1. Chapter 5 - Title
2. Contents stability
cloud development
precipitation
3. Clouds Formation releases heat
Reflect, scatter, absorb IR radiation
Produce precipitation
Visually indicate the stability of the atmosphere
4. Questions 1. How and why do clouds form on some days and not on others?
2. Why does the atmosphere sometimes produce stratus clouds (thin layered) while other times we get cumulus, or cumulonimbus clouds to form?
The answer is largely related to the concept of atmospheric stability...
The answer is largely related to the concept of atmospheric stability...
The answer is largely related to the concept of atmospheric stability...
5. Cloud Development - Stable Environment Consider this simple situation of a marble in the bottom of a bowl
If you push the marble up the side of the bowl, what happens?
Stable air (parcel) - vertical motion is inhibited
if clouds form, they will be shallow, layered clouds e.g. stratus Sisyphus = A cruel king of Corinth condemned forever to roll a huge stone up a hill in Hades only to have it roll down again on nearing the top.
�[Latin Sisyphus, from Greek Sisuphos.] Sisyphus = A cruel king of Corinth condemned forever to roll a huge stone up a hill in Hades only to have it roll down again on nearing the top.
6. Cloud Development - Unstable Environment If the marble is on the top of the bowl and you give it a little push, what happens?
This is an unstable situation
Unstable air (parcel) - vertical motion occurs
commonly produces cummulus, cumulonimbus clouds
So, the question becomes,
how does one determine
the stability of the atmosphere?
7. Determining Stability Compare temperature (Tp) of a rising air parcel to that of its surroundings (Te)
Tp > Te : If rising air is warmer and less dense than the surrounding air, it will _____ until it reaches the same T as its surroundings.
Tp < Te : If rising air is colder it will be more dense than the surrounding air and _____ back to the original level.
Tp = Te : What happens?
RISE
SINKRISE
SINK
9. As a parcel of air rises, it cools, but at what rate?
rate of temperature change with height is called the�lapse rate. Units of lapse rate are °C /km
Let's first consider an unsaturated parcel of air
unsaturated parcels cool at a rate of 10°C /km - this is called the dry adiabatic lapse rate
If the surface temperature is 40°C What will be a parcel's temperature at 1 km?
What will be a parcel's temperature at 2 km?
At 1 km, 30 °C
At 2 km, 20 °CAt 1 km, 30 °C
At 2 km, 20 °C
10. Moist Adiabatic Lapse Rate (MALR) Moist Adiabatic Lapse Rate (MALR) = less
If air cools to T = TDP, RH = 100%
Cloud forms and heat is released
Latent heat added due to condensation offsets cooling due to expansion
Air cools at a lesser rate (6°C / km)
What will be a parcel's temperature at 3 km? �(note: its now cooling at MALR)�
What will be a parcel's temperature at 4 km?
20 – 6 = 14 °C
14 – 6 = 8 °C
20 – 6 = 14 °C
14 – 6 = 8 °C
11. Absolutely Stable Air Normally, air T decreases with height
Environmental Lapse Rate (ELR)
Radiosonde ELR = 4 °C/km (example)
Stable if rising parcel cools more rapidly with height than surrounding environmental T.
Always colder than surroundings
12. Absolutely Stable Air
13. Question How would you characterize the stability of an inversion layer?
14. Inversion Layer They are absolutely stable�DALR > MALR > ELR
Q: How do you form stable �layers in the atmosphere?
How do we make the ELR�turn to the right?
15. Formation of Stable Layers Air aloft warms
Warm advection
Sinking air (subsidence)
surface cools
Nighttime radiational cooling
Cold air moving in �at low levels
Warm air moving over �a cold surface�(cold frontal passage)
16. Formation of Stable Layers Stable air strongly resists upward motion
If clouds form in stable air they spread horizontally
e.g. cirrostratus, altostratus, nimbostratus, stratus have flat tops and bases
17. Unstable Air Unstable if environmental air Temperature decreases with height more rapidly than a rising air parcel cools
The rising parcel will become warmer than its environment and will rise
18. Unstable Air
19. Conditional Stability The unsaturated parcel will be cooler than then environment and will sink back to the ground
The saturated parcel will be warmer than the environment and will continue to rise
This is an example of conditional instability
What is the condition? Whether or not the parcel is saturated.Whether or not the parcel is saturated.
20. Conditionally Unstable Air
21. Questions What causes the atmosphere to become more unstable?
What causes air to rise so that clouds can form? ELR must become greater than DALR and MALR.ELR must become greater than DALR and MALR.
22. Formation of Unstable Layers Air T drops rapidly with height
ELR steepens
1. Cooling of air aloft
Winds bring in cold air
Clouds emit IR to space�
2. Warming of the surface
Daytime surface heating
Influx of warm air by wind
Air moving over a warm surface
23. Formation of Unstable Layers 3. Warm air moving in at low levels
This often occurs ahead of a cold front
4. Cold air moving over warm surface
What is an example of this?
Example over Lake Michigan Lake-Effect Snow.Lake-Effect Snow.
24. Stability Summary Clouds with rapidly rising air, especially cumulus congestus and cumulonimbus, indicate unstable conditions
Stratus clouds indicate stable conditions
25. Review The air temperature in a rising parcel of unsaturated air decreases at the dry adiabatic rate, whereas the air temperature in a rising parcel of saturated air decreases at the moist adiabatic rate
The dry adiabatic and moist adiabatic rate of cooling are different due to the fact that _______ ______ is released in a rising parcel of saturated air
In a stable atmosphere, a lifted parcel of air will be colder (heavier) than the air surrounding it. Because of this fact, the lifted parcel will tend to sink back to its original position
In an unstable atmosphere, a lifted parcel of air will be warmer (lighter) than the air surrounding it, and thus will continue to rise upward, away from its original position
The atmosphere becomes more stable (stabilizes) as the surface air _______, the air aloft _______, or a layer of air sinks (subsides) over a vast area
The atmosphere becomes more unstable (destabilizes) as the surface air ______, the air aloft ______, or a layer of air is lifted
Layered clouds tend to form in a stable atmosphere whereas cumuliform clouds tend to form in a conditionally unstable atmosphere Latent heat.
Cools, warms.
Warms, cools.
Latent heat.
Cools, warms.
Warms, cools.
26. Cloud Development and Stability Stages:
Thermals breaks from surface and ‘lifts’
Expands and cools on lifting
Cools to saturation point
Moisture condenses
Visible as cloud
Can occur in 4 different ways:
27. Cloud Formation Mechanisms (c) And (d) will be discussed later.(c) And (d) will be discussed later.
28. (a) Convection The vertical extent of the cloud is largely determined by the stability of the environment...
29. Stability and Cumulus Clouds In an absolutely stable, environment, no clouds will likely form
In a shallow conditionally unstable or absolutely unstable environment, one may expect clouds to develop, but their vertical growth will be limited...
30. Stability and Cumulus Clouds Stable above the cumulus
Does not rise ‘fair weather Cu’ or cumulus humilis
Unstable above the cumulus
Towering cumulus congestus, then cumulonimbus
31. Questions Are the bases on convective clouds generally higher during the day or the night? Explain.
2. For least polluted conditions, what would be the best time of day for a farmer to burn agricultural debris? 1. At night, because of lower temperatures at the surface, the difference between the dew point and the surface temperature is smaller than during the day. Therefore an air parcel need not rise so high for it to become saturated. If convection is able to occur, the cloud bases will therefore be lower at night.
2. For least pollution the farmer should burn his debris at that time of day most favorable for convection, i.e., at that time when the atmosphere is least stable. That tends to be the case at the warmest time of day. Thus the farmer should burn his debris at the warmest time of day, probably from mid to late afternoon.
1. At night, because of lower temperatures at the surface, the difference between the dew point and the surface temperature is smaller than during the day. Therefore an air parcel need not rise so high for it to become saturated. If convection is able to occur, the cloud bases will therefore be lower at night.
2. For least pollution the farmer should burn his debris at that time of day most favorable for convection, i.e., at that time when the atmosphere is least stable. That tends to be the case at the warmest time of day. Thus the farmer should burn his debris at the warmest time of day, probably from mid to late afternoon.
32. (b) Topography Orographic uplift – forced lifting along a barrier
Forced lifting produces cooling
Cloud on windward side
Downwind side is warmer and drier why? Heat released during condensation on windward side.
Water vapor condensed to form cloud on the windward side = rain shadowHeat released during condensation on windward side.
Water vapor condensed to form cloud on the windward side = rain shadow
33. Topography
34. (c) Convergence If air converges to a given location near the surface:
it can't "pile up" at that point
it can't go downward, the ground is there
it must go up!
Common at the center of an extra-tropical cyclone �(L pressure system)
35. (d) Frontal Lifting If air is lifted into a stable layer:
stratus or nimbostratus clouds are often the result �(common along warm fronts)
If air is lifted into a conditionally unstable layer:
cumulus or cumulonimbus are often the result �(common along cold fronts)
36. Precipitation Q: How does precipitation form?
not all clouds produce precipitation, why?
Q: What determines the type of precipitation?
37. Rain Drops, Cloud Droplets, and CCN Formation of raindrops from cloud droplets is complex
Cloud droplet: 0.02 mm
Rain droplet: 2 mm
Radius is 100 x greater, �so volume is 100 x 100 x 100 = 1x 106 times greater CCN = Cloud Condensation Nuclei.CCN = Cloud Condensation Nuclei.
38. Precipitation Processes Condensation nuclei play a role
far too slow
1 million cloud drops to 1 raindrop must be another process…
39. Rain in Clouds Without Ice (Warm Clouds) Collision and coalescence (sticky water)
Most important factor is liquid water content
Thickness of cloud
Updrafts
Electrical charge (+/-) (Smaller drops tend to bounce off one another) http://vortex.plymouth.edu/precip/terminalvelocity.htmlhttp://vortex.plymouth.edu/precip/terminalvelocity.html
40. Rain in Clouds Without Ice Explains why thin stratus only produces drizzle
Towering cumulus with rapidly rising air can produce heavy showers
41. Questions 1. Why is a warm, tropical cumulus cloud more likely to produce precipitation than a cold, stratus cloud?
2. Clouds that form over water are usually more efficient in producing precipitation than clouds that form over land. Why? 1. Thicker! More chances for collisoin and coalescense.
2. Contain more water vapor.1. Thicker! More chances for collisoin and coalescense.
2. Contain more water vapor.
42. Rain in Clouds With Ice (Cold Clouds)
At temperatures < freezing ice crystals coexist with liquid drops
No. cloud droplets > No. ice crystals
Liquid water exists as so called ‘supercooled’ water �(-40°C < Temp < 0°C)
only ice is found at altitudes above -40°C
Why?
Smaller the amount of pure water, lower the freezing point (less than 0 şC)
Few ice-forming nuclei (minerals, bacteria, leaf, ice crystals)
Supercooled water is sometimes referred to as subcooled water.Supercooled water is sometimes referred to as subcooled water.
43. Supercooled Water Exp.
44. Results: Homogeneous Freezing Pure water drops do NOT freeze at 0°C
it needs to be colder
Larger water drops will freeze at warmer temperatures than smaller drops
Smaller water drops require colder temperatures to freeze
Hence, you will find more smaller drops than larger drops higher in the cloud
45. Rain in Clouds With Ice (Cold Clouds) Neither the liquid cloud drops or solid ice particles are large enough to fall as precipitation
Given a mixed cloud containing water and ice, which type of particle (ice v.s. water) will grow more quickly and why?
46. Bergeron Process (the 3 Phase process) Bergeron or Ice-Crystal Process
Supercooled liquid droplets surround each ice crystal
Air is saturated, both are in equilibrium
More water vapor molecules around liquid
Escape from liquid surface easier
Saturation V.P. above water droplet is greater than the ice
Water vapor molecules diffuse from droplet to ice crystal
Ice crystals grow larger at the expense of the water droplets
Also
Accretion
Aggregation
http://vortex.plymouth.edu/precip/precip2aa.htmlhttp://vortex.plymouth.edu/precip/precip2aa.html
47. Accretion, Fracturing and Aggregation
48. Rain in Clouds With Ice (Cold Clouds) Homogeneous nucleation means without condensation nuclei:
Homogeneous nucleation occurs when the water vapor molecules condense and form a cloud droplet. To do this requires an environmental temperature of -40C and saturated air, or relative humidity of several hundred percent.
Heterogeneous nucleation means with condensation nuclei:
It turns out that saturating the air is not always enough to form a cloud. The water vapor molecules need a site to condense on. This site is called a Condensation Nuclei and the process referred to as heterogeneous nucleation. Cloud condensation nuclei (CCN) are about 1 micron is size.
Homogeneous nucleation means without condensation nuclei:
Homogeneous nucleation occurs when the water vapor molecules condense and form a cloud droplet. To do this requires an environmental temperature of -40C and saturated air, or relative humidity of several hundred percent.
Heterogeneous nucleation means with condensation nuclei:
It turns out that saturating the air is not always enough to form a cloud. The water vapor molecules need a site to condense on. This site is called a Condensation Nuclei and the process referred to as heterogeneous nucleation. Cloud condensation nuclei (CCN) are about 1 micron is size.
49. Cloud Seeding Man-made: Inject nuclei e.g. silver iodide or dry ice
Cloud particles become large enough to fall as rain
Not very effective!
50. Questions 1. Suppose that a thick nimbostratus cloud contains ice crystals and cloud droplets all about the same size. Which precipitation process will be most important in producing rain from this cloud? Why?
2. When cirrus clouds are above a deck of altocumulus clouds, occasionally a clear area, or "hole," will appear in the altocumulus cloud layer. What do you suppose could cause this to happen? 1. Bergeron process. Ice crystals grow in preference to cloud droplets.
2. Ice crystals from the Cirrus cloud act as ice nuclei, seeding the altocumulus.1. Bergeron process. Ice crystals grow in preference to cloud droplets.
2. Ice crystals from the Cirrus cloud act as ice nuclei, seeding the altocumulus.
51. Review Cloud droplets are very small, much too small to fall as rain
Cloud droplets form on cloud condensation _____. Hygroscopic nuclei, such as salt, allow condensation to begin when RH is less than 100 %
Cloud droplets, in above freezing air, can grow larger as faster-falling, bigger droplets collide and coalesce with smaller droplets in their path
In the ice-crystal (Bergeron) process of rain formation, both ice crystals and liquid cloud droplets must coexist at below-freezing temperatures. The difference in saturation vapor pressure between the liquid and ice causes water vapor to diffuse from the _________ _________ (which shrink) toward the ________ ________ (which grow)
Most of the rain that falls over middle latitudes results from melted snow that formed from the Bergeron process
Cloud seeding with _________ __________ can only be effective in coaxing precipitation from clouds if the cloud is supercooled and the proper ratio of cloud droplets to ice crystals exists Liquid droplets
Ice crystals
Silver IodideLiquid droplets
Ice crystals
Silver Iodide
52. Precipitation Types Summary Much rain starts as snow through the ‘ice crystal process’ and melts as it falls
Rain drops are not tear shaped. They are round or flattened
Water freezes into different shapes at different temperatures
A warm layer above a cold surface can result in sleet or freezing rain
Hail requires strong updrafts to be supported
53. Precipitation Types - Rain Rain – drop diameter > 0.5 mm (0.02 in)
Drizzle – drop diameter < 0.5 mm (most from stratus)
Virga – rain leaving cloud base and evaporates before hitting the ground
often visible as evaporating streaks of precipitation
Rain Events:
Showers - localized, sometime heavy rain events
usually associated with cumulonimbus
sometimes called a "cloud burst“
Continuous rain - from nimbostratus
54. Are Raindrops Tear-Shaped? Which shape more accurately depicts a rain drop?
Surface tension tends to squeeze drop to a shape that has the smallest surface area for its volume
55. Precipitation Types - Snow Snow - Often visible as fall streaks associated with high cirrus
More likely to reach surface when cold
Snow Events:
Flurries - weak, intermittent - produced from developing Cu
Snow squalls - brief, heavy snow fall - produced from Cu
Steady Snow - continuous for hours - produced from Nb
Blizzard - low temperatures, strong winds, blowing snow
56. Snow Warm, moist air, thin film of water acts as glue �= giant snowflakes
Cold, dry air = powdery flakes
Branching ‘dendrite’ pattern
Aggregates lead to many complex patterns
57. Other Types of Frozen Precipitation The vertical variation of temperature near the ground can have a dramatic influence on the type of precipitation that is observed at the ground
58. Precipitation Types - Sleet If a deep freezing layer exists at low levels, sleet may form
Snow will melt in warmer air layers
Surface layer will re-freeze into ice pellet known as sleet
British sleet = snow and rain
Layer may be too shallow to re-freeze, supercooled liquid reaches surface and instantly freezes = frezing rain (glaze)British sleet = snow and rain
Layer may be too shallow to re-freeze, supercooled liquid reaches surface and instantly freezes = frezing rain (glaze)
59. Meteograms Source: http://vortex.plymouth.edu/precip/precip2d.html
is a typical profile for sleet. You can see how the layer of colder air goes up higher in the atmosphere than it does in B, which is a typical profile for freezing rain. The layer of cold air in B is much more shallow and therefore, for a falling rain droplet, it would not have time to freeze while it is still in the air, but instead would freeze as it makes contact with the below freezing surface of the earth. �
This is a Meteogram, which is a more complicated version of the graphs shown in these slides.Source: http://vortex.plymouth.edu/precip/precip2d.html
is a typical profile for sleet. You can see how the layer of colder air goes up higher in the atmosphere than it does in B, which is a typical profile for freezing rain. The layer of cold air in B is much more shallow and therefore, for a falling rain droplet, it would not have time to freeze while it is still in the air, but instead would freeze as it makes contact with the below freezing surface of the earth.
This is a Meteogram, which is a more complicated version of the graphs shown in these slides.
60. Precipitation Types - Freezing Rain If a shallow freezing layer exists at low levels, freezing rain, �or glaze may form
Supercooled fog or �cloud freezing = rime
61. Precipitation Types - Snow Grains and Pellets Snow grains – small opaque �grains of ice (drizzle sized �from St cloud)
Snow pellets (graupel, soft hail)�– white opaque grains of ice �size of a rain drop�(break/bounce on impact)
62. Precipitation Types - Hail Graupel, frozen rain, �insects act as �accumulation points �‘embryos’
Grow by accretion in Cb �clouds
63. Measuring Precipitation Rain gauge contains a funnel to magnify the effective rain depth
EXAMPLE: 0.1 inches of rain would fill the inside tube with 1 whole inch of water, and a scaled ruler would measure this as 0.1 inches of actual rainfall.
*Imagine how hard it would be to measure to the nearest .01 of an inch in a regular bucket of water with a standard ruler! Radio detection and rangingRadio detection and ranging
64. Measuring Precipitation A tipping bucket gauge –�a pair of buckets seesaw, alternately fill and dump rain every 0.01”
The amount of precipitation can be recorded along with the time of occurrence and intensity (amount of rain per unit of time).
65. Radar ra(dio) d(etecting) a(nd) r(anging)
Radars transmit electromagnetic waves that bounce off of precipitation particles
Radar waves are scattered by rain or snow
Almost no scattering by cloud droplets (too small)
Strength of radar echo is related to rain or snowfall rate
Better radar in 1990’s:
Doppler radar measures everything a non-Doppler measures, plus speed of approaching or receding objects)
A palindrome is a word, verse, or sentence that reads the same backward or forward. A palindrome is a word, verse, or sentence that reads the same backward or forward.
66. Doppler Radar Doppler radar = �radar that can measure �‘Doppler shift’ �
(change in frequency (or ?) of waves caused by object approaching or receding) http://www.mnsu.edu/weather/wx_WALTER/Modules/Radar/radar_edu.htmlhttp://www.mnsu.edu/weather/wx_WALTER/Modules/Radar/radar_edu.html
67. Doppler Radar Draw radar waves on the following image:
68. Answer
