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Microburst


Illustration of a microburst. Note the downward motion of the air until
it hits ground level. It then spreads outward in all directions. The
wind regime in a microburst is opposite to that of a tornado.


Tree damage from a downburst

A *microburst* is a very localized column of sinking air, producing
damaging divergent and straight-line winds at the surface that are similar
to but distinguishable from tornadoes which generally have convergent
damage. There are two types of microbursts: wet microbursts and dry
microbursts. They go through three stages in their life cycle: the
downburst, outburst, and cushion stages. The scale and suddenness of a
microburst makes it a great danger to aircraft due to the low-level wind
shear caused by its gust front , with several fatal crashes having been
attributed to the phenomenon over the past several decades.

A microburst often has high winds that can knock over fully grown trees.
They usually last for a couple of seconds.


Contents

[hide ]

* 1 History of term 
o 1.1 Dry microbursts 
o 1.2 Wet microbursts 
* 2 Development stages of microbursts

* 3 Physical processes of dry and wet microbursts

o 3.1 Simple explanation 
o 3.2 Basic physical processes using simplified buoyancy
equations

o 3.3 Negative vertical motion associated only with buoyancy

* 4 Danger to aircraft 
* 5 Danger to buildings 
* 6 See also 
* 7 References 
o 7.1 Notes 
o 7.2 Printed media 
* 8 External links 


[edit ] History of term

The term was defined by senior weather expert Tetsuya Theodore Fujita as
affecting an area 4 km (2.5 mi) in diameter or less, distinguishing them
as a type of *downburst * and apart from common wind shear which can
encompass greater areas.^[1] Fujita also coined the term *macroburst* for
downbursts larger than 4 km (2.5 mi), a scale of size known as the
mesoscale.^[2]

A distinction can be made between a *wet microburst* which consists of
precipitation and a *dry microburst* which consists of virga .^[3] They
generally are formed by precipitation-cooled air rushing to the surface,
but they perhaps also could be powered from the high speed winds of the
jet stream deflected to the surface in a thunderstorm (see downburst ).

Microbursts are recognized as capable of generating wind speeds higher
than 75 m/s (168 mph; 270 km/h).



Dry microburst schematic from NWS


[edit ] Dry microbursts

When rain falls below cloud base or is mixed with dry air, it begins to
evaporate and this evaporation process cools the air. The cool air
descends and accelerates as it approaches the ground. When the cool air
approaches the ground, it spreads out in all directions and this
divergence of the wind is the signature of the microburst. High winds
spread out in this type of pattern showing little or no curvature are
known as straight-line winds.^[4]

Dry *microbursts*, produced by high based thunderstorms that generate
little surface rainfall, occur in environments characterized by a
thermodynamic profile exhibiting an inverted-V at thermal and moisture
profile, as viewed on a Skew-T log-P thermodynamic diagram. (Wakimoto,
1985) developed a conceptual model (over the High Plains of the United
States ) of a dry microburst environment that comprised three important
variables: mid-level moisture, a deep and dry adiabatic lapse rate in the
sub-cloud layer, and low surface relative humidity.



Wet microburst schematic from NWS


[edit ] Wet microbursts

Wet microbursts are downbursts accompanied by significant precipitation at
the surface which are warmer than their environment (Wakimoto, 1998).^[5]
These downbursts rely more on the drag of precipitation for downward
acceleration of parcels than negative buoyancy which tend to drive "dry"
microbursts. As a result, higher mixing ratios are necessary for these
downbursts to form (hence the name "wet" microbursts). Melting of ice,
particularly hail, appears to play an important role in downburst
formation (Wakimoto and Bringi, 1988), especially in the lowest one
kilometer above ground level (Proctor, 1989). These factors, among others,
make forecasting wet microbursts a difficult task.

*Characteristic* *Dry Microburst* *Wet Microburst* *Location of Highest
Probability within the United States* Midwest/West Southeast
*Precipitation* Little or none Moderate or heavy *Cloud Bases* As high as
500 mb Usually below 850 mb *Features below Cloud Base* Virga Shafts of
strong precipitation reaching the ground *Primary Catalyst* Evaporative
cooling Downward transport of higher momentum *Environment below Cloud
Base* Deep dry layer/low relative humidity/dry adiabatic lapse rate
Shallow dry layer/high relative humidity/moist adiabatic lapse rate
*Surface Outflow Pattern* Omni-directional Gusts of the direction of the
mid-level wind


[edit ] Development stages of microbursts

The evolution of downbursts is broken down into three stages: the contact
stage, the outburst stage and the cushion stage.



A downburst initially develops as the downdraft begins its descent from
cloud base. The downdraft accelerates and within minutes, reaches the
ground (contact stage). It is during the contact stage that the highest
winds are observed.

	


During the outburst stage, the wind "curls" as the cold air of the
downburst moves away from the point of impact with the ground.

	


During the cushion stage, winds about the curl continue to accelerate,
while the winds at the surface slow due to friction.^[6]


[edit ] Physical processes of dry and wet microbursts

	This article *needs attention from an expert on the subject*. See
the talk page for details. WikiProject Meteorology may be able to help
recruit an expert. /(February 2009)/

Microburstcrosssection.JPG


[edit ]
Simple explanation

In the case of a wet microburst, the atmosphere is warm and humid in the
lower levels and dry aloft. As a result, when thunderstorms develop, heavy
rain is produced but some of the rain evaporates in the drier air aloft.
As a result the air aloft is cooled thereby causing it to sink and spread
out rapidly as it hits the ground. The result can be both strong damaging
winds and heavy rainfall occurring in the same area. Wet downbursts can be
identified visually by such features as a shelf cloud, while on radar they
sometimes produce bow echoes. One of the most devastating microburst
occurred in Lewisville,Tx. In the case of a dry microburst, the atmosphere
is warm but dry in the lower levels and moist aloft. Thus when showers and
thunderstorms develop, most of the rain evaporates before reaching the
ground.^[7]


[edit ] Basic physical processes using simplified buoyancy equations

Start by using the vertical momentum equation

{dw\over dt} = -{1\over\rho} {\partial p\over\partial z}-g

By decomposing the variables into a basic state and a perturbation,
defining the basic states, and using the Ideal Gas Law (/p/ = ρ/R//T/_/v/
), then the equation can be written in the form

B \equiv -{\rho^\prime\over\bar\rho}g = g{T^\prime_v - \bar T_v \over \bar
T_v}

where B is used to denote buoyancy. Note that the virtual temperature
correction usually is rather small and to a good approximation, it can be
ignored when computing buoyancy. Finally, the effects of precipitation
loading on the vertical motion are parameterized by including a term that
decreases buoyancy as the liquid water mixing ratio (\ell) increases,
leading to the final form of the parcel's momentum equation:

{dw^\prime\over dt} = {1\over\bar\rho}{\partial p^\prime\over\partial z} +
B - g\ell

The first term is the effect of perturbation pressure gradients on
vertical motion. In some storms this term has a large effect on updrafts
(Rotunno and Klemp, 1982) but there is not much reason to believe it has
much of an impact on downdrafts (at least to a first approximation) and
therefore will be ignored.

The second term is the effect of buoyancy on vertical motion. Cleary, in
the case of microbursts, one expects to find that B is negative meaning
the parcel is cooler than its environment. This cooling typically takes
place as a result of phase changes (evaporation, melting, and
sublimation). Precipitation particles that are small, but are in great
quantity, promote a maximum contribution to cooling and, hence, to
creation of negative buoyancy. The major contribution to this process is
from evaporation.

The last term is the effect of water loading. Whereas evaporation is
promoted by large numbers of small droplets, it only takes a few large
drops to contribute substantially to the downward acceleration of air
parcels. This term is associated with storms having high precipitation
rates. Comparing the effects of water loading to those associated with
buoyance, if a parcel has a liguid water mixing ration of 1.0 gkg^−1 ,
this is roughly equivalent to about 0.3 K of negative buoyancy; the latter
is a large (but not extreme) value. Therefore, in general terms, negative
buoyancy is typically the major contributor to downdrafts.^[7]



[edit ] Negative vertical motion associated only with buoyancy

Using pure "parcel theory" results in a prediction of the maximum
downdraft of

-w_{\rm max} = \sqrt{2\times\hbox{NAPE}}

where NAPE is the Negative Available Potential Energy,

\hbox{NAPE} = -\int_{\rm SFC}^{\rm LFS} B\,dz

and where LFS denotes the Level of Free Sink for a descending parcel and
SFC denotes the surface. This means that the maximum downward motion is
associated with the integrated negative buoyancy. Even a relatively modest
negative buoyancy can result in a substantial downdraft if it is
maintained over a relatively large depth. A downward speed of 25 m/s
results from the relatively modest NAPE value of 312.5 m²s^−2 . To a
first approximation, the maximum gust is roughly equal to the maximum
downdraft speed.^[7]



A photograph of the surface curl soon after a microburst impacted the
surface


[edit ] Danger to aircraft

Further information: Downburst and Wind shear


The scale and suddenness of a microburst makes it a great danger to
aircraft, particularly those at low altitude which are taking off and
landing. The following are some fatal crashes and/or aircraft incidents
that have been attributed to microbursts in the vicinity of airports:

* A MALÉV Ilyushin Il-18 (HA-MOC), Copenhagen Airport – 28 August 1971.
* Eastern Air Lines Flight 66 , John F. Kennedy International Airport –
June 24, 1975^[8]

* Pan Am Flight 759 , New Orleans International Airport – July 9,
1982^[8] * Delta Air Lines Flight 191 , Dallas-Fort Worth International
Airport – August 2, 1985^[8] * Martinair Flight 495 , Faro Airport –
December 21, 1992^[9] * USAir Flight 1016 , Charlotte/Douglas
International Airport – July 2, 1994 * Goodyear Blimp (Stars and
Stripes) , Coral Springs, Florida – June 16, 2005

A microburst often causes aircraft to crash when they are attempting to
land (the above mentioned Pan Am flight is a notable exception). The
microburst is an extremely powerful gust of air that, once hitting the
ground, spreads in all directions. As the aircraft is coming in to land,
the pilots try to slow the plane to an appropriate speed. When the
microburst hits, the pilots will see a large spike in their airspeed,
caused by the force of the headwind created by the microburst. A pilot
inexperienced with microbursts would try to decrease the speed. The plane
would then travel through the microburst, and fly into the tailwind,
causing a sudden decrease in the amount of air flowing across the wings.
The decrease in airflow over the wings of the aircraft causes a drop in
the amount of lift produced. This decrease in lift combined with a strong
downward flow of air can cause the thrust required to remain at altitude
to exceed what is available.^[8]


[edit ] Danger to buildings

* On May 4, 2010, the University of Massachusetts at Amherst was hit by a
microburst, causing destruction of trees and buildings. Preliminary
estimates put the cost of repairs at over $100,000.

* On May 2, 2009, the lightweight steel and mesh building in Irving ,
Texas used for practice by the Dallas Cowboys football team was flattened
by a microburst, according to the National Weather Service.^[10]

* On March 12, 2006, a microburst hit Lawrence , Kansas . 60 percent of
the University of Kansas campus buildings sustained some form of damage
from the storm. Preliminary estimates put the cost of repairs at between
$6 million and $7 million.^[11]




Strong microburst winds flip a several-ton shipping container up the side
of a hill, Vaughan Ontario, Canada