Periodic Reporting for period 2 - SWATCH (Savanna water and carbon fluxes modelling integrating Earth Observation data)
Okres sprawozdawczy: 2020-02-01 do 2021-01-31
Since savannas are highly influenced by human activities, private and institutional practices play a key role in their conservation. Earth Observation (EO) data integration in process-based models to estimate water and CO2 exchanges, enable us to map the evolution of ecosystems health, improving their management and therefore their productivity and resilience. However, to model semiarid savanna water use and biomass production at regional scales, we must develop mechanistic understanding of how the endemic dry periods of high air temperatures and no rainfall, and the canopy structure (patched multiple canopy layers), interact with land-atmospheric processes. In addition, robust techniques must be devised to upscale the ecosystem parameters and fluxes over space and time.
This proposal aims to develop a unique information system for savanna water use and biomass production on a regional scale capable to support decision-making processes. This effort will be a key point to ensure a sustainable rural development and food security, in a future when a growing population will face extreme climate conditions, directly addressing the European H2020 Work Programme priorities. SWATCH (Savanna WATer and Carbon fluxes modelling integrating EartH Observation data) integrates different-scale Earth Observation data (from remote-sensing techniques) into water and surface energy balances and plant production/light-use efficiency models. Long-term eddy covariance towers and ground measurements will be used to determine ecosystem parameters, to develop accurate methods for space/time upscaling, and for model validation (Figure 1: SWATCH overview).
The objectives of the outgoing phase of this proposal have been, 1) Improve the knowledge of the biophysical processes that govern the exchanges of water and carbon between savanna landscapes and the atmosphere, and 2): Develop a mechanistic and robust model of water/energy/carbon fluxes in a savanna ecosystem, by integrating biophysical processes and various remote sensing products, to be able to achieve the last objective in the next phase of the project, 3) SWATCH implementation over a pilot study area in Spain (Figure 2: Work Package scheme).
This first phase, conducted in Californian savannas (US), was hosted by Prof. Baldocchi's group at UC Berkeley, with the collaboration of Dr. Kustas of the Hydrology and Remote Sensing Lab (USDA-HRSL, Beltsville). Due to their Mediterranean climate, California and Spain regions encompass a high percentage of savanna (~10% each), which makes them ideal locations to evaluate semiarid savannas. Prof. Baldocchi's group expertise on biosphere/atmosphere carbon and water exchanges and process-based modelling, more than 15 years of data series over Tonzi FluxNet oak savanna, and collaborators of the Biometlab such as M.R. Johnston (Harvard University), along with Dr. Kustas extensive expertise in modelling energy fluxes with EO, allowed Dr. Andreu to better understand ecosystem functioning on canopy/field scale, and how to bridge the gap between field (pixel resolution) and landscape/regional scales (whole satellite imagery). Related field campaigns where Dr. Andreu participated, such as the Grapex experiment lead by Dr. Kustas over Californian vineyards, or the new set up of Santa Clotilde site from IFAPA (Cordoba, Spain) were key on this first part of the fellowship (Figure 3: Field campaigns).
In the current return phase, with Dr. González-Dugo's group at IFAPA (Spain), the aim is to focus on a pilot experience, developing an information system useful to support management decisions regarding the Spanish oak savanna system, known as dehesa. Dr. González-Dugo's group is one of the few research institutions dedicated to monitor dehesas using EO data.