boundary layer evolution
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Boundary Layer Evolution. Atmos 3200/ Geog 3280 Mountain Weather and Climate. C. David Whiteman. Boundary layer definition. - PowerPoint PPT PresentationTRANSCRIPT
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Boundary Layer Evolution
Atmos 3200/Geog 3280Mountain Weather and Climate
C. David Whiteman
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Boundary layer definition
The boundary layer: The layer of fluid in the immediate vicinity of a fluid-solid boundary. In the atmosphere, the layer near the ground affected by diurnal heat, moisture and momentum transfer to or from the surface of the earth.
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Tethersonde and radiosonde
Whiteman photo
Whiteman (2000)
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Typical evolution of boundary layer
Whiteman (2000)
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Temperature and potential temperature profiles
Stull (2000)
Stull (2000)
Compare T and soundings
FA = free atmosphere; EZ = entrainment zone; ML = mixed layer, SL = superadiabatic layer;CI = capping inversion; RL = residual layer; SBL = stable boundary layer
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Diurnal fair weather evolution of bl over a plain
Whiteman (2000)
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Pressure and Winds
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Standard atmosphere
Pressure (hPa = mb)
Typical height (ft)
Typical height (m)
1013.25 0 0
1000 370 110
850 4780 1460
700 9880 3010
500 18280 5570
300 30050 9160
Pressure decreases exponentially with altitude
Pressure changes more rapidly in the vertical than in the horizontal, but the horizontal variations are important for visualizing traveling pressure systems.
Standard atmosphere (tropo)
15°C at sea level
Temperature lapse rate 6.5 °C/km
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Pressure and wind units (also temperature)
Pressure:– mb (hPa)– inches of mercury– mm of mercury– pounds per square inch– atmospheres
Winds:– mph (statute miles per hour)– m/s– knots (nautical miles per hour)– km/h
See Appendix D for unit conversions
Demonstrate KestralF = 32 + (9/5)C
C = (5/9) (F-32)
mph m/s km/h knots
1 0.4 1.6 0.9
2 0.9 3.2 1.7
3 1.3 4.8 2.6
4 1.8 6.4 3.5
5 2.2 8.0 4.3
10 4.5 16.1 8.7
Wind speed conversion table
Beaufort Wind Scale
See Table 5.2
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Highs, lows, ridges, troughs
Sea level pressure analysis Isoheight analysis, 500 mb
How to reduce surface pressure to sea level?
Pressure variation on constant height surface (left)Height variation on constant pressure surface (rt)
Isobar
Isohypse, isoheight, contour line
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500 mb hemispheric pattern
Mean 500 mb height pattern25 Jan 1999 500 mb height pattern
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Balance of forces, highs and lows, NH
Balance of Forces:
Pressure Gradient Force (PGF) is directed from high to low and is proportional to pressure gradient.
Coriolis Force (CF) is a function of speed and latitude and is directed to right of wind.
Friction Force opposes the wind and is proportional to surface drag.Above sfc friction, winds become parallel to isobars with low on left. If friction is felt, winds turn across isobars toward low pressure. Thus, winds spiral counterclockwise into sfc low and clockwise out of sfc high.
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Leeward, windward, definitions
Convention for naming winds:
Named for the direction from which they blowExample: A north wind blows from N to SExample: An east wind blows from E to W
A sea breeze blows from sea to landA land breeze blows from land to seaA mountain wind blows from mountain to valleyA valley wind blows from valley to mountain
If we need more specificity, use the bearing from which the wind blows
Example: a wind from 178° (a south wind)
Example: a wind from 87° (an east wind)
Or use a vector Will need a legendor scale
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Buys-Ballot rule (Northern Hemisphere)
“If the wind blows into your back, the Low will be to your Left (and the high will be to your right).”
This rule works well if the wind is above the earth’s boundary layer, not channeled by topography, etc.
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Today’s 500 mb analysis
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Today’s surface analysis (MSLP analysis)
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Transfer of heat by cyclones and anticyclones
Excess of solar radiation relative to long wave loss at equator. Deficit at poles. Poles get cold, equator gets warm. A zonal temperature gradient develops. Lows and highs and ocean currents are necessary to transfer heat from the equator toward the poles.
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Cornices, snow fence, flagged trees
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Diurnal variation of wind speed
Winds at the ground increase in the afternoon as stronger winds are mixed down from aloft.
Winds aloft decrease in the afternoon as the mixing exposes them to friction at the earth’s surface.