Transcript Lecture 5

Lecture 5
reading assignm: A&K finish Ch 3, Ch 4. Hartmann 3.8, 3.9, 3.10, 3.12
• Lapse rate, change in T with height
Atmospheric water:
• quantifying water vapor in the air
• cloud formation
• fog formation
• high/middle/low clouds
• radiative effects of clouds
Diurnal temperature cycle – notice the lag
Lapse rates and stability
Temperature inversion: when temperature
increases w. height…………………………..
Forming a temperature inversion. Temperature
inversions trap pollution near ground, can be
important for formation of severe weather
Atmospheric Water
Evaporation:process by which water
is converted from liquid form to gas
It takes energy!
It occurs more easily over warmer
surfaces. Evaporation is also greater
when atmospheric pressure is low,
wind speed is high and there is little
water vapor in the air.
Equilibrium when air is saturated
Measuring water vapor in the air
• Mixing ratio (units :g/kg w.r.t. dry air)
• Vapor pressure (at most 40 mb)
– Saturation vapor pressure
• Relative humidity:
– Vapor pressure/saturation vapor press x 100
• Dew point: temp to which cool air at same
pressure to cause condensation
• Frost point: temp to which cool air at same
pressure to cause frost to form
The source of water vapor is at the surface. That’s
why it decreases sharply away from surface.
Condensation/deposition:
Cloud formation, i.e., forming liquid
droplets and solid ice crystals from
water vapor
Solute effect
Curvature effect
Cloud formation
• Nucleation (formation of cloud droplet
around any type of particle.)
• Homogeneous nucleation
• Heterogeneous nucleation
• Condensation nuclei
– Hygroscopic nuclei
– Hydrophobic nuclei
• Ice nuclei
Fog – types and formation
• Radiation fog. Forms similar to dew
– Ground cools by radiation on long clear nights with
light winds
• Advection fog
– When warm air advected over a cool surface
– Off the coast of CA, cool coastal current
– Gulf of Mexico in fall & winter
• Evaporation (frontal or steam) fog
– When water evaporates from rain that falls from
warmer air into cold air near surface
• Upslope fog
Fog can at most form drizzle.
Traffic hazard
Lifting mechanisms forming clouds
LCL
updraft
Cloud classification
• Layered clouds -- stratus (layered)
• Convective clouds --- cumulo (heap)
• Clouds are also classified by their altitude
– Cirro (high composed of wispy ice crystals)
– Alto (in mid-troposphere)
• Nimbus (rain)
Cloud classification
Stratus is a very common cloud type in S Cal
Cumulus – Fair weather Cu
Nimbostratus (Ns) are deep layered clouds that bring
precipitation and appear dark gray
Cumulonimbus (Cb)
Altocumulus (Ac)
Radiative effects of clouds
• Clouds reflect solar radiation effectively
– Thicker clouds reflect more –cooling effect
• Clouds absorb & emit terrestrial radiation
• The altitude of a cloud is important in
determining radiative budget
– Because the higher the cloud, the colder it is,
and the less OLR it emits to space
• Clouds can cool or warm the planet
Globally and annually averaged
radiative effects of clouds
• If clouds were removed without any other
change then the Earth would gain
approximately 20 W/m2 in net radiation
and consequently it would warm.
Cloud composition: water clouds/ ice crystal clouds
Whether clouds originate over land or ocean
affects the number of CCNs
Shape of crystal
depends on
the environmental
temperature