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Middle-Latitude Cyclones - I

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Moves fast, showers along the leading edge (squall line) ... Frontolysis: The front weakens and dissipates. Why?-the air masses start losing their identities. ... – PowerPoint PPT presentation

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Title: Middle-Latitude Cyclones - I


1
Middle-Latitude Cyclones - I
2
RECAP Types of Fronts
  • Cold fronts cold, dry stable air is replacing
    warm, moist unstable air. Moves fast, showers
    along the leading edge (squall line).
  • Warm fonts warm, moist unstable air is replacing
    cold dry stable air. Overrunning warm air rides
    up and over the cold air, widespread cloudiness,
    light-to-moderate precipitation well ahead of the
    front
  • Stationary fronts essentially no movement, winds
    blow parallel to the front, in opposite
    directions on both sides
  • Occluded fronts when a cold front catches up
    with a warm front (more later)
  • The symbols on a map are in the direction of the
    air mass motion.

3
Stationary Front
  • Stationary front- a front which does not move or
    barely moves.
  • Stationary fronts behave like warm fronts, but
    are more quiescent.
  • Many times the winds on both sides of a
    stationary front are parallel to the front and
    have opposite direction.
  • Typically stationary fronts form when polar air
    masses are modified significantly so as to lose
    their character (e.g., cold fronts which stall).
  • Typically there is no strong precipitation
    associated with stationary fronts (why? no big
    contrast in the air mass properties, no air
    uplifting and condensation).

4
Occluded fronts.
Cold occlusion
  • Cold fronts move faster than warm fronts. They
    can catch up and overtake their related warm
    front. When they do, an occluded front is formed.
     
  • Cold occlusion very cold air behind, not so cold
    air ahead of, the warm front
  • The upper warm front follows the surface occluded
    front

5
Warm Occlusion
  • Very cold air ahead of, not so cold air behind,
    the warm front
  • The cooler air from the cold front cannot lift
    the very cold air ahead, rides piggyback
  • The warm front aloft precedes the surface
    occluded front

6
Weakening/Strengthening of the Front
  • Frontolysis
  • The front weakens and dissipates
  • Why?-the air masses start losing their
    identities.
  • The temperature (humidity) contrast across the
    front is decreasing.
  • Typical for slow moving fronts
  • Frontogenesis
  • The front intensifies.
  • Why? The temperature (humidity) contrast across
    the front is increasing.
  • Example cP air mass moves over warm ocean
    water.

7
Weather Map
  • Shown surface-pressure systems, air masses,
    fronts, isobars, winds and air flow (large
    arrows)
  • Green-shaded area precipitation

8
Weather Map
  • The example from Chapter 1 Fig. 1.14.

9
Sample weather maps
10
Polar Front Theory
  • A model of how mid-latitudes storms develop
    their birth, growth, and decay.
  • The model connects the storms with the dynamics
    of the polar front the transition zone between
    the cold air in the polar cell and the warmer air
    at middle-latitude (Ferrel cell).
  • The polar front is a region of air conversions
    at the surface, upward motion, and divergence
    aloft. This results in low surface pressure.

Jacob Bjerknes
Vilhelm Bjerknes
Halvor Solberg Tor Bergeron
11
The life of a mid-latitude (wave) cyclone
12
The life of a mid-latitude (wave) cyclone
  • A the polar front is stationary the winds are
    in opposite directions on the two sides of the
    front. This creates a cyclonic wind shear.
  • B A local perturbation a region of low pressure
    appears somewhere along the front. The front then
    breaks in two fronts
  • warm (moving northward - why? Coriolis force)
  • cold (moving southward - why? Coriolis force)
  • Central pressure the junction of the two fronts
  • A frontal wave is formed.
  • The winds aloft set the general direction of
    motion (black arrow)
  • The wave starts moving to the east and gradually
    becomes
  • C Open wave. The cold front moves faster than
    the warm front -gt polar front bends. Warm sector
    between the two fronts. The central pressure
    keeps dropping isobars now encircle it.

13
Weather patterns around a cyclonic wave
  • South of the wave
  • First a warm front
  • Warmer air advancing
  • Wide band of precipitation.
  • Starts with snow first.
  • Then rain and drizzle.
  • Cold front
  • Cold air advancing
  • Sharp drop of pressure
  • Strong precipitation at the front.
  • Then dry, cold, clear weather.
  • North of the wave some clouds associated with
    the low pressure center but no strong
    precipitation because there is no warm moist air
    around.

14
The life of a mid-latitude (wave) cyclone
  • D Mature cyclone (initial occlusion). Cold front
    closes in on the warm front. Most intense stage
    of the storm. Clouds cover a large area.
  • E Advanced occlusion. Triple point where all
    three fronts come together. The center of the
    storm gradually dissipates
  • Cold air on both sides of the occluded front
  • Warm sector far removed the rising warm and
    moist air provides energy for the storm (kinetic
    energy, latent heat of condensation)
  • F Cut-off cyclone plus a stationary front once
    again.

15
Family of cyclones
Dying out E Advanced occlusion
C Open wave
Just forming B Frontal wave
16
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17
Cyclogenesis
  • Any development or strengthening of a
    mid-latitude cyclone
  • Some regions have greater propensity for
    cyclogenesis
  • Gulf of Mexico
  • Eastern slopes of Rockies
  • and Sierra Nevada
  • Lee-side lows
  • Atlantic ocean east of
  • Carolinas
  • Noreasters

Lee cyclogenesis
18
Famous noreasters the Great Blizzard of 2006
  • Began on Feb 11 2006
  • Developed an eye
  • All-time record snowfall (27 in) in New York
    City.

19
Where do mid-latitude cyclones form?
  • Typical paths of winter mid-latitude
    (anti)cyclones
  • Lows towards the east-northeast
  • Highs towards the east-southeast
  • Explosive cyclogenesis (bomb) when the central
    pressure drops very rapidly (more than 24 mb in
    24 hours)
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