the same time period, tornado-related deaths
within permanent homes fluctuated between 20% and 30%, and deaths in vehicles decreased to ⁶⁵
9.9% of all tornado-related deaths, on average. The study concluded that the high percentage of
mobile homes in the Southeast may be the key factor explaining why most tornado-related deaths
occur in lower Arkansas, Tennessee, and lower Mississippi River valleys.
Members of Congress have recognized the increased vulnerability of citizens living in ^th
manufactured housing to tornadoes. In the 110 Congress, the House passed H.R. 2787, CJ’s
Home Protection Act of 2007, on October 30, 2007. The bill would amend §604 of the National
Manufactured Housing Construction and Safety Standards Act of 2004 (42 U.S.C. 5403) to ⁶⁶
require that all manufactured homes be equipped with a NOAA Weather Radio. NOAA Weather
Radios would presumably give the residents of manufactured homes a better chance of receiving
tornado warnings and allow them to take precautionary measures. A companion bill, S. 2724, was
introduced in the Senate on March 6, 2008. The Senate did not act on the bill.
In 2003, the 108^th Congress passed the Tornado Shelters Act (P.L. 108-146), which amended the
Housing and Community Development Act of 1974 (42 U.S.C. 5305(a)) to authorize
communities to use Community Development Block Grant (CDBG) funds for construction of
tornado-safe shelters in manufactured home parks. The law was aimed at communities of at least

20 manufactured homes and which consist of predominately low and moderate income residents.

To be eligible, the community has to be located in a state that was struck by a tornado during the ⁶⁷
fiscal year when funds were made available or during the previous three fiscal years.
Since 1950, violent tornadoes were responsible for 67.5% of all tornado deaths in the United ⁶⁸
States, yet comprise only 2.1% of all tornadoes. The number of fatalities caused by less violent
tornadoes is also significant, and some studies suggest that the percentage of fatalities caused by ⁶⁹
less violent tornadoes has increased since the 1970s. (See the Appendix for an explanation of
how violent tornadoes and less destructive tornadoes are classified: the F-Scale and enhanced F-
scale.)

⁶⁴^A^s^hley⁽²⁰⁰⁷⁾^,^p.¹²²⁴^.
⁶⁵^Ibid^.
⁶⁶^NOAA^W^e^ath^e^{r Rad}ⁱ^o^b^r^o^a^d^cast^s^o^f^fⁱ^{cial NW}^S^w^a^rnⁱⁿ^gs,^watch^e^s^,^f^o^recasts,^an^d^o^t^h^e^{r h}^azardⁱⁿ^f^o^rmatioⁿ²⁴^h^o^u^r^s
^{a d}^a^y^,⁷^d^a^{ys a}^w^e^e^k^t^o^al^l⁵⁰^st^at^es,^ad^j^acen^t^co^ast^a^l^w^a^t^e^rs,^P^u^ert^o^Ri^co^,^t^h^{e U.}^S^.^Vⁱ^rgiⁿ^Isl^aⁿ^d^s^,^aⁿ^d^t^h^{e U.}^S^.^P^aci^fⁱ^c
^T^e^rritorie^s^{. Se}^e^http:^//^w^w^w^.nw^s^.n^oa^a^.^g^o^v^/^nw^r/.
⁶⁷^For^m^o^r^e^inf^o^r^m^a^{tion o}ⁿ^the^C^D^B^G^pr^og^r^a^m^,^s^e^e^C^R^S^R^e^por^{t R}^L³³³³⁰^,^Co^mm^uⁿⁱ^t^y^Devel^op^men^t^B^l^o^{ck Gra}ⁿ^t
^F^u^nd^{s i}ⁿ^Di^sa^st^{er R}^e^lⁱ^e^f^aⁿ^d^R^eco^very^{, by}^Eug^e^ne^B^o^y^d^a^{nd O}^s^c^a^r^R^.^G^onz^a^l^e^s^.
⁶⁸^A^s^hley⁽²⁰⁰⁷⁾^,^p.¹²¹⁷^.
⁶⁹^I^b^id^{., p. 12}^18.

Tornadoes have been reported on all continents except Antarctica; however, they occur most ⁷⁰
commonly in North America and particularly in the United States. They can occur in all 50
states but they form most commonly in three regions: (1) a swath of the Midwest extending from
the Texas Gulf Coastal Plain northward through eastern South Dakota (known as “Tornado
Alley”); (2) an area that extends across the Gulf Coastal Plain from south Texas eastward to
Florida (known as “Dixie Alley”); and (3) an area located in eastern Iowa, south-central Indiana,
western Pennsylvania, and central Arkansas (a smaller “tornado alley”). See Figure 1.
Tornadoes occur mostly during spring and summer, and usually occur during the late afternoon ⁷¹
and early evening. However, tornadoes can occur on any day of the year and at any hour. The
United States averages approximately 1,000 tornadoes per year—the highest average annual
number in the world. (The actual number of recorded tornadoes per year varies, depending on the
source of information.) The first part of 2008 was relatively active, with 1,390 confirmed ⁷²
tornadoes through July. Tornadoes also caused 123 deaths between January and September of

2008, the ninth highest total for the nine-month period since reliable record keeping began in ⁷³

1953.

A tornado is a narrow, violently rotating column of air that extends from the base of a
thunderstorm to the ground. Tornadoes develop from severe thunderstorms in warm, moist,
unstable air along and ahead of cold fronts. There are two types of tornadoes, those that come ⁷⁴
from a supercell thunderstorm and those that do not.
Tornadoes that form from supercell thunderstorms are the most common, usually the largest, and
the most dangerous. In supercell thunderstorms, a rotating updraft is essential to development of a
tornado. Rotation of the updraft can be caused by wind shear, which occurs when winds at two
different levels above the ground blow at different speeds or in different directions. An invisible
tube of air begins to rotate horizontally, and rising air within the thunderstorm tilts the rotating air
from horizontal to vertical, resulting in rotation that extends through much of the storm. Once the
updraft is rotating and being fed by warm, moist air flowing in from the ground level, a tornado
can form. The mechanisms that cause tornadoes to form from supercell storms are not known
precisely, and it is not currently possible to predict which supercell thunderstorms will produce
tornadoes and which will not. Based on observations, approximately 20% of supercell ⁷⁵
thunderstorms produce tornadoes.

⁷⁰^Na^tiona^l^Se^v^e^re^Storm^s^L^a^bora^t^ory^,^a^t^http://w^ww^.nssl.noa^a^.^g^o^v^/^prim^e^r^/^t^orna^d^o^/^t^or_f^a^q^.shtm^l^.
⁷¹^Na^tiona^l^Se^v^e^re^Storm^s^L^a^bora^t^ory^,^a^t^http://w^ww^.n^ssl.noa^a^.^g^o^v^/^prim^e^r^/^t^orna^d^o^/^t^or_c^lim^a^t^olog^y^.^htm^l^#.
⁷²^NOAA^{, Natio}ⁿ^a^{l Clim}^{atic Da}^t^a^Cen^t^{er (A}^sh^ev^{ille, NC), “Cli}^m^a^te^o^f²⁰⁰⁸^U.^{S. T}^o^rn^a^d^o^Ov^ervⁱ^ew^,^”^at
^h^t^t^p^:^/^/^www^.ⁿ^cd^c.ⁿ^o^aa.^go^v/^o^a^/^c^lⁱ^m^at^e/^research^/²⁰⁰⁸^/^t^o^rn^ado^e^s0^8.^h^t^m^l^.^Dat^a^{as o}^f^Oct^.¹⁰^,²⁰⁰⁸^.
⁷³^Ibⁱ^d^.^A^l^so^,^f^o^{r a l}ⁱ^s^t^o^f^d^ecl^ared^di^sast^{ers b}^ecau^{se o}^f^t^o^rn^ad^o^e^{s o}^r^r^e^l^a^t^e^d^w^e^at^h^e^{r even}^t^s^,^{see F}^E^M^A^,²⁰⁰⁸^F^e^d^e^ral
^Disa^ste^r^De^c^l^a^r^a^{tions, a}^t^http^://w^ww^.^f^e^m^a^.^g^o^v^/^ne^w^s^/^d^isa^s^te^rs.f^e^m^a^.
⁷⁴^NOAA^N^a^tioⁿ^a^{l S}^e^{vere S}^t^o^r^m^s^L^a^b^o^r^ato^r^y^,^“^A^S^e^v^e^re^W^eath^e^{r P}^r^im^{er: Qu}^estioⁿ^s^an^d^Aⁿ^sw^{ers ab}^o^u^t^T^o^rⁿ^ad^o^e^s,^”
^a^t^http^://w^ww^.nssl.noa^a^.^g^o^v^/^prim^e^r^/torna^d^o/^tor_^ba^sic^s^.htm^l.
⁷⁵^Ibid^.

Figure 1. Map Showing the Number of Recorded Tornadoes Greater than F3 in the
United States Between 1950 and 1998
^Source:^{Federal Emerg}^ency^Man^{agement Age}^{ncy (FEMA), at}^http:^{//www.fema.gov/}^plan/^prevent/^saf^eroom/
^tsfs0^{2_torn_activity.sht. Accordi}^{ng to FEMA, the}^{map is}^{based on}^{NOAA, Storm Prediction Center}^statistics.
A non-supercell tornado forms from a vertically spinning parcel of air near the ground, about 1-10
kilometers in diameter, that is caused by wind shear from a warm, cold, or sea breeze front, or
from a dryline—the interface between warm, moist air and hot, dry air. When an updraft moves
over the spinning parcel of air and stretches it, a tornado can form. This type of tornado formation
commonly occurs in eastern Colorado, where cool air descending from the Rocky Mountains ⁷⁶
toward the west collides with hot dry air from the Great Plains. Land-falling tropical storms and
hurricanes can also generate non-supercell tornadoes.
The NWS, at the discretion of the Secretary of Commerce, has statutory authority for weather
forecasting and for issuing storm warnings (15 U.S.C. §313). The NWS provides weather, water,
and climate forecasts and warnings for the United States, its territories, adjacent waters, and
ocean areas. The NWS employs 4,700 employees in 122 weather forecast offices, 13 river ⁷⁷
forecast centers, national centers, and other supporting agencies around the country.

⁷⁶^Ibid^.
⁷⁷^T^h^{e n}ⁱⁿ^e^cen^t^e^{rs o}^f^t^h^{e NW}^Sⁱⁿ^cl^u^d^e^t^h^{e A}^vⁱ^a^tⁱ^oⁿ^W^eat^h^e^{r Cen}^t^er,^Clⁱ^m^at^{e P}^r^edⁱ^c^tⁱ^oⁿ^Cen^t^er,^Eⁿ^vi^r^oⁿ^m^en^t^a^l
^M^o^d^e^lⁱⁿ^g^Cen^t^er,^Hy^d^r^o^m^et^eo^ro^l^o^gi^cal^P^r^edi^c^tⁱ^oⁿ^Cen^t^er,^Natⁱ^oⁿ^a^l^Cen^t^{er f}^o^{r E}ⁿ^vi^ron^m^en^t^a^l^P^r^o^t^ectⁱ^o^n,^Ocean
^P^r^e^dⁱ^c^tⁱ^oⁿ^Cen^t^er,^S^p^{ace W}^eat^h^e^r^P^r^edⁱ^c^tⁱ^oⁿ^Cent^er,^S^t^o^r^m^P^r^edⁱ^c^tⁱ^oⁿ^Cent^er,^and^T^r^o^pⁱ^cal^P^r^edi^c^tⁱ^oⁿ^Cen^t^er.^S^ee
^http:^//w^w^w^.nw^s^.noa^a^.^g^o^v^/^or^g^a^niz^a^tion.^ph^p.

Each of the 122 weather forecast offices is equipped with technologies for observing, forecasting, ⁷⁸
and warning of severe thunderstorms and tornadoes. These technologies include Weather
Surveillance Radar (WSR-88D, also known as NEXRAD, a network of 161 radars), Automated ⁷⁹
Surface Observing Systems (ASOS) at over 1,200 sites, access to data from two Geostationary
Operational Environmental Satellites (GOES 8 and 10), and the Automated Weather Interactive ⁸⁰
Processing System (AWIPS).
Severe thunderstorm and tornado forecasts are made by the Storm Prediction Center (SPC) and
local weather forecast offices. Forecasters at the SPC use numerical weather prediction models to
determine if atmospheric conditions, temperature, and wind flow patterns may lead to formation
of severe weather. The SPC uses its suite of products to relay forecasts of organized severe
weather as much as three days ahead of time, and continually refines the forecast up until the ⁸¹
event has concluded. The severe weather forecast process typically follows the following
pattern: (1) convective outlook; (2) mesoscale discussion; (3) watch; and (4) warning.
The severe weather forecast process typically begins with a forecast issued one to two days in
advance of where both severe and non-severe thunderstorms are expected to occur around the ⁸²
country. This is known as a convective outlook. Areas of possible severe thunderstorms are
labeled slight risk, moderate risk, or high risk, depending upon the coverage and intensity of
expected severe thunderstorms in a region. The outlooks are the first severe weather threat
notifications that the local NWS offices and local emergency officials receive.
As a convective outlook area becomes more defined, a next step in the forecast process is often ⁸³
needed to describe an evolving severe weather threat. This is known as a mesoscale discussion.
Mesoscale discussions contain information that helps forecasters at local NWS offices understand
the causes and prepare for the types of severe weather expected.

⁷⁸^Jo^sep^h^H.^G^o^l^d^en^and^C^h^ri^st^op^{her R.}^A^d^a^m^s,^“^T^h^e^T^o^rn^ad^o^P^r^o^b^l^e^m^:^F^o^recast^,^W^a^rnⁱⁿ^g,^an^d^Respoⁿ^s^e,^”^N^a^tu^r^a^l
^Ha^za^rd^{s Review}⁽^M^a^y²⁰⁰⁰⁾^{, p}^.¹^07.
⁷⁹^A^S^OSⁱ^s^{a cl}ⁱ^m^at^o^l^o^gⁱ^cal^o^b^s^erviⁿ^gⁿ^e^t^w^o^r^{k t}^h^at^gen^e^rat^e^s^w^eat^h^e^{r rep}^o^r^t^s^at^h^o^u^r^l^yⁱⁿ^t^e^rval^s,^exce^p^t^w^h^en^w^eat^h^e^r
^c^ondi^tio^ns^a^r^e^c^h^aⁿ^gⁱ^ng^r^a^pi^dly^.
⁸⁰^AW^IP^Sⁱ^s^aⁿⁱⁿ^t^e^ractⁱ^v^{e co}^m^p^u^t^{er syst}^e^m^t^h^atⁱⁿ^t^e^grat^es^m^e^t^e^o^r^o^l^ogi^cal^an^d^h^y^d^r^o^l^o^gⁱ^cal^d^a^t^a^f^r^o^m^an^arra^y^o^f
^meteo^r^o^l^o^g^{ical sen}^s^o^r^s—rad^a^{r, sa}^{tellites, su}^rf^{ace in}^stru^m^eⁿ^t^s—an^d^en^ab^{les th}^{e f}^o^{recaster to}^p^r^ep^are^an^d^issu^{e m}^o^re
^accu^rat^e^an^d^tⁱ^m^el^y^f^o^reca^st^{s an}^d^w^a^rnⁱⁿ^gs.
⁸¹^T^h^e^SP^C^suite^of^pro^duc^{ts i}ⁿ^c^l^ud^e^s^sa^te^llite^im^a^g^e^r^y^,^ra^da^{rs, surf}^a^c^e^we^a^t^he^{r sta}^{tions, w}^e^a^t^he^{r ba}^llo^oⁿ^so^un^ding^s,
^wⁱ^{nd prof}^ile^{rs, lig}^ht^ning^de^te^c^tio^{n ne}^tw^ork^,^a^nd^inf^o^rm^a^{tion f}^r^om^loc^a^l^NW^{S of}^fⁱ^c^e^s^{. Se}^e^http://w^ww^.spc^.noa^a^.^g^o^v^/
^mⁱ^sc^/^a^bo^utus^.^h^tm^l.
⁸²
^NO^AA^S^t^o^r^m^P^r^edⁱ^c^tⁱ^oⁿ^Ceⁿ^t^er,^t^h^{e S}^e^{vere S}^t^o^r^m^s^F^o^recast^P^r^o^ces^s:^Ou^t^l^o^o^k^t^o^M^e^so^scal^{e Di}^scu^ssi^oⁿ^t^o^W^a^t^c^h^t^o
^W^a^rning^,^a^t^htt^p^://w^ww^.spc^.noa^a^.^g^o^v^/^mⁱ^sc^/^a^bou^tus.^htm^l^.
⁸³^Ibid^.

If development of severe thunderstorms or tornadoes is imminent, or likely to occur in the next
several hours, the next step is a severe storm watch. Such watches alert the public, aviators, and
local NWS offices that environmental conditions have become favorable for the development of
severe storms or tornadoes. Following the issuance of a severe storm watch, local networks of ⁸⁴
storm spotters are activated, and forecasters in the threat area closely monitor radar imagery and ⁸⁵
spotter reports to issue the appropriate severe thunderstorm and tornado warnings.
As the severe weather threat continues to develop, the local NWS offices and the storm spotters
try to detect severe thunderstorms and tornadoes using radar or other detection technology and
visual evidence. When severe hail, damaging winds, or a tornado appears imminent from radar or
visual evidence, local NWS offices will issue a severe thunderstorm or tornado warning as
appropriate. The warning contains specific language about areas at risk, time frames, specific ⁸⁶
hazards, recommended protective behavior for those at risk, and the office issuing the warning.
Several methods exist to communicate alerts and warnings to the public. The NWS maintains and
operates NOAA Weather Radio (NWR). NWR is a nationwide network of radio stations
broadcasting continuous weather information directly from the nearest NWS office. The NWR
works with the Emergency Alert System (EAS). The EAS is an automated simultaneous
retransmission system that allows NWS warnings to be disseminated over most radio and ⁸⁷
television networks, and over cable and satellite TV systems. NOAA Weather Radio broadcasts
official NWS warnings, watches, forecasts, and other hazard information 24 hours a day, 7 days a
week, to all 50 states, adjacent coastal waters, Puerto Rico, the U.S. Virgin Islands, and the U.S. ⁸⁸
Pacific Territories.
Issuing severe weather warnings to the public has evolved into what some observers term a
weather warning partnership: a roughly triangular exchange of information between the NWS,
private forecasters and the news media, and local emergency managers. The objective of the ⁸⁹
weather warning partnership is to provide a consistent warning message to the public at risk.
The NWS depends on weather warning partnerships with the electronic news media and local and
state emergency management officials to ensure that communities are prepared for severe weather

⁸⁴^Sto^r^m^sp^o^{tters rep}^o^{rt critical w}^e^a^t^h^e^{r in}^f^o^rm^atioⁿⁱⁿ^real^tⁱ^m^{e t}^o^t^h^{e NW}^S^f^r^o^m^{a sp}^eci^fⁱ^{c l}^o^catⁱ^oⁿ^.
⁸⁵^NOAA^S^t^o^r^m^P^r^ed^icti^oⁿ^Cen^t^er,^th^{e S}^e^{vere S}^t^o^r^m^s^F^o^recas^{t P}^r^o^c^e^{ss: Ou}^tloo^k^to^M^e^so^{scale Discu}^ssioⁿ^to^W^a^tch^to
^W^a^rning^,^a^t^htt^p^://w^ww^.spc^.noa^a^.^g^o^v^/^mⁱ^sc^/^a^bou^tus.^htm^l^.
⁸⁶^Jo^sep^h^H.^G^o^l^d^en^and^C^h^ri^st^op^{her R.}^A^d^a^m^s,^“^T^h^e^T^o^rn^ad^o^P^r^o^b^l^e^m^:^F^o^recast^,^W^a^rnⁱⁿ^g,^an^d^Respoⁿ^s^e,^”^N^a^tu^r^a^l
^Ha^za^rd^{s Review}⁽^M^a^y²⁰⁰⁰⁾^{, p}^.¹^11-¹¹^2.
⁸⁷^EA^{S is}^a^d^mⁱ^nis^t^e^r^e^d^by^FEMA^{, i}ⁿ^c^o^o^p^e^r^a^tio^{n w}^{ith t}^h^e^Fe^de^r^a^{l C}^o^m^m^unic^a^{tion C}^o^m^m^is^sⁱ^{on a}^{nd N}^W^{S. For}^m^o^r^e
^inf^o^r^m^a^{tion on}^EA^{S, s}^e^e^C^R^S^R^e^por^{t R}^L³²⁵^27,^The^Em^e^r^ge^nc^y^Al^e^r^{t Sy}^s^t^e^m⁽^EAS)^an^{d All-}^H^a^z^a^r^d^W^a^rⁿ^ings^{, by}
^Lⁱ^nda^K^.^Mo^or^e^.
⁸⁸^NOAA^W^e^ath^e^{r Rad}ⁱ^o^,^at^h^t^t^p^://^www^.ⁿ^w^s^.ⁿ^o^aa.^go^v/ⁿ^w^r/.
⁸⁹^R^.^A^.^Ma^ddux^{, “}^T^he^W^e^a^t^he^r^W^a^rⁿ^ing^P^a^r^t^ne^r^s^hip^,^”^P^r^o^ceedⁱⁿ^g^s^f^r^o^m^t^h^{e Ha}^z^a^rd^{s R}^e^sea^r^ch^aⁿ^d^A^p^p^lⁱ^c^a^tⁱ^oⁿ^s
^Wo^rksh^o^p^,^Nat^u^ral^Hazard^s^Rese^arch^an^d^A^p^p^lⁱ^catⁱ^oⁿ^s^Iⁿ^f^o^rm^atⁱ^oⁿ^Cen^t^er,^Uⁿⁱ^v^ersi^t^y^o^f^Co^l^o^rado^,^Bo^u^l^d^e^{r (19}⁹¹⁾^.

outbreaks and to further communicate the outlooks, watches, and warnings to the public.⁹⁰ Many
emergency management officials and news media monitor NWS outlooks so that they have
enough lead time for activating preparedness capabilities such as storm spotters, increasing
response levels, and preparing to activate the warning communication systems. The partnership is
essential in guaranteeing that there is a shared understanding of the weather threats and that
accurate warning information is communicated to the public at risk. Observers have noted that
this shared understanding helps prevent conflicting warnings—which could lead to delays in ⁹¹
seeking shelter—from being communicated to the public.

Congress may consider several options for potentially reducing the costs of severe thunderstorms
and tornadoes: improving detection and warning systems; fostering efforts to build more resilient
buildings and infrastructure; and supporting research and development to better understand why
and where severe thunderstorms and tornadoes occur, as well as other measures. Whether and
how climate change is influencing or could affect the frequency and intensity of thunderstorms
and tornadoes is not yet evident. Thus it is not clear whether long-term efforts to mitigate
greenhouse gas-induced global warming—such as by reducing emissions of carbon dioxide and
other gases—will also mitigate damage to property and reduce injuries and losses of life from
severe thunderstorms and tornadoes.
Enhancing the scientific understanding of how and why severe thunderstorms and tornadoes
form, and improving the accuracy and timeliness of forecasting and warning systems, will likely
provide individuals and communities in the United States better information to help them avoid
damage and injury from severe weather events. The role of the federal government in weather and
climate research, thunderstorm and tornado forecasting, and issuing warnings is substantial.
Spending on weather forecasts and warnings comprises the bulk of the NWS budget, which is
itself the largest component of NOAA’s annual budget. Several other federal agencies contribute
to the weather and climate enterprise, including NSF, NASA, the U.S. Geological Survey, and
others. The federal investment in weather-related response and recovery, including programs at
the Department of Agriculture and FEMA, is also substantial.
How climate change will influence the frequency and severity of severe thunderstorms and
tornadoes across the United States is not clear. Many observers and stakeholders call for
increased funding for improving the understanding of physical processes that produce extreme
events, such as severe thunderstorms and tornadoes, and how these processes change with ⁹²
climate. Observers and stakeholders are broadly in agreement about the types of R&D needed,
such as integrated data and observation systems, improved remote sensing capabilities, better ⁹³
modeling capability, and others.

⁹⁰^G^o^ldeⁿ^aⁿ^d^A^d^am^s⁽²⁰⁰⁰⁾^{, p}^.¹¹²^.
⁹¹^Ibid^.
⁹²^C^C^S^P^,^W^e^a^t^he^r^a^{nd C}^lim^a^t^e^Ex^t^r^em^e^s^{in a}^C^h^aⁿ^gⁱ^ng^C^lim^a^t^e⁽²⁰⁰⁸⁾^,^p.¹^22.^Se^e^,^f^o^r^e^x^am^ple^,^“A^dv^ic^e^{to the}^N^e^w
^A^d^mⁱ^nistra^{tion a}ⁿ^{d Co}^ng^re^{ss: A}^c^tions^to^Ma^k^e^{our Na}^tio^{n Re}^silieⁿ^t^to^Se^v^e^re^We^a^t^he^{r a}^{nd Clim}^a^t^e^Chaⁿ^g^e^,”^a
^doc^um^eⁿ^{t pr}^o^duc^e^d^by^the^Uⁿ^iv^e^r^s^ity^C^o^r^por^a^tion^f^o^r^A^t^m^o^s^phe^rⁱ^c^R^e^s^e^a^r^c^h^a^{nd s}^e^v^e^{n othe}^r^s^t^a^k^e^hol^de^r
^org^a^niz^a^tions^{; a}^t^htt^p^://w^w^w^.uc^a^r^.e^du/^td/^.^T^h^e^org^a^niz^a^tions^c^a^{ll f}^o^{r $9}^bill^io^{n i}ⁿ^f^undi^ng^f^o^{r w}^e^a^t^{her a}^{nd c}^lim^a^t^e^-
^re^la^te^{d f}^e^de^ra^{l e}^x^pe^nditure^s^{in ad}^ditioⁿ^t^o^c^u^r^r^e^ntly^e^s^ti^m^a^te^{d s}^p^e^nding^ov^e^r^t^h^e^ne^x^t^fⁱ^v^e^y^e^a^r^s^.
⁹³^G^r^a^{nd C}^h^a^lle^ng^e^s^f^o^r^Dⁱ^s^a^s^t^e^r^R^e^duc^tio^{n (}²⁰⁰⁵⁾^,^p.¹⁴^.

Even if funding increased substantially, however, it may not necessarily lead to significant
decreases in damages, injuries, or deaths from severe thunderstorms and tornadoes. Shifting
populations, changes in wealth density, and construction of dense infrastructure in areas prone to
severe weather could offset improvements in forecasting and warning systems:
^...th^e^poten^tial^f^o^{r cons}^{iderable los}^s^o^f^li^f^e^aⁿ^d^property^d^u^{e t}^o^torn^adoes^con^tinu^e^s^{to e}^x^is^t,
^e^s^p^e^cⁱ^a^l^l^yⁱⁿ^hi^gh^l^y^vul^ne^r^a^b^l^e^r^e^gi^oⁿ^{s o}^f^t^h^e^c^o^uⁿ^t^r^y^.^F^u^r^t^he^r^,^t^h^eⁱⁿ^creasⁱⁿ^g^popu^l^a^tⁱ^oⁿ^aⁿ^d
^mⁱ^g^r^atⁱ^oⁿ^pat^t^e^rn^s^o^f^t^hⁱ^s^popu^l^a^tⁱ^oⁿ^su^gg^es^t^t^h^at^t^h^e^o^v^e^r^a^l^l^v^u^lⁿ^e^r^a^bⁱ^lⁱ^t^y^aⁿ^d^rⁱ^s^k^t^o^h^u^m^aⁿ^s
^an^{d th}^{eir property}^m^a^y^a^m^pli^f^{y in}^th^{e fu}^t^u^{re des}^p^{ite i}^m^prov^e^m^en^tsⁱⁿ^f^o^recas^ti^ng^{, detec}^tⁱ^oⁿ^,⁹⁴
^an^d^w^a^rⁿⁱⁿ^g^dⁱ^s^s^e^mⁱⁿ^a^tioⁿ^.⁽^R^ef^er^en^ce^{s o}^m^itted^.⁾
In fact, implementing hazard mitigation strategies may include developing and enforcing land-use
planning and zoning laws, which are traditionally state and local issues and not Congressional ⁹⁵
concerns per se. Disseminating results of federally sponsored R&D, from activities such as
those authorized in the National Windstorm Impact Reduction Program, to states and local
communities may be more squarely in the Congressional purview, and more directly addressed
through oversight of the programs and annual appropriations for the participating agencies.

⁹⁴^A^s^hley⁽²⁰⁰⁷⁾^,^p.¹²²⁶^.
⁹⁵^{See, f}^o^{r ex}^a^m^p^l^{e, G}^r^an^d^Ch^allen^g^e^#³^—^d^e^v^e^lo^p^h^azard^m^itig^atioⁿ^strategⁱ^{es an}^d^tec^hnol^og^ie^s^;^oⁿ^e^of^sⁱ^x^g^r^a^nd
^c^h^a^lle^ng^e^s^de^v^e^lope^{d by}^the^N^a^tiona^{l Sc}^ie^nc^e^aⁿ^{d T}^e^c^hnol^og^y^C^ounc^il,^G^r^a^{nd C}^h^a^lle^ng^e^s^f^o^r^Dⁱ^s^a^ste^r^R^e^duc^tioⁿ
⁽²⁰⁰⁵⁾^.^A^r^g^u^a^b^l^y^{, the}^N^a^tiona^l^Fl^ood^Iⁿ^s^u^r^a^nc^e^P^r^og^r^a^m⁽^N^FI^P⁾^—^a^dm^inis^te^r^e^{d by}^FEMA^—ⁱ^s^aⁿ^e^x^am^ple^of^f^e^de^r^a^l
^inv^o^lv^e^m^eⁿ^{t in l}^o^c^a^l^c^o^m^m^unity^de^v^e^lopm^eⁿ^{t. T}^h^e^NFIP^m^a^k^e^s^f^l^ood^ins^u^ra^nc^e^a^v^a^ila^ble^{to c}^o^m^m^unitie^{s t}^h^a^t^a^g^re^e^to
^a^dopt^aⁿ^d^eⁿ^f^o^r^c^e^f^l^oodplaⁱ^{n m}^a^na^g^e^m^e^{nt or}^di^na^nc^e^s^{. F}^o^r^m^o^r^e^inf^o^r^m^a^{tion on}^the^N^F^I^P^{, s}^e^e^C^R^S^R^e^por^{t R}^L³⁴⁶¹^0,
^Mⁱ^dw^e^s^{t Floo}^di^{ng D}ⁱ^s^a^s^t^e^r^:^Re^thiⁿ^kⁱ^ng^Fe^de^r^a^l^Flo^o^d^Iⁿ^s^u^r^anc^e^?^,^b^y^Ra^w^l^{e O.}^Kin^g^.

The Fujita, or F-scale, was developed to provide a method for estimating the intensity of ⁹⁶
tornadoes, and was intended to relate the degree of damage to the intensity of wind. The original
F-scale was used for over three decades, but its limitations prompted the development of a new
scale, called the enhanced F-scale, or EF-scale. The EF-scale is intended to be a more robust and
precise method of assessing tornado damage than the original F-scale. The EF-scale calibrates
tornado damage by using 28 different types of damage indicators, such as the type of construction
(e.g., anchored versus unanchored houses, mobile homes, schools, garages, barns, skyscrapers, ⁹⁷
transmission towers, and others). Even with the improvements over the original F-scale, the EF-
scale only represents estimates of wind speed, based on damage, and not measurements of actual ⁹⁸
wind speeds in tornadoes. Actual tornado wind speeds are still largely unknown. Table A-1
compares the original F-scale and the EF-scale which is currently used by meteorologists and
wind engineers.
Table A-1. F-Scale and Enhanced F-Scale for Tornado Damage
^{Original F-scale}^{Wind Speed (mph)}^Enhan^{ced F-scale}^{Wind Speed (mph)}
^{F-0 45-7}⁸^EF-0^65-8⁵
^{F-1 79-1}¹⁷^EF-1^86-1¹⁰
^{F-2 118-}¹⁶¹^EF-2^111-¹³⁵
^{F-3 162-}²⁰⁹^EF-3^136-¹⁶⁵
^{F-4 210-}²⁶¹^EF-4^166-²⁰⁰
^{F-5 262-}³¹⁷^EF-5^Over²⁰⁰
^Source:^NOAA^{Storm Predictio}^{n Cente}^{r, at http://www.spc.noaa}^.gov/^faq/^{tornado/ef-scale.html.}
^P^e^ter^Fo^lg^er ^Aⁱ^s^h^{a C}^.^R^eed
^Sp^{ecialist i}ⁿ^En^er^g^y^aⁿ^d^Natu^r^a^{l Reso}^u^r^{ces P}^o^lic^y^An^al^y^s^{t i}ⁿ^Nat^u^r^a^{l Reso}^u^r^ces^P^o^licy
^pf^ol^g^e^r@^cr^s^.^l^o^c.g^o^v^,^7-¹⁵¹⁷^areed@^c^rs^.l^oc.g^ov^{, 7-}¹⁷⁵⁴

⁹⁶^D^r^{. T}^e^{d Fuji}^ta^de^v^e^lope^d^the^s^c^a^l^e^{in 1}⁹⁷¹^.
⁹⁷^NOAA^Sto^r^m^P^r^ed^icti^oⁿ^Cen^t^er,^{at h}^ttp^://w^ww^.^s^p^c^.n^o^aa.g^o^v^/^f^a^q^/to^rn^ad^o^/ⁱⁿ^d^e^x^.^h^t^m^l^#^f^-sc^a^le3^.
⁹⁸^NOAA^Sto^r^m^P^r^ed^icti^oⁿ^Cen^t^er,^{at h}^ttp^://w^ww^.^s^p^c^.n^o^aa.g^o^v^/^f^a^q^/to^rn^ad^o^/^ef^-sc^a^le.h^tm^l.