I. Atmospheric Circulation
A. Terms
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"Wind" - the horizontal movement of air relative to the Earth's
surface
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"Zonal Flow" - a predominately W-E or E-W wind flow
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"Meridional Flow" - a predominately N-S or S-N wind flow
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"Wind Compass", "Anemometer", "Wind Vane"
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Wind Direction: winds are named for the direction from which
they originate (from which they blow)
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"Isobars" - lines connecting points of equal pressure
B. Scales of Atmospheric Motions
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circulations are arranged according to their size (both in terms of space
and time)
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from smallest to largest:
1) Microscale Circulations:
length: ~ 1 centimeter - 100 meters
time: ~ seconds - minutes
e.g., eddies (small whirls of air) present in the rising air of smoke
stacks act to disperse the smoke; eddies also move tree branches, swirl
dust, blows loose papers, etc.
2) Mesoscale Circulations:
length: ~ 0.1 - 100 kilometers (km)
time: ~ hours - days
e.g., the circulation of city air, local winds (shoreline and mountain
circulations), thunderstorms, tornadoes, and small tropical storms
3) Synoptic Scale:
length: ~ 100 - 10,000 kilometers
time: ~ days - weeks
- wx systems observed on a wx map:
extratropical cyclones, high pressure systems, and hurricanes
4) Planetary-Scale Circulations (global scale or "general circulation")
length: greater than 10,000 km (earth's circumference is ~ 40,00
km)
time: weeks - months
e.g., "prevailing westerlies" in the middle latitudes, or the "trade
winds" in the low latitudes
C. Newton's Laws
1) 1st Law:
"In the absence of unbalanced force: a body at rest will remain at
rest; and a body in motion will remain in "straight-line" motion at constant
speed"
to change the motion of air, a force needs to be applied
2) 2nd Law:
Force = Mass x Acceleration (F = m x A)
-
the force (push or pull) acting on an object (air parcel) is directly porportional
to the acceleration produced
the acceleration of the object (air), is directly proportional to the force
applied;
thus, to determine the motion (speed & direction)
of air, we must examine all the forces that affect the horizontal movement
of air:
-
Pressure Gradient Force
-
Coriolis Force
-
Friction Force
C. Behavior of the Individual Forces That
Influence the Wind
1) Pressure Gradient Force (P)
- can be separated into 2 components:
P = Pv + Ph Pv = vertical component
Ph = horizontal component
a) Vertical Pressure Gradient Force:
- direction: upward (toward lower pressure)
- magnitude: same as G (gravitational force)
(Pv = -G)
b) Horizontal Pressure Gradient Force:
- direction: toward lower pressure
(perpendicular to the isobars on a sea-level surface map)
- magnitude: proportional to the "pressuregradient"
pressure gradient = change in pressure /horizontal distance
-
more closely spaced isobars on a surface map indicate where the horizontal
pressure gradient force is strongest !!!
2) Coriolis Force: (an "apparent" force)
direction: acts perpendicular (to the right of) the wind in the
Northern Hemisphere; perpendicular (to the left of) the wind in the Southern
Hemisphere
magnitude: proportional to the wind speed; increases for all
wind speeds from a value of zero at the equator to a maximum at the poles
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the coriolis force only influences wind direction, never wind speed
-
its affect is minimal for smaller-scale air flows
3) Friction:
direction: acts in opposition to the wind direction
magnitude: depends on the roughness of the surface over which
the air moves
-
friction is important to consider for air motions near the earth's surface;
it's relatively unimportant in the free atmosphere (above 1 km)
C. Force Balances & Resulting Flows
1). Geostrophic Balance
-
it exists for straight-line flow in the "free"
atmosphere
(above the friction layer - above 1,000 meters)
-
At equilibrium (balance): Ph = - Cor
-
The wind that results from this balance between the horizontal pressure
gradient force and the coriolis force is called the geostrophic wind (Vg).
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Vg blows parallel to the height contours (lines that connect points
of equal elevation above sea level)
-
the speed of the geostrophic wind is directly related to the pressure gradient
2) Surface Winds (Ekman Balance)
- for flow in the planetary boudary layer (PBL) (within the friction
layer - the lowest 1,000 m)
Ftotal = Ph + Cor + Fr
friction reduces wind speed which reduces the coriolis force; the
weaker coriolis force no longer balances the pressure gradient force and
the wind blows across the isobars toward lower pressure
-
the resultant wind from this balance blows at an angle of 20 to 40 degrees
across
isobars toward lower pressure !!
-
the greater the force of friction, the greater the cross isobar flow
a) vertical motions associated with highs & lows:
Summary of Surface, Upper-Air, and Vertical Circulations
D. Global Circulation
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if we average the planet's winds over a long period of time, the local
winds (circulations) vanish, and we see the global-scale wind patterns:
the "general circulation of the atmosphere"
(note that the "general circulation" represents the
average air
flow around the world. The actual winds at any given place and time may
vary greatly from this average)
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the differential heating (unequal heating) of the earth's surface is the
driving force behind the general circulation
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recall that averaged over the whole earth, insolation is equal to outgoing
long wave from the earth's surface
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however, the tropical areas experience a net gain in energy, while the
polar areas experience a net loss in energy. How is this inequity balanced?
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the atmosphere and oceans transport warm air poleward and cool air equatorward
Model of the Global Circulation:
1) Single-Cell Model
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assume: (1) that the earth's surface is uniformly covered
with water (no land vs. water differential heating effect); (2) that the
sun is always directly overhead at the equator (the winds will not shift
seasonally); and (3) the earth doesn't rotate (no coriolis force)
-
the only force operating is the pressure gradient force, and we get a giant
convection cell with warm air rising at the equator, heading north
and south on either side of the equator aloft, and then sinking motion
at the poles. The air then travels from the poles toward the equator at
the surface of the earth
-
we call this giant convection cell the "Hadley Cell"
2) Three-Cell Model
we keep the first two assumptions, but we do allow for
the coriolis force
here too, the tropics heat-up more than the poles, so we (as in the
single-cell model) have a surface high at the poles and a broad trough
of low pressure at the equator
in this model though, there are three circulation cells in each hemisphere
that act to redistribute heat energy
(a) Hadley Cell - a circulation in which air rises at
the equator, moves poleward at upper levels, cools, converges, and sinks
at ~ 30 degrees latitude; and returns to the equator at lower levels. The
latitudes beneath the rising branch of the Hadley Cell are known as the
doldrums
(much rain and light winds)
(b) Ferrel Cell - a circulation in which air sinks at
~ 30 degrees latitude, moves poleward at low levels, rises at ~ 60 degrees
latitude, and returns to ~ 30 degrees latitude at upper levels. The latitudes
beneath the sinking branch of the Ferrel Cell (or Hadley Cell) are known
as the "Horse Latitudes (little rain and light winds)
(c) Polar Cell - a circulation in which air rises at ~ 60 degrees
latitude, moves poleward at upper levels, sinks over the pole, and returns
to ~ 60 degrees latitude at lower levels
Surface Circulations:
(a) Trade Winds
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winds blowing form the NE in the Northern Hemisphere, & from the SE
in the Southern Hemisphere
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occur between the equator and ~ 30 degrees N (S) latitude
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are very steady in speed and direction
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the trades are the equatorward branch of the subtropical highs
centered in the horse latitudes
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trade winds from both hemispheres converge in the doldrums, often referred
to as the Intertropical Convergence Zone (ITCZ)
(b) Prevailing Westerlies
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winds blowing generally form the west in both hemispheres between ~ 30
and 60 degrees
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they occur over a region where there is a strong N-S temperature difference
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storms (extratropical cyclones) moving through this region cause the prevailing
westerlies to be much less consistent than the trade winds
(c) Polar Easterlies
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winds blowing generally from the east poleward of ~ 60 degrees
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the "polar easterlies" circulate around a weak polar high which
develops under the sinking branch of the polar cell
The Polar Front:
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cold air moving southward via the polar easterlies encounters mild air
moving poleward via the westerlies
-
these two air masses of contrasting temperatures don't readily mix. They
are separated by a boundary called the "Polar Front" (it is along this
boundary (front) that cyclones form)
Average Surface Winds & Pressure
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Equatorial Low Pressure Trough (ITCZ)
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Subtropical Highs
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Subpolar Lows
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Polar Highs
Global Winds
E. Local Winds
Thermal Circulations: circulations resulting from changes
in air temperature (density), in which warm (less dense) air rises and
cold (more dense) air sinks
Types:
1) Land and Sea Breezes
Lake Breeze
2) Monsoons
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regional wind systems that change direction seasonally - e.g. India's Monsoon
Monsoon
3) Mountain & Valley Breezes
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warm (less dense) air rises upslope from the valley during the day; and
cool, dense air sinks down the mountain slopes at night
Mountain & Valley Breeze
4) Katabatic Winds
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larger scale (regional-scale) density flows (e.g. Antartica & Greenland
katabatic flows; Santa Ana (warm) winds
Katabatic Winds
F. Upper Level Westerlies in Both Hemispheres
Upper-Level Westerlies in Both Hemispheres (why?)
Mid-Latitude Westerlies (Zonal Flow)
Mid-latitude Westerlies (Meridional Flow)
