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1
G109:
9. Clouds and Precipitation
9. C LOUDS
Reading Assignment:
• A&B:
Ch. 6,7 (p. 182-221)
Recall
• Condensation: water vapor (gas) ⇒ liquid
May lead to formation of dew, fog, cloud etc
Different but all require saturation
• Saturation occurs when either:
o Water vapor is added to the air
o Air is cooled to its Tdew - most common
Cooling
1. Radiation cooling - during evening hours
o dew, fog
2. When air lifts - Most common
o cooled adiabatically (DALR if unsaturated)
o If parcel rises high enough - cool sufficiently condensation level
o Above this point air continue to rise but now at SALR
o SALR < DALR ⇒ does not cool as rapidly
Height
T
2
G109:
9. Clouds and Precipitation
Different types of clouds form depending on the stability
Recall : stability - air tendency to mix vertically
1. Unstable - air tendency to rise
o Clouds towering
o Heavy precipitation
o Cumulus type
2. Stable - air tendency to sink - resists upward movement
o Air forced aloft by other means e.g. front, mountains
o Clouds widespread
o Little vertical thickness compared to horizontal
o Precipitation, if any, light to moderate
o Overcast
o Stratus type
Cloud types
4 basic categories
1. Cumulus → heaping, vertical development
2. Stratus
→ layered
3. Cirrus
→ curl of hair, thin wispy ice clouds
4. Nimbus
→ rain producing
http://ww2010.atmos.uiuc.edu/(Gh)/guides/mtr/cld/cldtyp/home.rxml
Height:
1. High
> 6000 m (ice)
2. Middle
2000- 6000 m (water droplets & ice)
3. Low
<2000 m (water droplets)
4. Clouds of vertical development
base low extend to high altitudes (>6000+ m)
Unstable - powerful vertical acceleration
3
G109:
9. Clouds and Precipitation
Cumulonimbus—most violent storms-- can extend the
entire depth of troposphere…
Cloud Formation
• Condensation (gas ⇒ liquid)
• Air must be saturated - cooled to Tdew or water added
• Must be a surface on to which water condenses
o Surface - in the atmosphere: Cloud Condensation
Nuclei (CCN or CN)
o If CCN are absent can have > 100% RH i.e. doesn't
condense
o CCN - microscopic dust, smoke, salt particles
ƒ Normally large numbers in the atmosphere
ƒ Salt particles - hygroscopic, they freely absorb
water
o When condensation takes place
ƒ initial growth of cloud droplets very rapid
ƒ diminishes quickly because H2O availability ⇓
ƒ Even in very moist air - growth of these cloud
droplets by additional moisture is slow
Clouds consist of billions of tiny droplets
- so minute they remain suspended in the air
4
G109:
9. Clouds and Precipitation
Takes about 1 million cloud droplets to form 1 rain drop
⇒ Condensation by itself is not responsible for formation of
rain
Cloud droplets < 20 µm
o Small size ⇒ fall very slowly
o Takes 48 h to fall 1000 m - never occur ⇒ evaporate
Raindrop - large enough to reach ground i.e. survive
Formation of Precipitation
Two mechanisms
• Bergeron
• Collision - coalescence
Bergeron - cold cloud process
Two properties of water
1) Pure water doesn't freeze at 0°C.
Pure water suspended in air doesn't freeze until -40°C
5
G109:
9. Clouds and Precipitation
Supercooled - liquid water < 0°C
Will freeze if:
a) agitated sufficiently
b) come into contact with solid particles with
ice/crystalline structure
• Freezing Nuclei (FN) - sparse in the atmosphere
• Don't generally become active until T<-10°C
0- -10°C
-10 - 20°C
<-20°C
Clouds primarily supercooled H20
Liquid and ice crystals co-exist
Clouds generally composed entirely of ice crystals
6
G109:
9. Clouds and Precipitation
2) Saturation vapor pressure (es)
same T
es ice < es water
solid
liquid
easier to lose molecules
ice crystals grow at the expense of liquid water
Ice crystals grow
Fall….collied with supercooled droplets
Break…form more FN… grow….snow
Lifted by vertical ascent of the air
Use this knowledge in cloud seeding (Ag I)
7
G109:
9. Clouds and Precipitation
Collision - Coalescence - warm cloud > 0°C
o Giant condensation nuclei
o Hygroscopic particles - sea salt
o Larger particles fall faster - collide with
smaller (slower) particles
o May coalesce
o Millions of collisions ⇒ produces
something large enough to survive to
the surface without completely
evaporating
o Need clouds with great vertical extent
o Need abundant moisture
8
G109:
9. Clouds and Precipitation
o Raindrops may break up if
ƒ Large size (max ≈ 5 mm)
when falling 30 km h-1
ƒ Surface tension - holds
the drop together
• Surpassed by the
drag imposed by the
air
Forms of precipitation*******
Liquid or solid dependent
• on formation process
• environment between bottom of cloud and surface
Snow
• has not melted - still crystals
• form depends history: T, humidity
Sleet
• small clear translucent particles of ice
9
G109:
9. Clouds and Precipitation
• melts, then freezes in the air above the surface
• no larger than the rain drops formed
Freezing Rain (glaze)
• Vertical T similar to that for sleet BUT subfreezing air near
the ground is not thick enough to allow raindrops to freeze
• Rain becomes supercooled
• Freezes when collides with solid objects
10
G109:
9. Clouds and Precipitation
Hail
• Concentric shells of different densities and degress of
opaqueness
• Diameter 1 to > 10 cm
• Cumulonimbus clouds
o vertical extent
o strong updrafts
o abundant supply of supercooled H20
o length of path through the cloud
11
G109:
9. Clouds and Precipitation
Fog
• Visibility < 1 km
• Air wet with millions of water droplets
• Formation and location different to cloud
• Formation = Used to distinguish types
1. Radiation or Ground Fog
Cause: radiative cooling
• Best on clear nights with shallow layer of moist air overlain
by drier air
• Ground cools rapidly - moist doesn't absorb much L↑
o Surface Inversion (warm air over cool air)
o Moist lower layers quickly become saturated
⇒ Fog forms
• Longer the night - longer the time of cooling
12
G109:
9. Clouds and Precipitation
⇒ greater the likelihood of fog
• Radiation fog - most common late fall/winter
• Slight wind < 2.5 m s-1 promotes fog development brings
more air into contacts with the ground
• Strong wind - prevents radiation fog from forming mixes
air near the surface with drier air above
• Valley bottom - cool air drain down, rivers - moist air
2. Advection Fog
Cause: warm moist air moves over a cold surface
Surface has to be sufficiently cool to reduce the T to Tdew
• Involves movement of air
• Surface H20 near the coast is colder than surface water
offshore
o San Francisco - summer breeze Golden gate bridge
13
G109:
9. Clouds and Precipitation
3. Upslope Fog
Cause: Moist air flows up an elevated plain, hill
Air gradually rises, expands, cools
If sufficient ⇒fog
4. Evaporation Fog
Cause: Water added to air by evaporation
e.g. breath out on a cold day
Steam Fog - above a heated swimming pool
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