Wind
Wind is air in
motion. It is produced by the uneven heating of the earth’s surface by the
sun. Since the earth’s surface is made of various land and water
formations, it absorbs the sun’s radiation unevenly. Two factors are
necessary to specify wind: speed and direction.
As the sun
warms the Earth's surface, the atmosphere warms too. Some parts of the Earth
receive direct rays from the sun all year and are always warm. Other places
receive indirect rays, so the climate is colder. Warm air, which weighs less
than cold air, rises. Then cool air moves in and replaces the rising warm air.
This movement of air is what makes the wind blow.
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A windstorm is just a storm with high winds or violent gusts but
little or no rain. A gust
front is the leading edge of cool air rushing down and out from a thunderstorm.
There are two main reasons why the air flows out of some thunderstorms so
rapidly. The primary reason is the presence of relatively dry air in the lower
atmosphere. This dry air causes some of the rain falling through it to
evaporate, which cools the air. Since cool air sinks (just as warm air rises),
this causes a down-rush of air that spreads out at the ground. The edge of this
rapidly spreading cool pool of air is the gust front. The second reason is that
the falling precipitation produces a drag on the air, forcing it downward. If
the wind following the gust front is intense and damaging, the windstorm is
known as a downburst.
A downburst is created by an area of
significantly rain-cooled air that, after hitting ground level, spreads out in
all directions producing strong winds. Unlike winds in a tornado, winds in a
downburst are directed outwards from the point where it hits land or water. Dry
downbursts are associated with thunderstorms with very little rain, while wet
downbursts are created by thunderstorms with high amounts of rainfall.
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A derecho is a widespread and long-lived windstorm that is
associated with a fast-moving band of severe thunderstorms. They can produce
significant damage to property and pose a serious threat life, primarily by
downburst winds. To be classified as a derecho, the path length of the storm
has to be at least 280 miles long. Widths may vary from 50-300 miles. Derechos
are usually not associated with a cold front, but a stationary front. They
occur mostly in July, but can occur at anytime during the spring and
summer.
The jet stream is the steering mechanism for fronts. It is a fast
flowing, river of air found in the atmosphere at around 12 km above the surface
of the Earth just under the tropopause. They form at the boundaries of adjacent
air masses with significant differences in temperature, such as of the polar
region and the warmer air to the south. Because of the effect of the Earth's
rotation the streams flow west to east, propagating in a serpentine or
wave-like manner at lower speeds than that of the actual wind within the
flow.
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The equator receives the Sun's direct
rays. Here, air is heated and rises, leaving low pressure areas behind. Moving
to about thirty degrees north and south of the equator, the warm air from the
equator begins to cool and sink. Between thirty degrees latitude and the
equator, most of the cooling sinking air moves back to the equator. The rest of
the air flows toward the poles.
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The trade winds are just air
movements toward the equator. They are warm, steady breezes that blow almost
continuously. The Coriolis Effect makes the trade winds appear to be curving to
the west, whether they are traveling to the equator from the south or
north.
The
doldrums is an area of calm weather. The trade winds coming from the south and
the north meet near the equator. These converging trade winds produce general
upward winds as they are heated, so there are no steady surface winds.
Between thirty and
sixty degrees latitude, the winds that move toward the poles appear to curve to
the east. Because winds are named from the direction in which they originate,
these winds are called prevailing westerlies. Prevailing westerlies in the
Northern Hemisphere are responsible for many of the weather movements across
the United States and Canada.
At about sixty
degrees latitude in both hemispheres, the prevailing westerlies join with the
polar easterlies to reduce upward motion. The polar easterlies form when the
atmosphere over the poles cools. This cool air then sinks and spreads over the
surface. As the air flows away from the poles, it is turned to the west by the
Coriolis effect. Again, because these winds begin in the east, they are called
easterlies.
On a
warm summer day along the coast, this differential heating of land and sea
leads to the development of local winds called sea breezes. As air above the
land surface is heated by radiation from the Sun, it expands and begins to
rise, being lighter than the surrounding air. To replace the rising air, cooler
air is drawn in from above the surface of the sea. This is the sea breeze, and
can offer a pleasant cooling influence on hot summer
afternoons.
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A land
breeze occurs at night when the land cools faster than the sea. In this case,
it is air above the warmer surface water that is heated and rises, pulling in
air from the cooler land surface.
Wind is
the fastest growing source of electricity in the world. It's often one of the
least expensive forms of renewable power available. Some experts say it can
sometimes be the cheapest form of any kind of power. Generating power from the
wind leaves no dangerous waste products behind. Best of all, its supply is
unlimited.
Windmills work
because they slow down the speed of the wind. The wind flows over the airfoil
shaped blades causing lift, like the effect on airplane wings, causing them to
turn. The blades are connected to a drive shaft that turns an electric
generator to produce electricity.
Local Winds
| Chinook |
Easterly off the Rocky
Mountains |
| Santa Ana |
Easterly towards Southern
California |
| Scirocco |
Southerly from North Africa
to southern Europe |
| Mistral |
Northwesterly from central
France to Mediterranean |
| Marin |
Southeasterly from
Mediterranean to France |
| Bora |
Northeasterly from eastern
Europe to Italy |
| Gregale |
Northeasterly from
Greece |
| Etesian |
Northwesterly from
Greece |
| Libeccio |
Southwesterly towards
Italy |
Beaufort Scale The Beaufort scale is an empirical measure for the
intensity of the weather based mainly on wind power. The scale was created by
the British naval commander Sir Francis Beaufort around 1806.
| Beaufort number |
Wind speed
MPH |
Wind Speed
Knots |
Description |
Sea conditions |
Land conditions |
| 0 |
<1 |
<1 |
Calm |
Flat |
Calm |
| 1 |
1-3 |
1-3 |
Light air |
Ripples without crests |
Wind motion visible in smoke |
| 2 |
4-7 |
4-6 |
Light breeze |
Small wavelets |
Leaves rustle |
| 3 |
8-12 |
7-10 |
Gentle breeze |
Large wavelets |
Smaller twigs in constant motion |
| 4 |
13-18 |
11-16 |
Moderate breeze |
Small waves |
Small branches begin to move |
| 5 |
19-24 |
17-21 |
Fresh breeze |
Moderate longer waves |
Smaller trees sway |
| 6 |
25-31 |
22-27 |
Strong breeze |
Large waves with foam crests |
Large branches in motion |
| 7 |
32-38 |
28-33 |
Near gale |
Sea heaps up and foam begins to streak |
Whole trees in motion |
| 8 |
39-46 |
34-40 |
Gale |
Moderately high waves with breaking crests |
Twigs broken from trees |
| 9 |
47-54 |
41-47 |
Severe gale |
High waves with dense foam |
Light structure damage |
| 10 |
55-63 |
48-55 |
Storm |
Very high waves.
The sea
surface is white |
Trees uprooted. Considerable structural damage |
| 11 |
64-72 |
56-63 |
Violent storm |
Exceptionally high waves |
Widespread structural damage |
| 12 |
73-82 |
64-71 |
Hurricane |
Sea completely white with driving spray. |
Massive and widespread damage to structure |
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