TY - JOUR
T1 - Estimating surface fluxes using eddy covariance and numerical ogive optimization
AU - Sievers, Jakob
AU - Papakyriakou, T.
AU - Larsen, S.E.
AU - Jammet, Mathilde Manon
AU - Rysgaard, Søren
AU - Sejr, Mikael Kristian
AU - Sørensen, L.L.
N1 - CENPERMOA[2015]
PY - 2015/2/26
Y1 - 2015/2/26
N2 - Estimating representative surface fluxes using eddy covariance leads invariably to questions concerning inclusion or exclusion of low-frequency flux contributions. For studies where fluxes are linked to local physical parameters and up-scaled through numerical modelling efforts, low-frequency contributions interfere with our ability to isolate local biogeochemical processes of interest, as represented by turbulent fluxes. No method currently exists to disentangle low-frequency contributions on flux estimates. Here, we present a novel comprehensive numerical scheme to identify and separate out low-frequency contributions to vertical turbulent surface fluxes. For high flux rates (|Sensible heat flux| > 40 Wm -2, |latent heat flux|> 20 Wm -2 and |CO2 flux|> 100 mmol m -2 d -1 we found that the average relative difference between fluxes estimated by ogive optimization and the conventional method was low (5-20%) suggesting negligible low-frequency influence and that both methods capture the turbulent fluxes equally well. For flux rates below these thresholds, however, the average relative difference between flux estimates was found to be very high (23-98%) suggesting non-negligible low-frequency influence and that the conventional method fails in separating low-frequency influences from the turbulent fluxes. Hence, the ogive optimization method is an appropriate method of flux analysis, particularly in low-flux environments.
AB - Estimating representative surface fluxes using eddy covariance leads invariably to questions concerning inclusion or exclusion of low-frequency flux contributions. For studies where fluxes are linked to local physical parameters and up-scaled through numerical modelling efforts, low-frequency contributions interfere with our ability to isolate local biogeochemical processes of interest, as represented by turbulent fluxes. No method currently exists to disentangle low-frequency contributions on flux estimates. Here, we present a novel comprehensive numerical scheme to identify and separate out low-frequency contributions to vertical turbulent surface fluxes. For high flux rates (|Sensible heat flux| > 40 Wm -2, |latent heat flux|> 20 Wm -2 and |CO2 flux|> 100 mmol m -2 d -1 we found that the average relative difference between fluxes estimated by ogive optimization and the conventional method was low (5-20%) suggesting negligible low-frequency influence and that both methods capture the turbulent fluxes equally well. For flux rates below these thresholds, however, the average relative difference between flux estimates was found to be very high (23-98%) suggesting non-negligible low-frequency influence and that the conventional method fails in separating low-frequency influences from the turbulent fluxes. Hence, the ogive optimization method is an appropriate method of flux analysis, particularly in low-flux environments.
U2 - 10.5194/acp-15-2081-2015
DO - 10.5194/acp-15-2081-2015
M3 - Journal article
SN - 1680-7316
VL - 15
SP - 2081
EP - 2103
JO - Atmospheric Chemistry and Physics
JF - Atmospheric Chemistry and Physics
ER -