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Weather Theory

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Warm front could have stratus type & cold front could have cumuliform type. Stratus can hide the cumuliform clouds & hide TS (known as embedded TS) ... – PowerPoint PPT presentation

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Title: Weather Theory

1
Weather Theory

Aviation 310

2
The Atmosphere

Divided into layers based on temperature
troposphere
stratosphere
mesosphere
thermosphere
Most flying occurs in tropospherejets may cruise
in stratosphere
tropopause is boundary b/w the two regions
78 nitrogen, 21 oxygen, 1 other gases

3
Atmosphere

Temp decreases w/ gain in altitude in troposphere
until reaching the tropopause where the temp is
constant
The rate of change of temp. w/ altitude is called
temperature lapse rate
Dry adiabatic lapse rate 3 deg/1000 ft
Wet adiabatic lapse rate 1.5 deg/1000 ft
Ambient lapse rate 2 deg/1000 ft

4
Troposphere

Most weather occurs in troposphere (I.e. clouds,
precipitation, wind)
Tropopause is about 20,000 over the poles
60,000 _at_ equator
It is higher in each region in summer than winter
Average is 36,000
Thunderstorm clouds can reach into the
stratosphere if severe enough

5
Air Masses

Maritime is air over an oceanit absorbs moisture
Continental is over is air over landvery dry

6
Weather Theory

The cause of all weather is unequal heating of
the Earths surface by the sun
Water requires more heat energy than land to
effect a change in temperature
Therefore, oceans will heat and cool more slowly
than landmasses

7
Atmospheric Circulation

The movement of air relative to earths surface
Due to unequal heating, warm, less dense air
rises this air is then replace by colder, more
dense air
Advection vertical movement of air
Convection horizontal movement of air

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Atmospheric Pressure

Standard 29.92 in of Mercury or 1013.2 millibars
_at_ S.L. decreases 1 inch/ 1000 ft
Pressure changes due to unequal heating of earth
Pressure systems
Highs an area of pressure higher than standard
Ridge an extended area of high pressure
Lows an area of pressure lower than standard
Trough an extended area of lower pressure
Air flows from high pressure to low pressure

11
Coriolis Effect

Due to the rotation of the earth, winds are
deflected to the right in the northern hemisphere
H L

12
Coriolis Force

In the Northern Hemisphere
Winds flow out of a high pressure system
clockwise due to Coriolis force.
Winds flowing into a low will be rotating
counter-clockwise due to Coriolis force.

13
Frictional Effects

Below 2,000 feet AGL surface friction will tend
to reduce wind speed and Coriolis force allowing
the winds to flow at an angle to the isobars
The angle that these winds flow at is
approximately 30 degrees

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Therefore winds flowing around a high moves
outward, downward and clockwise.
Winds moving around a low moves inward, upward
and counter-clockwise

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Isobars

Isobars connect points of equal pressure
Shows horizontal variations in pressure as well
as identifying high and low pressure

1000
998
L
996
992
17
Isobars

The more closely spaced the isobars, the stronger
the pressure gradient and thus the stronger the
wind

L
18

Isobars

Pressure gradient force starts air moving
Coriolis effect turns it right
These forces keep working until wind is
blowing parallel to the isobars
This is called geostrophic wind.

L
19
Moisture

As air is heated and cooled, water changes state
between vapor, liquid, and solid
This change of state results in an exchange of
heat (latent heat)

20
Moisture

Latent heat absorbed
Sublimation solid to gas
Melting solid to liquid
Evaporation liquid to gas

Latent heat released
Deposition gas to solid
Condensation gas to liquid
Freezing liquid to solid

21
Moisture

Latent heat absorbed
Latent heat released

22
Saturation

Air is limited in ability to contain moisture as
water vapor
Ability to hold moisture in vapor form is
dependent on temperature of the air
Warm air can hold more water vapor than cold air
When air reaches 100 capacity it is saturated

23
Saturation

When saturation is reached, any additional
moisture MAY condense to visible moisture, i.e..
water
Water is continuously changing states from liquid
to gas
When the air is warmer, there is a greater number
of molecules evaporating than condensing we have
a net evaporation
As air is cooled, the evaporation rate decreases
and condensation exceeds evaporation. These
sub-microscopic drops clump together into a cloud
drop.

24
Relative Humidity

Amount of water vapor present, compared to the
actual amount that air can hold
Expressed in percentage
Cold air at 0 degrees C that is 100 saturated
may only be 80 saturated if it is warmed to 15
degrees.

25
Relative Humidity

For this reason, the air becomes saturated more
quickly in winter while the conditions may still
be relatively dry compared to the summer.
When it is muggy, there is a lot of moisture in
the air making it feel wet.
Drier conditions tend to prevail in winter than
in summer.

26
Dewpoint

The temperature to which air must be cooled to
become saturated
When the dewpoint is reached, if condensation
nuclei are present, visible moisture may condense
out of the air into liquid drops which we see as
clouds or fog

27
Moisture, Temperature, and Stability

Stability- The tendency for a body to return to
its original condition following displacement.
With respect to the atmosphere, stability is the
tendency for a parcel of air to continue lifting
if it is provided an initial lifting force.
Lifting may be by mechanical, convective, or
frontal means.

28
Unstable Airmass

Cumuliform clouds
Showery precipitation
Rough air (turbulence)
Good visibility (except in blowing
obscuration)

29
Stable Airmass

Stratiform clouds fog
Continuous precipitation
Smooth air
Fair to poor visibility (in haze smoke)

30

Cloud Formation

Criteria for cloud characteristics
Moisture
Lifting action
Condensation nuclei
Type dependant upon stability

31
Methods Of Lifting

Convective
Surface heating
Mechanical
Frontal
Orographic
Low pressure

32
Convective Lifting

Cold air moving over or lying over a warm surface
will be warmed from below causing it to become
less stable
To find the cloud base, use the following
equation
air temperature - dewpoint
---------------------------------
2.5C or 4.4F

33
Orographic Lifting

Air flowing over mountains rises is cooled
When cooled below dewpoint, clouds form
Altitude that cloud bases form depends on
moisture content its dewpoint
Clouds may be below mountain tops or above them

34
Orographic Lifting Cont.

A lens-shaped cloud that forms as a cap over a
mountain is a lenticular cloud
It stays in place as air moves thru it even up to
50 kts or more
When an airstream flows over a mountain range a
stable layer is above, waves occur
Clouds may form in the crest of the waves while
roll clouds may form _at_ a lower altitude
These indicate strong turbulence exists

35
Clouds Formed by Turbulence Mixing

As air flows over surface, friction causes
variations in wind strength direction
Stronger the wind the rougher the surface, the
larger the eddies the stronger the mixing
Air in rising currents will cool if turbulence
extends high enough, it may cool to dewpoint
clouds could form
W/ turbulent mixing, stratiform clouds may form
over a large area

36
Cloud Families

Low
Middle
High
Clouds with extensive vertical development

37
Ten Basic Cloud Types

Stratus (ST)
Stratocumulus (SC)
Nimbostratus (NS)
Cumulonimbus (CB)
Cumulus (CU)

Altocumulus (AC)
Altostratus (AS)
Cirrocumulus (CC)
Cirrostratus (CS)
Cirrus (CI)

38
Broad Cloud Categories

Cumulus--heaped clouds associated with
instability at that level
Stratus--flat clouds associated with stability at
that level
Nimbus--dark clouds associated with rain

39
Cloud Types

Moist air that is unstable will continue rising,
forming cumulus-type clouds w/ vertical
development turbulence
Moist air that is stable will stop rising
stratus-type clouds w/ little vertical
development no turbulence
The type of cloud depends on the stability of the
air!

40
Low Clouds

Between the surface and 5,000 feet
Named with the prefix Strato, or nimbo
Stratus, Nimbostratus, Stratocumulus

41
Middle Clouds

Named with the prefix alto
Found between 5,000 and 18,000 feet
Examples
Altostratus
Altocumulus

42
High Clouds

Named with the prefix cirro
Found above 18,000 feet
Examples
Cirrostratus
Cirrocumulus

43
Clouds w/Extensive Vertical Development

Extend from below 5,000 feet to above 35,000 feet
Examples
Cumulonimbus
Towering cumulus

44
Definitions-Ceiling

Ceiling- The lowest layer of clouds or obscuring
phenomena classified as broken or overcast, but
not thin or partial

45
Fronts

Boundary between two different air-masses
When flying thru a front, there is a change in
wind direction, temperature, and pressure
When two masses of air of different temperatures
meet, the warmer/less dense air will flow over
the cooler air
Warmer air mass cools as it is forced upward
When reaches dewpoint, clouds form

46
Frontal Symbols

Cold Front
Warm Front
Occluded Front
Stationary Front
47
Cold-Dry Air
Cool-Moist
L
Warm-Moist Air
48
Fronts

The name given to a front describes the air
behind it
Since fronts will always involve a temperature
difference, there will always be warm air rising
in the proximity of a front

49
Warm Front

Warm air overriding cold or cool air
Stratiform cloud development
Steady precipitation
Little turbulence

Cool air
Warm air
50
Warm Front

The frontal air _at_ altitude is actually well ahead
of the frontal line
Rain could be falling up to 200 miles ahead of
the front
Rain falling into cooler air beneath the warm
front may cause precipitation induced fog or
freezing rain (depending on how cold the air is)

51
Temperature Inversion

Can occur near ground, on cold, clear nights when
surface loses heat making air adjacent to surface
warmer
Visibility can be a problem because there is no
upward convective movement to carry particles away

52
Temperature Inversion

Windshear - sudden, drastic shift in wind speed,
direction or both
This may exist _at_ top of the inversion if there
are strong winds aloft
T.I. may exist in warm fronts which can cause
freezing rain serious danger to the pilot

53
Signs of a Warm Front

As front passes, might see high cirrus clouds
followed by a lowering base of stratus type
clouds
Rain may be falling evaporating before it
reaches the ground (virga)
Rain may be continuous until front passes along
with fog

54
Signs of Warm Front Cont.

Pressure will fall continuously as front
approaches as it passes, either stop falling or
fall _at_ a lower rate
Temp. will rise as front moves over surface
Relative humidity will decrease b/c warm air
holds more moisture fog will dissipate
Wind direction will veer(clockwise change of
direction) as front passes

55
Cold Front

Cold air underrunning warm air
Cumuliform clouds
Showery precipitation
Turbulence
Thunderstorms common

56
Cold Front
Warm air
Cold air
57
Cold Front

Air that is forced to rise as front passes is
unstable you get cumuliform type clouds
TS, Squall lines, severe turbulence windshear
Windshear turbulence are possible _at_ airport _at_
or just after front passes

58
Signs of Cold Front

Pressure falls then rises after front has past
Cumuliform clouds
Sudden drop in temp lower dewpoint
Veering of wind direction, thus windshear

59
Occluded Front

Occurs when a cold front overtakes a warm front -
3 air masses involved
Warm air is completely pushed aloft
Weather characteristics of both types of fronts
An occlusion marks the diminishing of a low
pressure center (frontoloysis)

60
Occluded Front
Warm Air
Cool Air
Cold Air
61
Occluded Front

Cold front travels faster so overtakes warm front
Low pressure systemit is common for cold front
to occur in SW sector of a low warm front in E

62
Signs of Occluded Front

Clouds will be dependent on what the warm/cold
fronts have
Warm front could have stratus type cold front
could have cumuliform type
Stratus can hide the cumuliform clouds hide TS
(known as embedded TS)
Severe WX can occur in early part of occlusion
b/c unstable air is forced up (short)
Flight thru can be dangerous due to severe wx

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Categories of Icing

1. Structural
2. Induction

66
Structural Icing

Primarily caused by water droplets freezing on
the skin of the aircraft as it passes through a
cloud/precipitation.
The way the droplets freeze produce three
different icing types.
Clear
Rime
Mixed

67
Clear Icing

Large droplets that freeze slowly forming a clear
coating
Resembles ice cubes in freezer
Heaviest and most solid type of icing
Most dangerous
Found in cumiliform clouds

68
Rime Icing

When droplets are small and freeze immediately
air is trapped in the icing
The trapped air makes the icing opaque, or milky
Rougher surface, but lighter than clear ice
Easier to get rid of
Found in stratus clouds

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Mixed Icing

A combination of rime and clear
When snow or ice particles become trapped in
clear ice, very rough accumulations develop.

70
Induction Icing

Includes icing on intakes and in carburetors.
Mainly causes loss of engine power due to loss of
intake.
Induction ice occurs due to the same effects as
structural icing. Carburetor ice occurs due to
the decrease in temp from decrease in pressure
and latent heat of vaporization.

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Thunderstorm Hazards

Hail
Turbulence
Windshear
Lightning
Icing
Heavy precipitation
Tornadoes

73
Requirements for a Thunderstorm

Moisture
Instability
Lifting Mechanism
Fronts
Thermals
Orographic

74
Classic Thunderstorm Formation

Three stages of a thunderstorm
Cumulus development of thunderstorm
characterized by updrafts
Mature most sever phase characterized by
updrafts and downdrafts beginning of
precipitation at the surface
Dissipating thunderstorm dies out characterized
by downdrafts

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Fog Types