Understanding Weather and Climate Ch 8
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Transcript Understanding Weather and Climate Ch 8
How Does Air Move Around the Globe?
Review of last lecture
• Know 3 Forces that affect wind speed /direction
• Especially work on Coriolis force, as this is the hardest
to understand. Which direction is air deflected to by
Coriolis force?
• What is the geostrophic balance? At which level is it
valid? Difference between upper level and surface
winds
• Troughs, ridges, cyclones and anticyclones. Do they
correspond to high or low surface pressure? Is the air
moving clockwise or counter-clockwise around them?
The most common atmospheric
circulation structure
CE
H
L
Cooling
or No
Heating
Heating
Friction
H
L
CE
Imbalance of heating
Imbalance of temperature
Imbalance of pressure
Wind
Introduction
• Well-defined heating, temperature and pressure patterns exist
across the globe
• These define the general circulation of the planet
• In describing wind motions:
– Zonal winds (east-west): flow parallel to lines of latitude
• Flowing eastward: Westerly wind
• Flowing westward: Easterly wind
– Meridional winds (north-south): flow parallel to lines of
longitude
• Flowing northward: Southerly wind
• Flowing southward: Northerly wind
Annual mean precipitation (heating)
Extratropical stormtrack
Tropical rainfall
Extratropical stormtrack
Primary Highs and Lows
Equatorial low
Subtropical high
Subpolar low
Polar high
Three-cell model
Zonal mean circulation
Each hemisphere is
divided into 3 distinct
cells:
Hadley Cell
Ferrel Cell
Polar Cell
Vertical structure and mechanisms
Polar Cell (thermal):
Driven by heating at
50 degree latitude
and cooling at the
poles
Ferrel Cell (dynamical):
Dynamical response to
Hadley and polar cells
Polar
Hadley
Hadley Cell (thermal):
Heating in tropics forms
surface low and upper
level high air converges
equatorward at surface,
rises, and diverges
poleward aloft
descends in the subtropics
Zonal mean structure of temperature
Two characteristics:
•
Horizontally uniform
in the tropics
•
Steep gradient in
the extratropics
Zonal mean structure of zonal wind
Two characteristics:
•
Westerly winds in
the extratropical
troposphere
•
Jet streams: local
maximum of winds
Westerly winds in the extratropical troposphere
• The existence of the upper level
pressure gradient air is being pushed
toward poles Coriolis effect deflects
upper air (to the right) Westerlies
dominate upper troposphere
• Strongest during winter thermal
gradient is large
• Explains why storms move eastward,
flight times
The Jet Streams
• Caused by steep temperature
gradients between cold and
warm air masses
• Polar front - marks area of
contact, steep pressure
gradient polar jet stream
• Low latitudes subtropical
jet stream
• Stronger in winter, affect daily
weather patterns
A Jet Stream seen from satellite
The subtropical jet is seen as a band of clouds extending
from Mexico on an infrared satellite image
Video: The jet streams
Semipermanent Pressure Cells
• Instead of cohesive pressure belts circling the Earth,
semipermanent cells of high and low pressure exist; fluctuating
in strength and position on a seasonal basis.
• These cells are either dynamically or thermally created.
• Sinking motions associated with the subtropical highs promote
desert conditions across specific latitudes.
• Seasonal fluxes in the pressure belts relate to the migrating Sun
(solar declination).
South Pacific
high
South Atlantic
high
For NH winter:
1. Aleutian and Icelandic lows
2. Siberian and Bermuda-Azores highs
3. South Pacific, Atlantic, Indian highs
South Indian
high
South Pacific
high
South Atlantic
high
For NH summer:
1. Tibetan low
2. Hawaiian and Bermuda-Azores highs
3. South Pacific, Atlantic, Indian highs
South Indian
high
Low pressure: clouds and precipitation
Extratropical stormtrack
Tropical rainfall
Extratropical stormtrack
High pressure: warm surface temperature,
drought and desert
Global distribution of deserts (all near high pressure cells)
General circulation of the oceans
• Ocean surface currents – horizontal water motions
• Transfer energy and influence overlying atmosphere
• Surface currents result from frictional drag caused by
wind - Ekman Spiral
• Water moves at a 45o angle (right)
in N.H. to prevailing wind direction
• Due to influence of Coriolis effect
• Greater angle at depth
Global surface currents
• Surface currents mainly driven by surface winds
• North/ South Equatorial Currents pile water westward, create the Equatorial
Countercurrent
• western ocean basins –warm poleward moving currents (example: Gulf Stream)
• eastern basins –cold currents, directed equatorward
Summary
• Three precipitation (heating) belts. Primary high and
lows
• Three-cell model. Mechanism for each cell
• Two characteristics of zonal mean temperature structure
• Two characteristics of zonal mean wind structure. Why
does westerly winds prevail in the extratropical
troposphere? What cause the jet streams?
• Semipermanent pressure cells. Low pressure is
associated with clouds and precipitation. High pressure
is associated with warm surface temperature, drought,
and desert.
• What drives the ocean surface currents? In the case of
Ekman spiral, what is the direction of surface current
relative to surface wind?
Works cited
Images
•http://pulleysandgears.weebly.com/gears.html
•http://visual.merriamwebster.com/earth/meteorology/meteorological-measuringinstruments/measure-wind-direction.php