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Transcript
Accounting for biodiversity in marine ecosystem models Jorn Bruggeman S.A.L.M. Kooijman Dept. of Theoretical Biology Vrije Universiteit Amsterdam Interspecific differences quantified by traits How to capture biodiversity in models? Species-specific models are incomparable Approach: one omnipotent species Parameter values determine the species Species-determining parameters: traits Ecosystem diversity Phototrophs and heterotrophs: a section through diversity bact 1 heterotrophy bact 3 ? bact 2 ? ? mix 1 mix 2 mix 3 mix 4 ? phyto 1 ? phyto 2 ? phyto 3 phototrophy phyto 2 Infinite diversity continuity in traits Species = investment strategy Why not ‘just’ do everything well? Good qualities must be paid for – – Budget is limited make choices! Usefulness of qualities depends on environment – costs for directly associated machinery (photosynthesis, phagocytosis) costs for containment if qualities conflict (nitrogen fixation requires anoxic environment) No photosynthesis in dark environments Species define niche by choosing qualities to invest in (‘strategy’) Cost-aware phytoplankton population + + structural biomass nutrient + + + κL light harvesting + structural biomass nutrient + κN + nutrient harvesting Functional group: phytoplankton Discretized trait distribution – 15 x 15 trait values = 225 ‘species’ Start with homogeneous distribution, low densities Realistic setting Bermuda Atlantic Time-series Study (BATS) – 10 years of monthly depth profiles for physical/biological variables Turbulent water column model (1D) – – – – General Ocean Turbulence Model (GOTM) upper 250 meter k-ε model for turbulence parameterization realistic forcing with meteorological data (ERA-40) Biota: chlorophyll Modeled light harvesting equipment chlorophyll BATS measured chlorophyll averaged over 10 years Succession: average trait values in time Modeled light harvesting equipment cell-specific chlorophyll Modeled nutrient harvesting equipment surface-to-volume 1/cell length Trends Cell-specific chlorophyll increases with depth – – High-chlorophyll species do better in low-light deep Thus: succession (‘shade flora’), not photo-acclimation (Geider) Seasonal succession: large small species – – – Small species fare better in oligotrophic environment Bloom start with high nutrient level, large species Small species gain upper hand as bloom proceeds (Margalef) Conclusions and perspectives Trait-based approach demonstrates diversity in space and time – – Description of BATS – – Qualitatively ‘reasonable’ with current (5 parameter!) model Space for improvement; parameter fitting with base no-trait model Aim: collapse trait distribution – increase in chlorophyll content with increasing depth decrease in cell size between start of bloom and winter Loss of state variables fitting becomes possible Future: traits for ecosystems – – – heterotrophy predation/defense body size
