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Studies in SOLAS-Japan using an intermediate complexity ecosystem model

Studies in SOLAS-Japan using an intermediate complexity ecosystem model. Faculty of Environmental Earth Science, Hokkaido University E-mail: naoki@ees.hokudai.ac.jp. Today’s talk:

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Studies in SOLAS-Japan using an intermediate complexity ecosystem model

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  1. Studies in SOLAS-Japan using an intermediate complexity ecosystem model Faculty of Environmental Earth Science, Hokkaido University E-mail: naoki@ees.hokudai.ac.jp • Today’s talk: • An intermediate complexity ecosystem model “NEMURO” 1. Interannual variability of global marine ecosystem 2. Their responses to the global warming 3. Simulation of an iron fertilization experiment “SEEDS I” • Our studies in SOLAS-Japan 4. Development of the extended NEMURO 5. Response of biogeochemical cycles to weather disturbances Naoki Yoshie and Yasuhiro Yamanaka

  2. Original NEMURO coupled with carbon cycles (Yamanaka et al., JO, 2004) We had to divide diatom in 2 groups to adjust NEMURO to an iron fertilization experiment “SEEDS I”.

  3. Sensitive to Felow Fe conc. :low activity high Fe conc.:high activity Insensitive to Felow Fe conc. :med. activity high Fe conc.:med. activity NEMURO for SEEDS(Yoshie et al., PO, 2005) Separating into 2 groups

  4. too early ! 1 diatom model(e.g., Chai et al., 2002)Amplitude of bloom:good Timing of bloom :too early Comparison among 1 and 2 diatom models, and observation in SEEDS Phytoplankton Obs. 1 diatom model 2 diatoms model 2 diatom model(Yoshie et al., 2005)Amplitude of bloom:good Timing of bloom :good NO3 fCO2

  5. Before iron-enrichment,PLc is very minor with very low activity due to the iron depletion. After iron-enrichment (from day 0),Activity ofPLc rapidly increases due to plentiful iron. PLc increases and becomes major around day 5. Time lag of diatom bloom in SEEDS Vmax of PLc Activity Why SEEDS has 5days time lag between iron-enrichment and diatom bloom? Vmax (Vmax of total diatom) Vmax of PLp Biomass PLc PLp Activity of total phytoplankton Fv/Fm, Suzuki et al., 2005 Dissolved iron conc. The time lagis caused bythe transition of dominance, from pennate (PLp) to centric (PLc) diatoms. Tsuda et al., 2004

  6. We are developing a model representing following 2 directions. • Tight coupling between biogeochemical cycles and marine ecosystem • Their responses to high frequency forcings such as weather disturbances Our studies in SOLAS-Japan

  7. Extended NEMURO (eNEMURO) introducing subtropical groups of plankton New subtropical groups Since original NEMURO was tuning to adjust subarctic ecosystem, and NEMURO has to be retuned in order to be applied to subtropical ecosystem. We introduce these small-size subtropical plankton. This is current status of our model. We will improve the model for SOLAS by introducing DMS, Fe, dust, etc.

  8. Response of biogeochemical cycles by weather disturbances We focus on disturbances on the synoptic scale (ex., storm).

  9. We have been developing a intermediate complexity ecosystem model representing biogeochemical cycles. 1. Interannual variability of global marine ecosystem 2. Their responses to the global warming 3. Simulation of an iron fertilization experiment We will contribute to SOLAS using our ecosystem models. Summary Thank you.

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