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Atmospheric Circulations

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Mountains - Chinook winds, mountain/valley breezes ... Chinook Winds. Air which starts at 10 C on the western side, ends up at 18 C on the eastern side. ... – PowerPoint PPT presentation

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Title: Atmospheric Circulations


1
Atmospheric Circulations
  • Chapter 7

2
A Fluid Atmosphere
  • Easier to envision atmospheric motions if we
    think of our atmosphere as a fluid
  • Thats what it really is
  • Air motions are similar to those in any fluid
  • Oceans, rivers, etc.
  • All kinds of circulations ranging from
    microscopic whirls to large storms (low pressure
    systems) to global wind patterns (jet streams)

3
Water vs Air
Eddies
Gulf Stream
4
Scales of Motion
  • In meteorology, scales of motion describe the
    size and duration of circulations
  • Smallest scale were concerned with is the
    microscale, largest is the global scale
  • And everything in between

5
Scales of Motion
  • Global
  • Synoptic
  • Meso
  • Micro

6
Scales of Motion
7
Scales of Motion
  • Often, its hard to tell what kind of motions are
    going on since you cant see air
  • Cant see turbulence in a plane right?

8
Lenticular cloud
9
Scales of Motion
  • Sometimes you can see whats going on when
    motions are visible in clouds

10
Local Wind Systems
  • Interesting topic because they exist almost
    everywhere
  • Coastal regions - Seabreezes
  • Mountains - Chinook winds, mountain/valley
    breezes
  • Often due to 1) terrain or 2) temperature
    differences from one place to another
  • If due to 2) - we call it a thermal circulation

11
Thermal Circulations
  • These circulations are due to differences in
    temperature
  • Like between air over land vs air over water
  • The temp differences cause something to happen to
    the pressure
  • And what happens when the pressure is different
    from place to place??
  • WIND

12
Thermal Circulations
  • Initially, if temps are uniform, so are pressure
    surfaces
  • Going upward, pressure surfaces are horizontal
  • But what if air to the south heats up?

13
Thermal Circulations
  • Remember from earlier, if a column of air warms,
    it stretches vertically
  • So, the pressure surfaces are now higher in the
    warmer air causing a pressure gradient force -
    wind

14
Thermal Circulations
  • To the south, a thermal low pressure develops
    at the surface
  • Due to air moving toward north aloft
  • To the north, high pressure develops at surface
  • Due to air piling up aloft

15
Thermal Circulations
  • So, air begins to move from high to low at both
    the surface and aloft
  • Air at the surface warms near the low and rises
  • Air aloft cools over the surface high and sinks

16
Sea Breezes
  • Sea breezes are a good example of a thermal
    circulation
  • Form in tropical/sub-tropical regions in the warm
    season
  • People from coastal areas of FL know about these
    - nice at the beach but reeeaaall dark inland
  • Can also have lake breezes and river breezes
    which form in the same way

17
Sea Breezes
  • Same as before except now the water/land is
    causing the contrast in temp/pressure
  • Thermal low develops over land and wind at the
    surface moves from water to land

18
Sea Breezes
  • As before, air rises in the vicinity of the
    thermal low and often produces thunderstorms
    inland
  • Thats why the summer weather at the coast is
    usually better than weather inland (in terms of
    sunshine)

19
Sea Breezes-lightning
T-storms
East Coast Sea Breeze
Sea Breeze in panhandle
20
Sea Breezes
  • How would you know that a sea breeze has passed?
  • Temp ?
  • Decreases (air off of the water is cooler)
  • Humidity ?
  • Increases (air off of the water is more moist)
  • Wind ?
  • Shifts to onshore and increases in speed
  • Sky ?
  • Clear after passage, cloudy before

21
Sea Breezes
  • Florida gets hit often by thunderstorms due to
    sea breezes
  • Sometimes sea breezes from both coasts converge
    over the central peninsula (Orlando in particular)

22
T-storm frequency
23
Sea Breezes
  • Which raises an interesting question

24
Land Breezes
  • Remember from several weeks ago we said that land
    heats up and cools down quicker than water?
  • Happens at night causing a reversal of the sea
    breeze
  • Called a land breeze

25
Land Breezes
  • Air over land cools quickly at night
  • So now air over water is warmer than air over
    land
  • Winds switch to offshore
  • generally weaker than the sea breeze

26
Monsoon
  • What kind of image does that word conjure up?
  • Lots of heavy rain?
  • Floods?
  • Actually it means
  • A seasonal shift in wind patterns
  • So it doesnt directly address rain at all
  • The monsoon is a thermal circulation just like
    the sea breeze but it occurs as a seasonal cycle
    - not a daily cycle

27
Asian Monsoon
  • Asian monsoon is the most well developed one
  • Weaker monsoon over the desert southwest of N.
    America
  • Very cold air over the continent during winter
  • Causes high pressure and flow toward the water
  • This also keeps moisture offshore
  • So, very dry over land in the winter

28
Asian Monsoon
  • Things (winds) change during the summer as the
    land heats up and low pressure develops
  • Now wind moves onshore and brings with it very
    moist air
  • This region, particularly central India, gets
    absolutely hammered w/ rain
  • Some places over 400 inches a year! (most of it
    coming in 6-7 months!)

29
Asian Monsoon
  • Why so much rain (other than the obvious)?
  • 1) Convergence of air enhances upward motion
  • 2) Terrain

Lots of mountains
30
Chinook Winds
  • Snow eaters
  • Warm, dry winds on the eastern side of the Rocky
    Mountains
  • Due to compressional heating as air descends
  • Enhanced if clouds form on the western side
  • Can cause warming of gt40ºF in 1 hour!

31
Chinook Winds
  • Chinook wall cloud - precursor of Chinook winds
  • 20ºF when this pic was taken - 60ºF same time
    next day

32
Chinook Winds
  • How they work
  • Any air which descends will warm by compression -
    compressional heating
  • main source of warmth for Chinooks
  • But if clouds form on the western side of the
    mountains, the Chinook wind will be even warmer
    and drier than w/o clouds
  • Why?
  • Have to go back to the moist/dry adiabatic stuff
  • Remember moist rate6ºC/1000m, dry
    rate10ºC/1000m

33
Chinook Winds
  • Air which starts at 10ºC on the western side,
    ends up at 18ºC on the eastern side.
  • Due to cooling at the moist rate starting at 1000
    m..but warming at the dry rate going down
  • So, clouds enhance the Chinook winds

Cooling at moist rate
Warming at dry rate
34
Chinook Winds
  • Very localized - just near the mountain base
  • As warm air hits the cold air below, the boundary
    can oscillate
  • Cities near the boundary can experience rapid
    back-and-forth changes in temperature

35
Chinook Winds
  • One case in South Dakota
  • 530 a.m. -4ºF
  • 940 a.m. 54ºF
  • 1030 a.m. 11ºF
  • 1045 a.m. 55ºF

36
Santa Ana Winds
  • Named after the Santa Ana Canyon in S.California
    where they are often funneled through
  • Like Chinooks - compressional heating causes them
  • Air descends from high plateaus
  • Hot and dry
  • Major problem associated with them are forest
    fires
  • Winds dry things out AND fan flames

37
General Circulation
  • From earlier, there are all kinds of local wind
    systems - many more than I went over
  • All kinds of smaller circulations too
  • But what about the global wind patterns?
  • If we average winds over a long period of time,
    the small stuff disappears and we are left with
    the global scale winds or general circulation
    of the atmosphere
  • Keep in mind - just an average
  • Can be different at any particular instant

38
General Circulation
  • A look at the average global winds can give us
    insight into
  • 1) Driving mechanisms behind the winds
  • 2) Model of how heat is transferred from the
    tropics to the poles
  • Already established the fact that uneven heating
    of the earth is what causes weather
  • Including wind
  • In a nutshell tropics get excess energy while
    polar regions have an energy deficit
  • Wind tries to balance things

39
Single Cell Model
  • Very simplified model but still gives us some
    insight. 3 Key assumptions
  • 1) All water over the earth
  • 2) Sun always over equator
  • 3) No rotation
  • Result
  • High pressure at the poles
  • Low pressure at the equator
  • 1 huge convective cell in each hemisphere
  • Called Hadley Cells after the guy who
    postulated the idea.

40
Single Cell Model
  • Cold air flows toward tropics from poles (H to L)
    at the surface
  • Warm air flows toward poles from tropics aloft
  • Just like a sea breeze circulation
  • So, some of the excess energy at the tropics is
    transferred to the poles
  • What if we get rid of assumption 3 and let the
    earth rotate?

41
Three Cell Model
  • Now we have 3 cells in each hemisphere rather
    than one.
  • More realistic
  • Still have H pressure at poles and L pressure at
    equator
  • Also now, H and L pressure at 30º and 60º
    respectively

H
L
H
L
H
L
H
42
Three Cell Model
  • Look at the vertical motion where the cells meet
  • Equator Rising air
  • Lots of rain here
  • 30º Sinking air
  • Most of the worlds deserts lie near this
    latitude
  • 60º Rising air
  • This is where most big mid-latitude storms form
  • So this model does a better job with surface
    winds

43
Three Cell Model
  • Not too bad huh?
  • Everything is shifted to the south due to seasons
  • Cloud bands where the model says low pressure
    should be
  • Rising air

Today
44
Surface Winds
  • Intertropical Convergence Zone (ITCZ)
  • near the equator
  • tropical systems form here
  • Trade winds
  • named such because sailing vessels used these
    winds to travel west
  • not much wind poleward of the trades (horse
    latitudes)
  • Westerlies
  • where we live
  • Polar Easterlies

45
The Real World
  • Still two assumptions in the three cell model
  • all water/no land and sun always over equator
  • These factors change things a bit and give us the
    real pressure/wind fields.

46
The Real World
  • Semi-permanent features
  • Lows near 60º
  • Highs near 30º

January
47
The Real World
  • Strength and position of these features changes
    with the seasons
  • The Highs on either side of the U.S. have a great
    impact on weather at each coast

July
48
Semi-permanent Highs
  • Generally sinking air on the east side of highs
    and rising air on the west side
  • Summers are dry on the west coast and wet on the
    east coast

49
Semi-permanent Highs
  • LA (west coast) gets almost no rain during the
    summer
  • Atlanta (east) gets a great deal of rain during
    the summer months

50
Jet Streams
  • Fast flowing rivers of air at upper levels
  • 33,000-46,000 ft usually
  • On average 100s - 1000s miles long, 100 miles
    wide, 1 mile deep
  • Existence first confirmed by military pilots
    during WWII
  • Suspected beforehand due to fast moving cirrus
    clouds
  • Important because they can show us where cold air
    is and where storms will track
  • Also if storms will intensify

51
Jet Streams
  • Like all winds, jets occur due to horizontal
    differences in pressure
  • Sharp north/south temperature/pressure
    differences aloft
  • The temperature contrast is at a maximum during
    the winter
  • Jet streams are strongest during winter season

52
Jet Streams
  • Cold air to the north side
  • Warm air to the south
  • So, we get our coldest weather when the jet
    stream dips to the south over the SE U.S.
  • Like last week

Cold
Warm
53
Jet Streams
  • Cold air heading into the East
  • Strong N-S component (like now), the flow is
    called meridional
  • Active weather patterns
  • Flow more E-W, called zonal
  • Cold air pretty much stays to the north

54
Jet Streams
  • Jet stream as simulated with a mesoscale model
  • Japan Jet
  • Strongest jet stream (on average) in the world
  • Orange indicates wind speeds of near 200 mph!
  • Jet Streak - highest wind speeds w/in jets

55
Atmosphere/Ocean Interaction
  • Water temps along the West Coast are cold!
  • Along the East Coast, temps are much warmer
  • Why?

56
Atmosphere/Ocean Interaction
  • Winds are from the north along the coast causing
    the current to flow toward the south
  • The Coriolis force deflects the surface water to
    the right
  • Now, cold water from below moves up to replace it
  • Called upwelling

57
ENSO -El Niño Southern Oscillation
  • In the news a lot several years ago
  • 2-7 year cycle
  • Weakening or reversal of the Pacific trade winds

58
ENSO
  • Normally, low pressure exists over the western
    Pacific and high pressure dominates over the
    eastern Pacific
  • So, winds blow from east to west at the surface

59
ENSO
  • The wind causes warm water to move west and
    upwelling occurs near the coast of S. America
    (cold water up to the surface)

60
ENSO
  • The upwelling along the coast is essential for
    the fishing (anchovies) industry
  • Cold water from below reaches the surface and is
    rich in nutrients (fish like it)

61
ENSO
  • Non-El Niño sea surface temperatures

Cold
Warm
62
ENSO
  • Every few years, the surface pressure pattern
    breaks down causing a weakening or even reversal
    of the trade winds
  • Now warm water is pushed toward S. American coast

63
ENSO
  • Lasts a year or two on average
  • Devastates the fishing industry in this region
  • Changes weather patterns worldwide

64
ENSO
  • El Niño sea surface temperatures

Warm
Cold
65
ENSO
  • Warm water spreading east toward the S. American
    coast

March 17
March 27
April 6
66
ENSO Worldwide
  • So does it just affect weather in the Pacific
    where it occurs?
  • No way
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