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Cloud Development and Precipitation

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Title: Cloud Development and Precipitation


1
Chapter 5
  • Cloud Development and Precipitation

2
Equlibrium
3
Atmospheric Stability
  • Air is in stable equilibrium when after being
    lifted or lowered, it tends to return to its
    original position resists upward and downward
    air motions.
  • Air Parcel- balloon like blob of air
  • As air rises its pressure decreases and it
    expands and cools
  • As air sinks pressure increases and it is
    compressed and warms

4
Adiabatic Process
  • If an air parcel expands and cools, or compresses
    and warms, with no interchange of heat with its
    outside surroundings the situation is called an
    adiabatic process.
  • Dry Adiabatic lapse rate 10C per 1km or 5.5F
    per 1,000 feet. (applies to unsaturated air)
  • Moist Adiabatic lapse rate - 6C per 1km or
    3.3F per 1,000 ft (applies to saturated air).
    Not a constant. Varies greatly. This number is
    used to keep things simple.

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6
Determining Stability
  • Determine stability by comparing the temperature
    of a rising parcel to that of its surrounding
    environment.
  • If it is colder than its environment it will be
    more dense (heavier) and tend to sink back to its
    original level. This is called stable air
    because the parcel resists moving away from its
    original position.
  • If the parcel is warmer (less dense) than its
    environment, it will continue to rise until it
    reaches the same temperature of its environment.
    This is called unstable air because the parcel
    continues to move away from its original position.

7
Stable Air
  • Environmental Lapse Rate rate at which the air
    temperature of the environment would be changing
    if we were to climb upward into the atmosphere.
  • Absolutely stable the lifted parcel of air is
    colder and heavier than air surrounding it (its
    environment).
  • Stable air strongly resists upward vertical
    motion, it will, if forced to rise, tend to
    spread out horizontally.
  • Atmosphere is stable when the environmental lapse
    rate is small when there is relatively small
    difference in temperature between the surface air
    and the air aloft.
  • The atmosphere stabilizes as the air aloft warms
    or as the air near the surface cools.

8
Stable Air
Dry air example
9
Stable Air
Saturated air example
10
Cold surface air, on this morning, produces a
stable atmosphere that inhibits vertical air
motions and allows fog and haze to linger close
to the ground.
11
Unstable Air
  • Atmosphere is unstable when the air temperature
    decreases rapidly as we move up into the
    atmosphere.
  • Absolutely unstable atmosphere when considering
    both moist and dry air the rising air is warmer
    than the environmental air around them.
  • Atmosphere becomes unstable when
  • Daytime solar heating of the surface
  • An influx of warm air brought in by the wind near
    the surface
  • Air moving over a warm surface

12
Unstable Air
-
Dry air example
13
Unstable air. The forest fire heats the air,
causing instability near the surface. Warm,
less-dense air (and smoke) bubbles upward,
expanding and cooling as it rises.
14
Conditionally unstable air.The atmosphere is
stable if the rising air is unsaturated...
15
Conditionally Unstable Air
  • Suppose an unsaturated, but humid air parcel is
    forced to rise from the surface.
  • As it rises, it expands and cools at the dry
    adiabatic rate until it cools to its dew point.
  • The elevation above the surface where the air is
    saturated and clouds form is called the
    condensation level.
  • Above the condensation level rising air cools at
    the moist adiabatic rate.
  • Conditionally unstable atmosphere the condition
    for stability being where (if anywhere) the
    rising air becomes saturated. If unsaturated
    stable air is lifted to a level where it becomes
    saturated, instability may result.
  • (See text figure 5.7 on page 116)

16
When the environmental lapse rate is greater than
the dry adiabatic rate, the atmosphere is
absolutely unstable. When the environmental lapse
rate is less than the moist adiabatic rate, the
atmosphere is absolutely stable. And when the
environmental lapse rate lies between the dry
adiabatic rate and the moist adiabatic rate
(shaded green area), the atmosphere is
conditionally unstable
17
Cumulus clouds developing into thunderstorms in a
conditionally unstable atmosphere over the Great
Plains. (Note the anvil in the distance)
18
Level of free convection
  • The level of the atmosphere where an air parcel,
    after being lifted, becomes warmer than the
    environment surrounding it. This air can then
    rise on its own and the atmosphere is unstable.

19
Convection and Clouds
  • Some areas of the earth surface absorb more
    sunlight than others, and thus heat up more
    quickly. (Discuss examples)
  • Thermal a hot bubble of air that breaks away
    from the surface and rises, expanding and cooling
    as it ascends.
  • As a thermal rises, it mixes with cooler, drier
    air aloft and gradually looses its identity.
    But, if it cools to its saturation point, the
    moisture inside will condense and the thermal
    becomes a cumulus cloud.

20
Thermals forming cumulus clouds
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23
Four primary means of convection(ways to form
clouds)
  • Surface heating (thermals)
  • Topographic (forced) lifting
  • Convergence at the surface
  • Frontal (forced) lifting

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28
Topography and Clouds
  • Orographic lift forced lifting along a
    topographic barrier (mountains)
  • Rain Shadow the region on the leeward side of a
    mountain, where precipitation is noticeably low
    and the air if often drier
  • Lenticular clouds (mountain wave clouds) form
    on the lee side of mountains. Resemble waves
    that form in a river downstream from a large
    boulder.
  • Rotor clouds Form beneath lenticular clouds.
    In the large swirling eddy associated with the
    mountain wave, the rising part may cool and
    condense enough to form a cloud.

29
Orographic lift, cloud development, and the
formation of a rain shadow
30
The air's stability greatly influences the growth
of cumulus clouds.
31
The air's stability greatly influences the growth
of cumulus clouds.
32
The air's stability greatly influences the growth
of cumulus clouds.
33
The formation of lenticular clouds
34
Lenticular clouds (mountain wave clouds) over
Mount Shasta in Northern California
35
Collision and Coalescence Process
  • In clouds with tops warmer than -15oC collisions
    between droplets can play a significant role in
    producing precipitation.
  • Large drops form on large condensation nuclei or
    through random collisions of droplets.
  • As the droplets fall (larger drops fall faster
    than smaller drops) the larger droplets overtake
    and collide with smaller drops in their path.
  • The merging of cloud droplets by collision is
    called coalescence. (Note collision does not
    always guarantee coalescence)

36
Relative sizes of raindrops, cloud droplets and
condensation nuclei
37
Collision and Coalescence
  • In a warm cloud composed only of small cloud
    droplets of uniform size, the droplets are less
    likely to collide as they all fall very slowly at
    about the same speed. Those droplets that do
    collide, frequently do not coalesce because of
    the strong surface tension that holds together
    each tiny droplet.

38
Collision and Coalescence
  • In a cloud composed of different size droplets,
    larger droplets fall faster than smaller
    droplets. Although some tiny droplets are swept
    aside, some collect on the larger droplet's
    forward edge, while others (captured in the wake
    of the larger droplet) coalesce on the droplet's
    backside.

39
Warm Clouds
  • A cloud droplet rising then falling through a
    warm cumulus cloud can grow by collision and
    coalescence, and emerge from the cloud as a large
    raindrop.

40
Factors in cloud formation and raindrop production
  • The clouds liquid water content
  • The range of droplets sizes
  • The cloud thickness
  • (heaviest precipitation occurs in those clouds
    with most vertical development)
  • The updrafts of the cloud
  • The electric charge of the droplets and the
    electric field in the cloud

41
Ice Crystal (Bergeron) Process
  • Process of rain formation proposes that both ice
    crystals and liquid cloud droplets must co-exist
    in clouds at temperatures below freezing.
  • This process is extremely important to rain
    formation in the middle and high latitudes where
    cloud tops extend above the freezing level (cold
    clouds)

42
Supercooled water
Collison coalescence occurs here
The distribution of ice and water in a
cumulonimbus cloud.
43
Ice Nuclei
  • Ice-forming particles that exist in subfreezing
    air
  • Small amount of these available in atmosphere
  • Clay materials, bacteria in decaying plant leaf
    material and other ice crystals

44
Saturation Vapor PressureIce vs Water
  • In a saturated environment, the water droplet and
    the ice crystal are in equilibrium, as the number
    of molecules leaving the surface of each droplet
    and ice crystal equals the number returning. The
    greater number of vapor molecules above the
    liquid indicates, however, that the saturation
    vapor pressure over water is greater than it is
    over ice.

45
Ice Crystal (Bergeron) Process
  • The ice-crystal process. The greater number of
    water vapor molecules around the liquid droplets
    causes water molecules to diffuse from the liquid
    drops toward the ice crystals. The ice crystals
    absorb the water vapor and grow larger, while the
    water droplets grow smaller.
  • It takes more vapor molecules to saturate the air
    directly above the water droplet than it does to
    saturate the air directly above the crystal.
  • Ice crystals grow at the expense of the
    surrounding water droplets.

46
Accretion
  • In some clouds ice crystals might collide with
    supercooled liquid droplets. Upon contact, the
    liquid droplets freeze into ice and stick to the
    ice crystal accretion or riming.
  • The icy matter that forms is called graupel or
    snow pellets.

47
Secondary Ice particles
  • In colder clouds the ice crystals may collide
    with other ice crystals and fracture into smaller
    ice particles or tiny seeds which freeze hundreds
    of supercooled droplets on contact.

48
Aggregation
  • As the crystals fall, they may collide and stick
    to one another forming an aggregate of crystals
    called a snowflake.

49
Cloud Seeding
  • To inject (or seed) a cloud with small particles
    that will act as nuclei, so that the cloud
    particles will grow large enough to fall to the
    surface as precipitation.
  • First experiments in late 1940s using dry ice.
  • Silver Iodide is also used today because its
    structure is similar to that of ice crystals.
  • Natural seeding cirriform clouds lie directly
    above a lower cloud deck, ice crystals descend
    into lower clouds.

50
Natural seeding by cirrus clouds may form bands
of precipitation downwind of a mountain chain.
51
Precipitation Types
  • Rain
  • Drizzle
  • Virga
  • Showers
  • Snow
  • Snow grains and snow pellets
  • Fallstreaks
  • Flurries
  • Squalls
  • Blizzard
  • Sleet and Freezing Rain
  • Hail

52
Rain
  • Falling drop of liquid water that has a diameter
    equal to or greater than .5 mm (.02 in)
  • Drizzle drops too small to qualify as rain
  • Virga raindrops that fall from a cloud but
    evaporate before reaching the ground
  • Shower intermittent precipitation from a
    cumuliform cloud usually of short duration but
    often heavy intensity
  • Acid rain rain that is mixed with gaseous
    pollutants (sulfur, nitrogen) and becomes acidic

53
Virga
54
Snow
  • A solid form of precipitation composed of ice
    crystals in complex hexagonal form
  • Much of the precipitation reaching the ground
    actually begins as snow.
  • Fallstreaks Ice crystals and snowflakes falling
    from high cirrus clouds. Behave similar to Virga
    fall into drier air and disappear before
    reaching the ground. Change from ice to vapor
    (sublimation)
  • Flurries light snow showers that fall
    intermittently for short durations. Light
    accumulation.
  • Squall more intense snow shower, brief but
    heavy snowfall.
  • Blizzard severe weather condition. Low
    temperatures and strong winds (greater than 30
    kts) bearing a great amount of falling or blowing
    snow.

55
Fallstreaks
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Dendrite snowflakes most common form of snow.
58
Sleet and Freezing Rain
  • Sleet type of precipitation consisting of
    transparent pellets of ice 5 mm or less in
    diameter (ice pellets)
  • Freezing Rain/drizzle rain/drizzle that falls
    in liquid form and then freezes upon striking a
    cold object or ground. (glaze)
  • Rime an accumulation of white or milky granular
    ice. Formed when supercooled cloud or fog
    droplets strike an object whose temperature is
    below freezing.

59
Sleet forms when a partially melted snowflake or
a cold raindrop freezes into a pellet of ice
before reaching the ground.
60
Rime -An accumulation of rime forms on tree
branches as supercooled fog droplets freeze on
contact in the below-freezing air.
61
A heavy coating of freezing rain during this ice
storm caused tree limbs to break and power lines
to sag.
62
Vertical temperature profiles (solid red line)
associated with snow.
63
Vertical temperature profiles (solid red line)
associated with sleet.
64
Vertical temperature profiles (solid red line)
associated with freezing rain.
65
Vertical temperature profiles (solid red line)
associated with rain.
66
Hail
  • Hailstones are pieces of ice either transparent
    or partially opaque, ranging in size from that of
    a small pea to that of a golf ball or larger.
  • Produced in cumulonimbus clouds when graupel,
    large frozen raindrops or just about anything
    (insects) act as embryos that grow by
    accumulating supercooled liquid water droplets.
  • Golf ball size hail has remained aloft for
    between 5 and 10 minutes.

67
Hailstones
  • Hailstones begin as embryos (usually ice
    particles) that remain suspended in the cloud by
    violent updrafts. When the updrafts are tilted,
    the ice particles are swept horizontally through
    the cloud, producing the optimal trajectory for
    hailstone growth. Along their path, the ice
    particles collide with supercooled liquid
    droplets, which freeze on contact. The ice
    particles eventually grow large enough and heavy
    enough to fall toward the ground as hailstones.
     

68
The accumulation of small hail after a
thunderstorm. The hail formed as supercooled
cloud droplets collected on ice particles called
graupel inside a cumulonimbus cloud.
69
The giant Coffeyville hailstone first cut then
photographed under regular light... September
1970 weighed 1.67 lbs.
70
Measuring Precipitation
  • Rain gauge instrument used to collect and
    measure rainfall.
  • Trace an amount of precipitation less than .01
    in
  • Snow depth determined by measuring in three or
    more representative areas and taking an average.
  • Water equivalent generally about 10 inches of
    snow will melt down to about 1 inch of water.
    Varies greatly and depends on texture and packing
    of snow.

71
Standard Rain Gauge
  • A nonrecording rain gauge with an 8 inch diameter
    collector funnel and a tube that amplifies
    rainfall by ten.

72
Tipping Bucket Rain Gauge
  • The tipping bucket rain gauge. Each time the
    bucket fills with one-hundredth of an inch of
    rain, it tips, sending an electric signal to the
    remote recorder.

73
Doppler Radar
  • Radar radio detection and ranging
  • Used to examine the inside of clouds
  • Doppler Radar a radar that determines the
    velocity of falling precipitation either toward
    or away from the radar unit by taking into
    account the Doppler shift
  • Doppler shift (effect) the change of frequency of
    waves that occurs when the emitter or the
    observer is moving toward or away from the other

74
Doppler radar display showing precipitation
intensity over Oklahoma for April 24, 1999. The
numbers under the letters DBZ represent the
logarithmic scale for measuring the size and
volume of precipitation particles
75
Doppler radar display showing 1-hour rainfall
amounts over Oklahoma for April 24, 1999.
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