2026-04-18T02:56:53Zhttps://recercat.cat/oai/requestoai:recercat.cat:20.500.12327/1242025-10-22T11:07:05Zcom_2072_4428com_2072_4427col_2072_487898
00925njm 22002777a 4500
dc
El-Madany, Tarek S.
author
Reichstein, Markus
author
Perez-Priego, Oscar
author
Carrara, Arnaud
author
Moreno, Gerardo
author
Martín, M. Pilar
author
Pacheco-Labrador, Javier
author
Wohlfahrt, Georg
author
Nieto, Hector
author
Weber, Ulrich
author
Kolle, Olaf
author
Luo, Yun-Peng
author
Carvalhais, Nuno
author
Migliavacca, Mirco
author
2018-07-25
To understand what is driving spatial flux variability within a savanna type ecosystem in central Spain, data of
three co-located eddy covariance (EC) towers in combination with hyperspectral airborne measurements and
footprint analysis were used. The three EC systems show consistent, and unbiased mass and energy fluxes.
Nevertheless, instantaneous between-tower flux differences i.e. paired half hourly fluxes, showed large variability. A period of 13 days around an airborne hyperspectral campaign was analyzed and proved that betweentower differences can be associated to biophysical properties of the sampled footprint areas. At high photosynthetically active radiation (PAR) net ecosystem exchange (NEE) was mainly controlled by chlorophyll content
of the vegetation (estimated through MERIS Terrestrial Chlorophyll Index (MTCI)), while sensible heat flux (H)
was driven by surface temperature. The spatial variability of biophysical properties translates into flux variability depending on the location and size of footprints. For H, negative correlations were found with surface
temperature for between-tower differences, and for individual towers in time, meaning that higher H was observed at lower surface temperatures. High aerodynamic conductance of tree canopies reduces the canopy
surface temperature and the excess energy is relieved as H. Therefore, higher tree canopy fractions yielded to
lower surface temperatures and at the same time to higher H. For NEE, flux differences between towers were
correlated to differences in MTCI of the respective footprints, showing that higher chlorophyll content of the
vegetation translates into more photosynthetic CO2 uptake, which controls NEE variability. Between-tower
differences of latent heat fluxes (LE) showed no consistent correlation to any vegetation index (VI), or structural
parameter e.g. tree-grass-fraction. This missing correlation is most likely caused by the large contribution of soil
evaporation to ecosystem LE, which is not captured by any of the biophysical and structural properties.
To analyze if spatial heterogeneity influences the uncertainty of measured fluxes three different measures of
uncertainty were compared: the standard deviation of the marginal distribution sampling (MDS), the two-towerapproach (TTA), and the variance of the covariance (RE). All three uncertainty estimates had similar means and
distributions at the individual towers while the methods were significantly different to each other. The uncertainty estimates increased from RE over TTA to MDS, indicating that different components like space, time,
meteorology, and phenology are factors, which affect the uncertainty estimates. Differences between uncertainty
estimates from the RE and TTA indicate that spatial heterogeneity contributes significantly to the ecosystem-flux
uncertainty
El-Madany, Tarek S., Markus Reichstein, Oscar Perez-Priego, Arnaud Carrara, Gerardo Moreno, M. Pilar Martín, and Javier Pacheco-Labrador et al. 2018. "Drivers Of Spatio-Temporal Variability Of Carbon Dioxide And Energy Fluxes In A Mediterranean Savanna Ecosystem". Agricultural And Forest Meteorology 262: 258-278. Elsevier BV. doi:10.1016/j.agrformet.2018.07.010.
0168-1923
http://hdl.handle.net/20.500.12327/124
https://doi.org/10.1016/j.agrformet.2018.07.010
Drivers of spatio-temporal variability of carbon dioxide and energyfluxes ina Mediterranean savanna ecosystem