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Fires and the Contemporary Global Carbon Cycle Guido van der Werf (Free University, Amsterdam, Netherlands) In collaboration with: Jim Randerson (UCI,

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Presentation on theme: "Fires and the Contemporary Global Carbon Cycle Guido van der Werf (Free University, Amsterdam, Netherlands) In collaboration with: Jim Randerson (UCI,"— Presentation transcript:

1 Fires and the Contemporary Global Carbon Cycle Guido van der Werf (Free University, Amsterdam, Netherlands) In collaboration with: Jim Randerson (UCI, CA, USA) Louis Giglio (SSAI, MD, USA) Prasad Kasibhatla (Duke University, NC, USA) Jim Collatz (NASA GSFC, MD, USA)

2 Main Objectives 1.Quantify the contemporary amount of biomass burned on a global scale 2.Assess the role of biomass burning in the global CO 2 and CH 4 cycle 3.Determine the climate sensitivity of biomass burning

3 ‘Classical’ approach: Emissions = Σ x,t A × B × CC × EF Giglio et al, submitted to ACPD

4 Net Primary Production Allocation =f(treecover) Aboveground Biomass C Belowground Biomass C Combustion Belowground Litter C Aboveground Litter C f(A,CC,M)f(A,CC) Respiration Fuelwood collection Herbivore consumption A = area burnt CC = combustion completeness M = fire induced mortality Fires embedded in the CASA satellite-driven biogeochemical model

5 Annual fire emissions, averaged over the 1997 – 2004 period

6 Annual fire emissions as percentage of NPP, averaged over the 1997 – 2004 period

7 Fuel consumption as calculated by CASA Emission (g) per m 2 burned

8 On a global scale, IAV in burned area and emissions are decoupled BA driven by savannas Emissions driven by forest fires (including deforestation) 1997 peat burning in Asia

9 Observed CO anomalies Boreal region CO (forward modeling) Atmospheric CO as a constrain on fire emissions

10 CO: forward modeling optimized in inversion to fit observations CO 2 : fires explain ~2/3 of the growth rate anomaly (60% SE-Asia, 30% C+S America, 10% Boreal) CH 4 : fires explain most of the growth rate anomaly. Contribution of IAV in fire activity to CO 2 and CH 4 growth rates

11 Mismatch in seasonality between top-down and bottom-up observations (southern Africa) Atmosphere: peak in September - October Satellite surface observations: peak in June – July - August

12 Effect of IAV in precipitation on fire activity

13 Concluding remarks 1.Global (vegetation) fire emissions as calculated by our modeling framework is ~2.5 Pg C / year, largest uncertainties in deforestation regions 2.IAV in fire emissions contributed significantly to variability in the 1997-2001 growth rate of CO 2 and CH 4. 3.IAV in fire emissions is dominated by IAV in forest fires. Implications: IAV in burned area and emissions are decoupled IAV in CO and CH 4 is larger than IAV in C or CO 2 4.(Multi-specie) inversions and high resolution (deforestation) fire modelling ideally employed to further improve estimates

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