NWSCOMET Hydrometeorology Course 23 February 9 March 2000

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NWSCOMET Hydrometeorology Course 23 February 9 March 2000

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1. NWS-COMET. Hydrometeorology Course. 23 February 9 March 2000. Meteorology Primer ... Very long term average for mid-latitudes. Average surface pressure 1013 mb ... – PowerPoint PPT presentation

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Title: NWSCOMET Hydrometeorology Course 23 February 9 March 2000

1
NWS-COMETHydrometeorology Course23 February 9
March 2000

Meteorology Primer

Presented by Pete Stamus Wed-Thurs, 23-24
February 2000 Hydromet 00-2
2

Peter A. Stamus
Research Associate - Senior Meteorologist
CSU/Cooperative Institute for Research in the
Atmosphere (CIRA)
and
Colorado Research Associates (CORA)
303-415-9701 x224
303-415-9702 (fax)
stamus_at_co-ra.com

3
Purpose of the primer

Basic understanding of meteorological processes.
Starting point for the rest of Hydromet
To give you a semester-long Introduction to
Meteorology course in 8 hours.

4
Atmosphere StructureFun facts

Standard atmosphere
Very long term average for mid-latitudes
Average surface pressure 1013 mb
Average surface temperature 59 oF
1/2 of the mass of the atmosphere (500 mb)
below 6 km (3.7 miles)

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Atmosphere StructureFun facts

Lapse rate (decrease in temperature in the
vertical)
Troposphere
15 oC (at sfc) to -50 oC (at 10 km)
-6.5 oC / km

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Water vapor in the atmosphereThe most important
parameter we attempt to measure and forecast.

Clouds
Precipitation
Energy Transfer

9
Evaporation and Condensation
10
Evaporation and Condensation

Evaporation
Fast molecules escape, slower remain
cooling process
Condensation
Slower molecules collide, form droplets,
droplets fall, faster molecules remain
warming process

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Evaporation and Condensation (cont.)

The Evaporation/Condensation process transfers
heat energy to the atmosphere
Latent Heat of Condensation

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Evaporation and Condensation (cont.)Fun facts

Wind enhances evaporation
Warm water evaporates faster than cool water
Air temperature affects evaporation rate
Cool air, slower molecules, condensation more
likely, slows evaporation
Warm air can hold more water vapor before
saturation than cold air

14
Saturation Vapor Pressure
15
Relative Humidity and Dew Point
Parcel B
Parcel A
Pressure at 1000 mb
T 10 oC (50 oF) e 12.3 mb es 12.3 mb
T 20 oC (68 oF) e 12.3 mb es 23.7 mb
RH (e / es) x 100 100
RH (e / es) x 100 52
Therefore Td 10 oC for Parcel B Dew point
Temperature to which air must be cooled at
constant pressure to reach saturation. It is a
measure of the airs actual water vapor
content. Relative Humidity is a measure of the
degree of saturation of the air.
16
Energy Budget

Incoming solar
Emitted long-wave
Transfer with latitude
Long-term balance

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Energy Transfer with latitude
20
Daily and Seasonal Energy Balance
21
Lab 1

Basic Surface Features/Moisture

22
Atmospheric Pressure

Pressure total weight of air above
Air is compressible, so gravity concentrates most
air molecules near the surface
Atm pressure decreases with height
rising air cools, sinking air warms
Greatest pressure variation in vertical, but
smaller horizontal variations produce winds and
weather systems

23
Pressure and terrain
24
Pressure and volume
25
Pressure and volume (cont.)
26
Typical 500 mb map
27
Lab 2

3-D Atmospheric Structure

28
Wind

Differential heating of land/ocean leads to
pressure differences in the atmosphere
Pressure differences are forces that lead to
atmospheric motions

29
Wind (cont.)

Newtons Laws of Motion
First Law
Objects at rest remain at rest and objects in
motion remain in motion, provided no force acts
on the object
Second Law
Force equals mass times the acceleration produced
F ma
To determine wind direction and speed, need to
know the forces that affect horizontal movement
of the air

30
Wind (cont.)