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Sensible Heat Flux From Arid Regions: A Simple Flux‐Variance Method
Author(s) -
Albertson John D.,
Parlange Marc B.,
Katul Gabriel G.,
Chu ChiaRen,
Stricker Han,
Tyler Scott
Publication year - 1995
Publication title -
water resources research
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.863
H-Index - 217
eISSN - 1944-7973
pISSN - 0043-1397
DOI - 10.1029/94wr02978
Subject(s) - sensible heat , mechanics , convection , convective boundary layer , heat flux , planetary boundary layer , buoyancy , environmental science , flux (metallurgy) , atmospheric instability , boundary layer , meteorology , atmospheric sciences , heat transfer , materials science , geology , physics , wind speed , metallurgy
Similarity models in the inner region of the unstable atmospheric boundary layer (ABL) are generally based on four dimensional parameters: buoyancy, friction velocity, surface heat flux, and the height above the land surface. In the free convection limit the friction velocity can be neglected, thus reducing the measurement needs in practical applications. Some field measurements of the second moment of temperature have indicated that free convection scaling of this statistic may be extended into more dynamic regimes, namely, the “dynamic‐convective” and, perhaps, the “dynamic” regions of the ABL. An advantage of this approach is that the sensible heat flux can be estimated without shear stress measurements. This temperature variance similarity model is applied for a wide range of unstably stratified flows over the dry Owens Lake, in southeastern California. The simple free convection model of the temperature variance is accurate for sensible heat flux estimation across the full range of unstable atmospheric stability conditions.