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Trade-offs between sequestration and bioenergy benefits Nicolas VUICHARD (1,2) Philippe CIAIS (2) Luca BELELLI (3) Riccardo VALENTINI (3) (1)CIRED – Nogent.

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Presentation on theme: "Trade-offs between sequestration and bioenergy benefits Nicolas VUICHARD (1,2) Philippe CIAIS (2) Luca BELELLI (3) Riccardo VALENTINI (3) (1)CIRED – Nogent."— Presentation transcript:

1 Trade-offs between sequestration and bioenergy benefits Nicolas VUICHARD (1,2) Philippe CIAIS (2) Luca BELELLI (3) Riccardo VALENTINI (3) (1)CIRED – Nogent (France) (2)LSCE/IPSL – Saclay (France) (3)University of Tuscia – Viterbo (Italy) Growing biofuels over abandoned croplands in the former USSR

2 Abandoned cultivated lands are suitable candidates for bioenergy production (Field, 2008) ► Do not compete with food security ► Dot not induce a carbon debt Bioenergy competes with soil C sequestration but has a higher environmental impact Is there an optimal onset time to start biofuel cultivation, given future climate change and management practices?

3 The end of the USSR resulted into one of the largest crop abandonment of the 20 th century - 20 Mha Hurtt et al., 2006 20 Mha

4 Soil carbon changes are impacted by Crops Recovering grassland Natural grassland Soil carbon + Climate ++ Management + Climate ++ Land-use legacy 1950’s1990’s

5 A potential of 0.5 GtC could be sequestered into the abandonned 20 Mha of croplands New soil C data from abandonned crop fields in Russia

6 Goals Carbon benefit of sequestration by natural steppe recovery Carbon benefit of biofuel due to both: - biofuel can also sequester below ground C - biofuel harvest substitutes to Fossil Fuel Compare recovery vs. biofuel option -> Use a spatially explicit process-based model to address these questions

7 Model set-up

8 The ORCHIDEE global carbon-water-energy model ORCHIDEE SECHIBA energy & water cycle photosynthesis  t = 1 hour LPJ spatial distribution of vegetation (competition, fire,…)  t = 1 year STOMATE vegetation & soil carbon cycle (phénologie, allocation,…)  t = 1 day NPP, biomass, litterfall vegetation types LAI, roughness, albedo soil water, surface temperature, GPP rain, température, humidity, incoming radiation, wind, CO 2 meteorological forcing sensible & latent heat fluxes, CO 2 flux, net radiation output variables prescribed vegetation vegetation types

9 Including crops in ORCHIDEE Same Gridded climate and soil data STICS agronomic Model Library of ≠ crop varieties LUE growth Biomass allocation and yield Water and Nitrogen demand No soil C balance scale : field, months ORCHIDEE global model Generic ecosystem C dynamics with land-use disturbances scale : local => regional => global 1 year => 1000 years Brisson et al. (2002) LAI Root profile Irrigation needs Daily data assimilation of crop parameters into ORCHIDEE

10 Input (spatially explicit) land-use statistics FAO Including land-use change & land management Input N-fertilizer addition statistics USDA Simple agricultural parameterization Harvest -> grains + straw exported Tillage -> Mean Residence Time of soil C pools faster by 30% time 19511993 Recovery period 2000 Orchidee-Stics Orchidee Cultivation period on arable land of former USSR

11 Results

12 Croplands 100% instant. aband. If croplands all maintained after 1993 If croplands all abandoned in 1993 Realistic abandonment scenario gC m -2 yr -1 Sink regional mean Net Carbon Balance changes agriculture 19511993 recovering grassland 2000 Orchidee-SticsOrchidee

13 Sink spatial patterns Regional C gain from 1993 to 2000 373 gC per m 2 Some grid points in the south are net sources, because NPP of steppes is lower than soil carbon input from former crop fields -> we really need spatially explicit modelling

14 Towards realistic estimates Map of the C storage from 1993 to 2000 Abandoned cropland area from 1993 to 2000 C gain from 1993 to 2000 per m 2 64 TgC in 8 years over 17 Mha

15 Sensitivity tests No fertilization during cultivation period => +37% No tillage during cultivation period (no impact on soil decomposition) => -25% 10% of straw remained on plot => -15%

16 Biofuels on the steppe ?

17 Modelling Biofuel on the steppe Ethanol production from natural grassland biomass as in Tilman et al. (2006) ► 1 gC substitutes 0.42 gC Scenario: an abrupt switch to biofuels in 1990 Compare scenario with sequestration by calculating the crossing time t cross t cross = time at wich biofuels deliver more C benefits than sequestration

18 Biofuel production vs steppe recovery sequestration Soil C sequestration in natural steppe Total Bioenergy production Soil C sequestered with Bioenergy production t cross

19 t cross spatial patterns in yrs after 1990

20 Timing of bioenergy implementation If we wait 60-years after abandonment to install biofuels ? Trajectories change... but same t cross Soil C sequestration Bioenergy production Soil C released with bioenergy production t cross

21 Sensitivity to C initial stocks Condition: MRT must remain constant over time This condition could be challenged if Warming accelerates decomposition Tillage must be increased for cultivating biofuels Tilling t0=just after abandonment Tilling t0=60 years after abandonment Never tilled t cross

22 Conclusions Biofuel production looks suitable on abandoned croplands of former USSR Energy = 0.23 EJ per year (0.05% of world demand) Net Carbon balance of biofuels sink of 0.56 Gt C over 60 years - Carbon storage in biofuel soils = 0.08 GtC - Fossil carbon substituted = 0.48 Gt C Net Carbon Storage if steppe recovery sink of 0.3 Gt C over 60 years

23 Crossing date = 11 years, at which biofuels have a better carbon balance than steppe recovery Crossing date is relatively insensitive to timing of implementation under some conditions (no soil warming) Quick benefits

24 Perspectives Generalize to other ecosystems Priority = sugarcane in Brazil Calculate maps of carbon debt in the eventuality of forest clearing Welcome collaborations with real experts !


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