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Observations of the scale-dependent turbulence and evaluation of the flux-gradient relationship for sensible heat for a closed Douglas-fir canopy in very weak wind conditions

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Title Observations of the scale-dependent turbulence and evaluation of the flux-gradient relationship for sensible heat for a closed Douglas-fir canopy in very weak wind conditions
Names Vickers, D. (creator)
Thomas, C. K. (creator)
Date Issued 2014-09-16 (iso8601)
Note This is the publisher’s final pdf. The published article is copyrighted by the author(s) and published by Copernicus Publications on behalf of the European Geosciences Union. The published article can be found at: http://www.atmospheric-chemistry-and-physics.net/home.html.
Abstract Observations of the scale-dependent turbulent
fluxes, variances, and the bulk transfer parameterization
for sensible heat above, within, and beneath a tall closed
Douglas-fir canopy in very weak winds are examined.
The daytime sub-canopy vertical velocity spectra exhibit
a double-peak structure with peaks at timescales of 0.8 s
and 51.2 s. A double-peak structure is also observed in the
daytime sub-canopy heat flux co-spectra. The daytime momentum
flux co-spectra in the upper bole space and in the
sub-canopy are characterized by a relatively large crosswind
component, likely due to the extremely light and variable
winds, such that the definition of a mean wind direction,
and subsequent partitioning of the momentum flux
into along- and cross-wind components, has little physical
meaning. Positive values of both momentum flux components
in the sub-canopy contribute to upward transfer of momentum,
consistent with the observed sub-canopy secondary
wind speed maximum. For the smallest resolved scales in the
canopy at nighttime, we find increasing vertical velocity variance
with decreasing timescale, consistent with very small
eddies possibly generated by wake shedding from the canopy
elements that transport momentum, but not heat. Unusually
large values of the velocity aspect ratio within the canopy
were observed, consistent with enhanced suppression of the
horizontal wind components compared to the vertical by the
very dense canopy.
The flux–gradient approach for sensible heat flux is found
to be valid for the sub-canopy and above-canopy layers when
considered separately in spite of the very small fluxes on the
order of a few Wm⁻² in the sub-canopy. However, single-source
approaches that ignore the canopy fail because they
make the heat flux appear to be counter-gradient when in
fact it is aligned with the local temperature gradient in both
the sub-canopy and above-canopy layers. While sub-canopy
Stanton numbers agreed well with values typically reported
in the literature, our estimates for the above-canopy Stanton
number were much larger, which likely leads to underestimated
modeled sensible heat fluxes above dark warm closed
canopies.
Genre Article
Access Condition http://creativecommons.org/licenses/by/3.0/us/
Identifier Vickers, D., & Thomas, C. K. (2014). Observations of the scale-dependent turbulence and evaluation of the flux-gradient relationship for sensible heat for a closed Douglas-Fir canopy in very weak wind conditions. Atmospheric Chemistry and Physics, 14(18), 9665-9676. doi:10.5194/acp-14-9665-2014

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