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Thunderstorms

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Title: Thunderstorms


1
Thunderstorms
2
Stages of Development of Thunderstorms
  • Most thunderstorms typically go through three
    stages of development
  • cumulus stage
  • mature stage
  • dissipating stage

3
Cumulus Stage
  • (1) Cumulus stage warm, humid air rises, cools,
    becomes saturated and water vapor condenses to
    form a cumulus cloud. If the air is unstable,
    then the cloud continues to grow vertically.
    During this stage most of the air is rising, but
    there is no lightning or thunder.

4
Cumulus Stage (Cont.)
5
Mature Thunderstorm Stage
  • As the cloud grows the formation of ice crystals
    brings about the development of precipitation.
  • When the precipitation begins falling toward the
    surface, frictional drag between the drops and
    ice crystals starts pulling air downwards
    creating downdrafts.

6
Mature Thunderstorm Stage (Cont.)
  • Regions of updrafts and downdrafts are found in
    the mature thunderstorm.
  • The existence of both updrafts and downdrafts can
    create significant turbulence in a mature
    thunderstorm.

7
Mature Thunderstorm Stage (Cont.)
  • The downdrafts may draw some drier, environmental
    air into the cloud in a process called
    entrainment.
  • Entrainment leads to the evaporation of water,
    which causes the air to cool and enhances the
    downdrafts.

8
The Gust Front
  • When the downdrafts reach the surface, the air
    flows out horizontally beneath the thunderstorm.
  • This produces an area of strong winds called the
    gust front that spreads out ahead of the
    thunderstorm.

9
The Gust Front (Cont.)
  • As the gust front passes a location, the wind
    speed increases, the temperature decreases, and
    the pressure increases slightly.

10
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11
The Roll Cloud
  • Along the gust front, warm, moist air may be
    forced upwards and produce a roll cloud.

12
The Mature Stage (Cont.)
  • Lightning and thunder occur during the mature
    stage.
  • The heaviest rain occurs during the mature stage
    and hail may occur.

13
Mature Stage (Cont.)
anvil
Drier environmental air is entrained into the
thunderstorm enhancing downdrafts
Roll Cloud
Gust Front
Heavy Rain
14
The Dissipating Stage
  • Eventually the downdrafts spread throughout the
    thunderstorm.
  • In the case of a slow-moving thunderstorm the
    sinking air cuts off the supply of warm, moist
    air and the thunderstorm begins to dissipate.

15
The Dissipating Stage (Cont.)
  • The dissipating stage is characterized by weak
    downdrafts throughout the thunderstorm, and light
    rain
  • Lightning and thunder may continue to occur
    during the dissipating stage of a thunderstorm.

16
The Dissipating Stage (Cont.)
Weak downdrafts occur throughout the dissipating
thunderstorm
Light Rain
17
Types of Thunderstorms
  • There are three basic types of thunderstorms
  • air mass
  • multicell
  • supercell

18
Air Mass Thunderstorms
  • Air mass thunderstorms develop individually in
    warm, moist maritime tropical air masses.
  • During a sunny day absorption of solar radiation
    increases the surface temperature to the
    Convective Temperature and the air parcels become
    unstable.

19
Air Mass Thunderstorms (Cont.)
  • The unstable air starts to rise and the
    thunderstorms progress from the cumulus stage,
    through the mature stage to the dissipating stage
    within an hour or so.
  • Air mass thunderstorms form when the winds are
    light and move little. Eventually the downdrafts
    cut off the supply of warm moist air and the
    thunderstorm dissipates.

20
Multicell Thunderstorms
  • At times the gust front (also sometimes called an
    outflow boundary) from one thunderstorm will
    generate enough rising motion to produce a new
    thunderstorm cell right next to the original
    thunderstorm.

21
Multicell Thunderstorms (Cont.)
  • Thus, it is possible to have multiple
    thunderstorms at different stages of development
    next to each other.
  • The identifiable group of thunderstorms is called
    a multicell thunderstorm.

22
Multicell Thunderstorm (Cont.)
New Thunderstorm Cell at the Cumulus Stage
Gust Front
Mature Thunderstorm Cell
23
Squall Lines
  • At times, depending on the larger scale wind
    conditions, the gust fronts (or outflow
    boundaries) merge and produce lines of
    thunderstorms called squall lines.

24
Squall Lines (Cont.)
N
Gust Fronts Merge
Separate Multicell Thunderstorms
E
Creating a linear squall line with embedded cores
of heavier precipitation.
25
Supercell Thunderstorms
  • Supercell thunderstorms are very large
    thunderstorms whose updrafts and downdrafts
    maintain the storm for hours.
  • Supercell thunderstorms may also contain a
    rotating updraft.

26
Supercell Thunderstorms (Cont.)
  • Their structure, large size and long duration
    mean that supercell thunderstorms are capable of
    producing flooding rainfall, damaging surface
    winds, large hail and large tornadoes.

27
Supercell Thunderstorms (Cont.)
  • Supercell thunderstorms are sometimes classified
    according to how much precipitation they produce.
  • (1) High Precipitation (HP) Supercell or
  • (2) Low Precipitation (LP) Supercell

28
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29
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30
The Dry Line
  • The dry line is the name given to the boundary
    that separates hot, dry continental tropical air
    from warm, moist maritime tropical air.
  • Since the hot dry air is more dense than the warm
    moist air the dry line is sometimes capable of
    producing enough lift to generate supercell
    thunderstorms.

31
Mesoscale Convective Complexes (MCCs)
  • Separate multicell and/or supercell thunderstorms
    sometimes produce gust fronts or that produce
    large squall lines.
  • The upper level outflows (i.e. the anvils) at the
    tops of the thunderstorms can merge on satellite
    images making it look like one mass of
    thunderstorms covering over 100,000 square
    kilometers.

32
Mesoscale Convective Complexes (MCCs) (Cont.)
  • These larger features are called Mesoscale
    Convective Complexes (MCCs).
  • MCCs can last for 12-18 hours, may produce very
    heavy rainfall over large areas and can generate
    a number of tornadoes.

33
Lightning and Thunder
  • Lightning is produced by a discharge of
    electricity that can heat the air to a
    temperature of 30,000C.
  • The nearly instantaneous increase of temperature
    by 30,000C causes the air to expand very rapidly
    and creates a shock wave that we hear as thunder.

34
Distance of Lightning Strokes
  • The visible radiation we see as a lightning
    stroke travels at the speed of light and we see
    it almost immediately.
  • Thunder travels at the speed of sound (about 330
    m s-1).

35
Distance of Lightning Strokes (Cont.)
  • If you count the number of seconds between the
    lightning stroke and the arrival of the thunder,
    you can determine how far away the lightning
    stroke occurred.

36
Distance of Lightning Strokes (Cont.)
  • For example, suppose 10 seconds elapse between
    the time you see a flash of lightning and hear
    the thunder.
  • 10 s x 330 m s-1 3300 m
  • The lightning stroke was approximately
  • 3300 m (about 2 miles) away.

37
Generation of Lightning
  • Clouds tend to develop a positive charge in the
    upper portion of the cloud.
  • Clouds tend to develop a negative charge in the
    lower portion of the cloud.
  • The surface of the Earth and objects on the
    surface tend to be positively charged.

38
Positive Charge in the Upper Portion of the Cloud


- - - - - - - - - -
Negative Charge in the Lower Portion of the Cloud




Positive Charge at the Surface and on Objects on
the Surface
39
Generation of Lightning (Cont.)
  • When the electrical field grows strong enough a
    current begins to flow from the cloud toward the
    surface.
  • The current flows in steps of 50-100 meters.
  • This current is called a stepped leader and it is
    nearly invisible to the human eye.

40
Positive Charge in the Upper Portion of the Cloud


- - - - - - - - - -
Negative Charge in the Lower Portion of the Cloud
A stepped leader starts to flow down from the
cloud.




Positive Charge at the Surface and on Objects on
the Surface
41
Generation of Lightning (Cont.)
  • As the end of the stepped leader approaches the
    ground, a current of positively charged particles
    starts upward from the surface.

42
Positive Charge in the Upper Portion of the Cloud


- - - - - - - - - -
Negative Charge in the Lower Portion of the Cloud
A stepped leader starts to flow down from the
cloud.
A current of positively charged particles starts
upward




Positive Charge at the Surface and on Objects on
the Surface
43
Generation of Lightning (Cont.)
  • When the two currents meet, a large number of
    electrons flow to the ground and a much larger
    visible return stroke moves upward into the cloud.

44
Positive Charge in the Upper Portion of the Cloud


- - - - - - - - - -
Negative Charge in the Lower Portion of the Cloud
A large number of electrons flow to the ground
A current of positively charged particles starts
upward




Positive Charge at the Surface and on Objects on
the Surface
45
Positive Charge in the Upper Portion of the Cloud


- - - - - - - - - -
Negative Charge in the Lower Portion of the Cloud
A large number of electrons flow to the ground
A visible return stroke moves upward into the
cloud




Positive Charge at the Surface and on Objects on
the Surface
46
Generation of Lightning (Cont.)
  • Typically this process repeats itself several
    times to create the lightning flash we see.
  • The subsequent leaders coming back down from the
    cloud are called dart leaders.

47
Positive Charge in the Upper Portion of the Cloud


- - - - - - - - - -
Negative Charge in the Lower Portion of the Cloud
The subsequent leaders coming down are called
dart leaders




Positive Charge at the Surface and on Objects on
the Surface
48
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49
Thunderstorm Days in the U.S.
  • Thunderstorms are most common over Florida and
    the region around the Gulf of Mexico.
  • Central Ohio averages about 40 days with
    thunderstorms each year.

50
Hail
  • Hail forms in the strongest updrafts of
    thunderstorms.
  • Drops of liquid water collide with the original
    ice pellet (also called a hail embryo).
  • The liquid water freezes on the ice pellet and
    the hailstone grows by accretion.

51
Hail (Cont.)
  • When the hailstone grows too large for the
    updraft to support it against the pull of the
    gravitational force, then it falls to the
    surface.

52
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53
Hail Occurrence in the U.S.
  • Hail is most common over eastern Wyoming, eastern
    Colorado, western Nebraska and western Kansas
    which experience 6-10 days a year with hail.
  • On average over central Ohio we see about 1-3
    days per year with hail.

54
Tornado
  • A tornado is a strong, small rapidly rotating low
    pressure system that extends beneath a
    thunderstorm to the ground.
  • The exact processes that lead to the formation of
    a tornado are still not fully understood.

55
Tornado (Cont.)
  • Some process thought to be related to the change
    of wind direction with height (i.e. directional
    shear) causes a part of the thunderstorm to begin
    to rotate.
  • This initial rotation is called a mesocyclone.

56
Tornado (Cont.)
  • If the rotation extends beneath the thunderstorm,
    condensation may occur due to the expansion and
    cooling of the air and a visible funnel cloud may
    be observed.
  • If the bottom of the funnel cloud touches the
    surface of the Earth, then it is called a tornado.

57
Mesocyclones
Funnel Cloud
Tornado
58
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59
Tornado Frequency
  • You are most likely to see tornadoes in parts of
  • Oklahoma
  • Texas
  • Kansas
  • Indiana
  • Nebraska
  • Florida

60
Tornado Frequency (Cont.)
  • Tornadoes occur more frequently in western Ohio.
  • On average 12-13 tornadoes occur over Ohio during
    a year.

61
Enhance Fujita (EF) Scale for Tornado Damage
  • Theodore Fujita developed a scale for assessing
    the damage caused by tornadoes.
  • An updated and Enhanced Fujita (EF) scale was
    implemented by the U.S. National Weather Service
    on February 1, 2007.

62
Operational EF Scale
  • EF number 3 second gust (mph)
  • 0 65-85
  • 1 86-110
  • 2 111-135
  • 3 136-165
  • 4 166-200
  • 5 over 200

63
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64
Straight Line Winds
  • Sometimes it is difficult to determine if damage
    was caused by a tornado or by straight line
    winds.
  • Thunderstorms can sometimes produce very strong
    downdrafts called downbursts or microbursts that
    generate powerful straight line winds when they
    reach the surface.

65
Severe Thunderstorm
  • The U.S. National Weather Service defines a
    Severe Thunderstorm as having three-quarter inch
    hail or large and/or wind gusts of at least 50
    knots.

66
Severe Thunderstorm Watch and Warning
  • A Severe Thunderstorm Watch indicates that
    conditions over a region are such that it is
    possible for severe thunderstorms to form during
    the next few hours.
  • A Severe Thunderstorm Warning indicates that a
    severe thunderstorm has been identified visually
    by spotters or by radar.

67
Tornado Watch and Warning
  • A Tornado Watch indicates that conditions over a
    region are such that it is possible for tornadoes
    to form during the next few hours.
  • A Tornado Warning indicates that a tornado had
    been identified visually by spotters or by radar.
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