Page Comparison

...

1. Idealized experiments designed to quantify carbon cycle feedback sensitivities
   
   1. Idealized 1% per year CO₂, BGC coupling, C-driven, constant N-dep, aerosols, CH₄ and other GHGs, no crops or LUC (140 y)
   2. Idealized 1% per year CO₂, RAD coupling, C-driven, constant N-dep, aerosols, CH₄ and other GHGs, no crops or LUC (140 y)
   3. Idealized 1% per year CO₂, FULL coupling, C-driven, constant N-dep, aerosols, CH₄ and other GHGs, no crops or LUC (140 y)
2. Idealized experiments designed to quantify the influence of nutrient cycles on carbon cycle feedback sensitivities
   1. Idealized 1% per year CO₂, BGC coupling, C-driven, increasing N-dep, aerosols, CH₄ and other GHGs, no crops or LUC (140 y)
   2. Idealized 1% per year CO₂, RAD coupling, C-driven, increasing N-dep, aerosols, CH₄ and other GHGs, no crops or LUC (140 y)
   3. Idealized 1% per year CO₂, FULL coupling, C-driven, increasing N-dep, aerosols, CH₄ and other GHGs, no crops or LUC (140 y)
3. Preindustrial Pre-industrial control experiment to quantify residual drift in climate and biogeochemical cycles
   1. 300–1000 500–1000 y control, C-driven, constant N-dep, aerosols, CH₄ and other GHGs, no crops or LUC (300–1000 500–1000 y)
4. Historical experiments designed to evaluate model performance and investigate emergent constraints
   1. Historical CO₂, BGC coupling, C-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (165 y)
   2. Historical CO₂, RAD coupling, C-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (165 y)
   3. Historical CO₂, FULL coupling, C-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (165 y)
   4. Historical CO₂, BGC coupling, E-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (165 y)
   5. Historical CO₂, RAD coupling, E-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (165 y)
   6. Historical CO₂, FULL coupling, E-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (165 y)
5. Future scenario experiments to quantify future changes in carbon cycle storage for given CO₂ emission trajectories
   1. SSP5-8.5 to 2100, BGC coupling, C-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (85 y)
   2. SSP5-8.5 to 2100, RAD coupling, C-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (85 y)
   3. SSP5-8.5 to 2100, FULL coupling, C-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (85 y)
   4. SSP5-8.5 to 2100, BGC coupling, E-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (85 y)
   5. SSP5-8.5 to 2100, RAD coupling, E-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (85 y)
   6. SSP5-8.5 to 2100, FULL coupling, E-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (85 y)
6. Extension of future scenario experiments to quantify non-linear carbon cycle feedbacks, strengthening of biogeophysical & biogeochemical feedbacks, and shifting strength of ocean and land feedbacks
   1. SSP-8.5 to 2300, BGC coupling, C-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (200 y)
   2. SSP-8.5 to 2300, RAD coupling, C-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (200 y)
   3. SSP-8.5 to 2300, FULL coupling, C-driven, increasing N-dep, aerosols, CH₄ and other GHGs, dynamic crops and LUC (200 y)

...