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The role of coherent flow structures in the sensible heat fluxes of an Alaskan boreal forest
Author(s) -
Starkenburg Derek,
Fochesatto Gilberto J.,
Prakash Anupma,
Cristóbal Jordi,
Gens Rudiger,
Kane Douglas L.
Publication year - 2013
Publication title -
journal of geophysical research: atmospheres
Language(s) - English
Resource type - Journals
eISSN - 2169-8996
pISSN - 2169-897X
DOI - 10.1002/jgrd.50625
Subject(s) - mean flow , canopy , atmospheric sciences , taiga , boreal , environmental science , forcing (mathematics) , flux (metallurgy) , flow (mathematics) , sensible heat , lagrangian coherent structures , climatology , turbulence , meteorology , geology , geography , ecology , mathematics , forestry , geometry , biology , chemistry , organic chemistry
Accelerations in the flow over forests generate coherent structures which locally enhance updrafts and downdrafts, forcing rapid exchanges of energy and matter. Here, observations of the turbulent flow are made in a highly heterogeneous black spruce boreal forest in Fairbanks, Alaska at ~2.6 h (12 m) and ~0.6 h (3 m), where h is the mean canopy height of 4.7 m. Wavelet analysis is used to detect coherent structures. The sonic temperature and wind data cover 864 half‐hour periods spanning winter, spring, and summer. When mean global statistics of structures are analyzed at the two levels independently, results are similar to other studies. Specifically, an average of eight structures occurs per period, their mean duration is 85 s, and their mean heat flux contribution is 48%. However, this analysis suggests that 31% of the structures detected at 2.6 h, and 13% at 0.6 h, may be influenced by wave‐like flow organization. Remarkably, less than 25% of the structures detected occur synchronously in the subcanopy and above canopy levels, which speaks robustly to the lack of flow interaction within only nine vertical meters of the forest.