Download presentation
Presentation is loading. Please wait.
Published bySheryl Houston Modified over 9 years ago
1
ang Atmospheric Boundary Layer and Turbulence Zong-Liang Yang liang@jsg.utexas.edu http://www.geo.utexas.edu/climate Department of Geological Sciences Jackson School of Geosciences 1
2
ang Outline Definition and Basic Properties Why Study ABL? Structure of ABL Features of Wind Speed Variation Surface Energy Balance Summary 2
3
ang ABL: Definition and Basic Properties 3 The layer of air near the Earth’s surface, also called the Planetary Boundary Layer. It is that portion of the lower troposphere that feels the effects of the underlying surface within about 30 minutes or less. The surface influences ABL by friction and by heat fluxes at the surface. This layer is turbulent and is well mixed. Turbulence is generated by wind shear (wind is approximately geostrophic at the top of the ABL but zero at the surface). Temperature gradients can either generate or suppress turbulence. Temperatures vary diurnally, unlike the free atmosphere above. Its height evolves with time over the course of a day. Boundary layer clouds: fair-weather cumulus, stratocumulus, fog. Maximum height: usually ~1 km, ~3 km over deserts, dry fields and boreal forests; 1–2 km over wetter surfaces.
4
ang Why Study ABL? 4 Humans live in the ABL. Fluxes are mediated here. 50% of the atmosphere’s kinetic energy is dissipated in the boundary layer. It is the location of the source and sink of many trace gases (including water vapor, CO 2, ozone, methane) and dusts/pollutants. It is a reservoir of trace gases and pollutants. It is important for local forecasting. There is a strong effect on the rest of the atmosphere. Boundary-layer clouds are very important for climate.
5
ang Structure of ABL (1/2) 5 During a clear day, it consists of a roughness sublayer (air flows around individual roughness elements – grass, plants, trees, or buildings), a surface boundary layer, a well-mixed layer and a capping entrainment layer. Formerly known the constant flux layer, ~ 100 m thick or 10% of the ABL Potential temperature and other quantities are constant with altitude. Earth’s rotation becomes important, and the wind direction veers with height. The ABL is capped by a temperature inversion, which inhibits mixing and confines pollution below it.
6
ang Structure of ABL (2/2) 6
7
ang Features of the Wind Speed Variation 7 Wind speeds from 3 different levels recorded from a synoptic gale Increase in mean (average) speed with height Turbulence (gustiness) at each height level Broad range of frequencies in the fluctuations Similarity in gust patterns at lower frequencies
8
ang Surface Energy Balance 8
9
ang Earth’s Global Energy Budget Trenberth et al. (2009) 80% of net radiation at the surface is used for evaporation!
10
ang Air Flow and Turbulent Vortices Air flow can be imagined as a horizontal flow of numerous rotating eddies, a turbulent vortices of various sizes, with each eddy having 3D components, including vertical components as well. The situation looks chaotic, but vertical movement of the components can be measured from the tower.
11
ang Determine Vertical Fluxes
12
ang Surface Energy Balance
13
ang Surface Energy Balance
14
ang Surface Energy Balance
15
ang Surface Energy Balance
16
ang Surface Energy Balance
17
ang Surface Energy Balance
18
ang Surface Energy Balance
19
ang Surface Energy Balance
20
ang Surface Energy Balance
21
ang Surface Energy Balance
22
ang Surface Energy Balance
23
ang Supplementary Materials
24
ang Reynolds Decomposition and Eddy Covariance
25
ang Reynolds Decomposition and Eddy Covariance
26
ang Bulk Aerodynamic Formulas (Parameterizations) τ = ρ C DM U r 2 SH = c p ρ C DH U r [T s – T a (z r )] LE = L ρ C DE U r [q s – q a (z r )] C DN = [κ / ln(z r /z 0 )] 2 C DM = C DN,M f M (R iB ) C DH = C DN,H f H (R iB ) C DE = C DN,E f E (R iB )
27
ang Global Distribution of Sensible Heat Flux http://www.cdc.noaa.gov/
28
ang Global Distribution of Latent Heat Flux http://www.cdc.noaa.gov/
29
ang Regional Patterns of The Surface Energy Balance Yuma, AZ energy balance (ly/day) At the other extreme is Yuma, Arizona, a warm and dry climate. The most noticeable characteristic of this place is the lack of latent heat transfer. Though ample radiation is available here, there is no water to evaporate. Nearly all net radiation is used for sensible heat transfer which explains the hot dry conditions at Yuma. West Palm Beach, Fl energy balance (ly/day) West Palm Beach, Florida is located in a warm and moist climate. Latent energy transfer into the air is greatest during the summer time which is the wettest period of the year, and when net radiation is the highest. During the summer, sensible heat transfer decreases as net radiation is allocated to evaporation and latent heat transfer.
30
ang 30
31
ang Lawrence et al., 2011 31 500+
32
ang Summary Prof. Zong-Liang Yang +1-512-471-3824 liang@jsg.utexas.edu http://www.geo.utexas.edu/climate Additional Major References “The ABL” by Roland Stull 32
Similar presentations
© 2025 SlidePlayer.com. Inc.
All rights reserved.