This title appears in the Scientific Report :
2019
CloudRoots: an integrated field experiment and modelling approach to study soil-plant-atmosphere interactions
CloudRoots: an integrated field experiment and modelling approach to study soil-plant-atmosphere interactions
Due to their high-quality routine measurement programme, ICOS sites lend themselves as anchors for additional experiments. As an example, we describe the CloudRoots campaign near the agricultural site Selhausen (DE-RuS)in spring 2018. Little is known about the two-way feedback between stomatal contr...
Saved in:
Personal Name(s): | Vila, Jordi (Corresponding author) |
---|---|
Hartogensis, Oscar / Quade, Maria / Matveeva, Maria / Roeckmann, Thomas / Adnew, Getachev / de Boer, Hugo / Emin, Dzhaner / Schmäck, Jessica / Langensiepen, Matthias / Schmidt, Marius / Klosterhalfen, Anne / Ney, Patrizia / Brüggemann, Nicolas / Graf, Alexander | |
Contributing Institute: |
Agrosphäre; IBG-3 |
Published in: | Geophysical research abstracts, 21 (2019) |
Imprint: |
2019
|
Physical Description: |
EGU2019-10114-1 |
Conference: | EGU General Assembly, Vienna (Austria), 2019-04-07 - 2019-04-12 |
Document Type: |
Contribution to a conference proceedings Journal Article |
Research Program: |
Terrestrial Environmental Observatories TRR 32: Muster und Strukturen in Boden-Pflanzen-Atmosphären-Systemen: Erfassung, Modellierung und Datenassimilation Instrumental and Data-driven Approaches to Source-Partitioning of Greenhouse Gas Fluxes: Comparison, Combination, Advancement Terrestrial Systems: From Observation to Prediction |
Publikationsportal JuSER |
Due to their high-quality routine measurement programme, ICOS sites lend themselves as anchors for additional experiments. As an example, we describe the CloudRoots campaign near the agricultural site Selhausen (DE-RuS)in spring 2018. Little is known about the two-way feedback between stomatal control (controlling the partitioning of energy into sensible and latent heat) and cloud development (affecting potential evapotranspiration). Coupled models of the soil-vegetation-boundary layer continuum have the potential to explain this, but their calculations are only as robust as the data used to parameterize or validate the model. For observations and modelling, the challenge is ininterconnecting processes at leaf level to the physics of turbulence and clouds. We temporarily amend the existing radiation, flux and soil dynamics/respiration measurements of the ICOS site by scintillometry, sap-flow and leaf-level flux measurements, vertical profiles and isotope measurements. Scintillometers provide minute-scale turbulent fluxes enabling to connect stomatal responses to the energy, moisture and CO2 fluxes at this timescale [1]. Sap-flow [2], leaf-level chamber, canopy-resolving profile [3] and isotope measurements have the potential to distinguish stomatal CO2 and H2O fluxes from the eddy-covariance based net fluxes. Relating the leaf and canopy level measurements to cloud development and potential cross-scale feedbacks are integrated and explored with the CLASS model ([4], https://classmodel.github.io). The campaign is partnering with two complementary test campaigns for the FLEX mission(https://earth.esa.int/web/guest/missions/esa-future-missions/flex) and the MOSES project (https://moses.eskp.de/home/), taking place, among others, in the same region in spring and summer 2018. The poster will show first results and method intercomparisons from the CloudRoots field campaign.[1] van Kesteren et al. 2013, Agric. For. Meteorol. 178-179:75-105[2] Langensiepen et al. 2014, Agric. For. Meteorol. 186:34[3] Ney and Graf 2018, Bound.-Layer Meteorol. 166:449[4] Vilà-Guerau de Arellano et al. 2015, Atmospheric Boundary Layer: Integrating air chemistry and land interactions. Cambridge University Press. |