Download MET 200 Lecture 7 Cloud Forms Colorado`s “biblical” flood

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Transcript 
MET 200 Lecture 7
Cloud Forms
Cloud forms and what they tell us.
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Colorado’s “biblical” flood
2
Colorado’s “biblical” flood
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Boulder Co. Flood
Colorado’s “biblical” flood
230.6 mm (9.08 in)
Estimating the return interval of
the Boulder Flood
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Boulder Co. Flood
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Boulder Co. Flood
Rainfall amounts for the seven days ending at noon MDT on Friday, September
13, ranged from 5 to 10-plus inches across large swaths of the Colorado Front
Range, with similar amounts eastward into northwest Kansas.
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Boulder Co. Flood
Boulder Co. Flood
• Boulder’s previous record for wettest calendar day—4.80” (July 31,
1919)—was shattered.
• The single day of rain on Thursday was also nearly twice as much as
any other entire September has produced (5.50”, in 1940).
• The full week’s rainfall easily topped the 9.59” observed in May 1995,
Boulder’s wettest month up to now.
• This week’s precipitation also exceeded the 12.96” that fell in Boulder
during this entire year up to September 8. It put the city within
striking distance of wettest year on record (29.93”, set in 1995), with
only about 2” more needed by December 31 to break that mark.
Between 00Z Thursday 9/12 (6 PM Mountain Daylight Time on
Wednesday) and 00Z Friday 9/13, a total of 9.08” was measured at the
official Boulder site. From 6 PM Monday 9/9 through 6 PM Friday 9/13,
the grand total was a whopping 14.71”.
9
Cloud Stories
Previous Lecture: Cloud Formation
Clouds can tell us many things about our atmospheric
environment including
– Atmospheric stability
– Cloud microphysics, e.g., ice vs liquid
–
10
Ice
can survive a long time outside of a cloud boundary making the
cloud edges diffuse.
– Wind speed and direction at levels of the clouds
– Wind shear in precipitating clouds
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Cloud Formation
Mechanisms for Cooling the Air
(1) Lifting – most clouds form when air is lifted.
All clouds require 3 things
1.
Water vapor
a) Convergence – low press center – stratus
2.
Cloud Condensation nuclei (CCN)
b) Mountains – lifting by terrain
3.
Cooling - heat transfer out of air parcel or work
done by air molecules in parcel.
c) Fronts – lifting over denser air.
d) Warm air relative to surroundings
i) Fires, volcanoes – cumulus
ii) Latent heat
(2) Mixing – seeing your breath on cold day
(3) Contact – with cold surface – advection fog
(4) Radiation – ground fog
13
Cooling Increases Relative Humidity
14
Lecture 7
The saturation vapor pressure of water increases with temperature.
Therefore, if the amount of water in the air stays the same, but the
temperature drops, then the relative humidity increases.
Cloud Forms
Cloud forms and what they tell us.
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Cloud type summary
Cloud classification
Clouds are categorized by their height, appearance and
vertical development
– High Clouds - generally above 23,000 ft at middle
latitudes (>6 km)
•
Main types - Cirrus, Cirrostratus, Cirrocumulus
– Middle Clouds – 7,000-23,000 ft (2-6 km)
•
Main types – Altostratus, Altocumulus
– Low Clouds - below 7,000 ft (<2 km)
•
Main types – Stratus, stratocumulus, nimbostratus
– Vertically developed clouds (via convection)
•
Main types – Cumulus, Cumulonimbus
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Cirrus with Fog
High Clouds
High clouds
• White during the day
• Red/orange/yellow at
sunrise and sunset
– Cirrus
•
•
•
•
Made of ice crystals
Thin and wispy
Move SW to NE
Indicate fair weather
– Cirrocumulus
•
•
Made of supercooled water
droplets
Small, rounded white puffs
individually or in long rows (fish
scales; mackerel sky)
–
Cirrostratus
•
•
•
•
Thin and sheetlike
Sun and moon clearly visible
through them
Halo common - indicates ice
Often precede precipitation
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Cirrus
Cirrus
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Cirrus
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Cirrostratus with Halo
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Cirrostratus
Cirrocumulus
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Cirrocumulus
Cirrocumulus
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Contrail
Middle Clouds
•
Altostratus
– Gray, blue-gray
– Often covers entire sky
– Sun or moon may show
through dimly
•
•
Usually no shadows
Altocumulus
– <1 km thick
– mostly water drops, often
supercooled
– Gray, puffy
– Differences from cirrocumulus
•
•
Larger puffs
More dark/light contrast
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Altostratus
Altostratus
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Altostratus
Altocumulus
Altostratus Castellanus
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Altocumulus
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Alto Cumulus
Alto Cumulus Undulatus
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Low Clouds
•
Stratus
Stratus
– Uniform, gray
– Resembles fog that does not reach the
ground
– Usually no precipitation, but light mist/
drizzle possible
•
Stratocumulus
– Low lumpy clouds
– Breaks (usually) between cloud
elements
– Lower base and larger elements than
altostratus
•
Nimbostratus
– Dark gray
– Continuous light to moderate rain or
snow
– Evaporating rain below can form stratus
fractus
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Fog
Stratus/Fog
39
40
Nimbostratus
Stratocumulus from below
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Fractus
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Fractus
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Stratiform cloud layers
Stratiform
cloud layers
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Stratocumulus
Vertically
developed clouds
•
Cumulus
– Puffy “cotton”
– Flat base, rounded top
– More space between cloud
elements than stratocumulus
•
Cumulonimbus
– Thunderstorm cloud
– Very tall, often reaching
tropopause
– Individual or grouped
– Large energy release from water
vapor condensation
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What conditions support taller cumulus
development ?
•
A less stable atmospheric (steeper lapse rate) profile
permits greater vertical motion
•
Lots of low-level moisture permits latent heating to
warm parcel, accelerating it upward
To forecast changing weather you have to predict how
the environmental lapse rate will change in time.
•
Fair Weather Cumulus
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Fair Weather Cumulus
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Fair Weather Cumulus
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Cumulus
Cumulus
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Cumulus Castelanus
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Cumulonimbus
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Cumulus
Congestus
Cumulonimbus
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Cumulonimbus and Anvil
Cumulonimbus
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Cumulonimbus with Anvil
Cumulonimbus with Anvil
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Tornado Funnel Cloud
Cumulonimbus with Anvil
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Mamatus
Mamatus
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Lenticular clouds
Virga
•
Stable air flowing over a
mountain range often forms a
series of waves
– Think of water waves formed
downstream of a submerged
boulder
•
•
•
Air cools during rising portion
of wave and warms during
descent
Clouds form near peaks of
waves
A large swirling eddy forms
beneath the lee wave cloud
– Observed in formation of rotor
cloud
– Very dangerous for aircraft
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68
Mountain Wave or Lenticular Clouds
Mountain Wave or Lenticular Cloud
69
Mountain Wave and Cumulus Clouds
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Mountain Wave or Lenticular Cloud
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Mountain Wave or Lenticular Cloud
Mountain Wave or Lenticular Cloud
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Kelvin-Helmholtz Instability
Summary of Cloud Types
Clouds are categorized by their height, appearance, and
vertical development
– High Clouds - generally above 16,000 ft at middle
latitudes (>6 km)
•
Main types - Cirrus, Cirrostratus, Cirrocumulus
– Middle Clouds – 7,000-23,000 feet (2-6 km)
•
Main types – Altostratus, Altocumulus
– Low Clouds - below 7,000 ft (<2 km)
•
Main types – Stratus, stratocumulus, nimbostratus
– Vertically developed clouds (via convection)
•
75
Main types – Cumulus, Cumulonimbus
76
Questions?
Smoke ring blown by
the active vent at the
summit of Mt Etna,
Sicily, Italy.
77
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