1. Why Climate Modelers Think We Need a Really, Really Big Computer Phil Jones Climate, Ocean and Sea Ice Modeling (COSIM) Climate Change Prediction Program Co-PI SciDAC CCSM Collaboration

2. Climate System

3. Climate Modeling Goals Understanding processes and how they interact (only one on-going experiment) Attribution of causes of observed climate change Prediction –Natural variability (ENSO, PDO, NAO) –Anthropogenic climate change (alarmist fearmongering) – IPCC assessments –Rapid climate change Input on energy policy

4. Climate Change IPCC TAR 2001

5. Greenhouse Gases Energy production Bovine flatulence Presidential campaigning

6. Rapid Climate Change

7. Polar and THC

8. State of the Art T85 Atmosphere (150km) Land on same 1 degree ocean (100km) Sea ice on same Physical models only – no biogeochemistry 5-20 simulated years per CPU day –Limited number of scenarios

9. Community Climate System Model Ocean POP Ice CICE/CSIM Atmosphere CAM Land LSM/CLM Flux Coupler 7 States 10 Fluxes 6 States 6 Fluxes 4 States 3 Fluxes 7 States 9 Fluxes 6 Fluxes 11 States 10 Fluxes 6 States 13 Fluxes 6 States 6 Fluxes Once per day hour NSF/DOE Physical Models (No biogeochem) 150km 100km

10. Performance

11. Performance Portability Vectorization –POP easy (forefront of retro fashion) –CAM, CICE, CLM Blocked/chunked decomposition –Sized for vector/cache –Load balanced distribution of blocks/chunks –Hybrid MPI/OpenMP –Land elimination

12. Performance Limitations Atmosphere –Dynamics (spectral or FV), comms –Physics, flops Ocean –Baroclinic, 3d explicit, flops/comms –Barotropic, 2d implicit, comms All –timestep

13. Prediction and Assessment Many century-scale simulations (>2500yrs) @~5yrs/day Cycle vampires: Many dedicated cycles at computer centers

14. Attribution Stott et al, Science 2000 “Simulations of the response to natural forcings alone … do not explain the warming in the second half of the century” “..model estimates that take into account both greenhouse gases and sulphate aerosols are consistent with observations over this*period” - IPCC 2001

15. The annual mean change of temperature (map) and the regional seasonal change (upper box: DJF; lower box: JJA) for the scenarios A2 and B2

16. The annual mean change of precipitation (map) and the regional seasonal change (upper box: DJF; lower box: JJA) for the scenarios A2 and B2

17. If elected, we plan… High resolution –Cloud resolving atmosphere (10km) –Eddy-resolving ocean (<10km) –Regional prediction Fully coupled biogeochemistry –Source-based scenarios More scenarios, more ensembles –Uncertainty quantification

18. Towards Regional Prediction

19. Resolution and Precipitation CCM3 extreme precipitation events depend on model resolution. Here we are using as a measure of extreme precipitation events the 99th percentile daily precipitation amount. Increasing resolution helps the CCM3 reproduce this measure of extreme daily precipitation events. (DJF) precipitation in the California region in 5 simulations, plus observations. The 5 simulations are: CCM3 at T42 (300 km), CCM3 at T85 (150 km), CCM3 at T170 (75 km), CCM3 at T239 (50 km), and CAM2 with FV dycore at 0.4 x 0.5 deg.

20. Eddy-Resolving Ocean 0.1 deg0.28 deg Obs2 deg

21. Only decades…

23. Chemistry, Biogeochemistry Atmospheric chemistry –Aerosols, ozone, GHG Ocean biogeochemistry –Phytoplankton, zooplankton, bacteria, elemental cycling, trace gases, yada, yada… Land Model –Carbon, nitrogen cycling, dynamic vegetation Source-based scenarios –Specify emissions rather than concentrations Sequestration strategies (land and ocean)

24. Aerosol Uncertainty

25. Atmospheric Chemistry Gas-phase chemistry with emissions, deposition, transport and photo- chemical reactions for 89 species. Experiments performed with 4x5 degree Fvcore – ozone concentration at 800hPa for selected stations (ppmv) Mechanism development with IMPACT –A) Small mechanism (TS4), using the ozone field it generates for photolysis rates. –B) Small mechanism (TS4), using an ozone climatology for photolysis rates. –C) Full mechanism (TS2), using the ozone field it generates for photolysis rates. Zonal mean Ozone, Ratio A/C Zonal mean Ozone, Ratio B/C

26. Ocean Biogeochemistry Iron Enrichment in the Parallel Ocean Program Surface chlorophyll distributions in POP for 1996 La Niña and 1997 El Niño

27. Global DMS Flux from the Ocean using POP The global flux of DMS from the ocean to the atmosphere is shown as an annual mean. The globally integrated flux of DMS from the ocean to the atmosphere is 23.8 Tg S yr-1.

28. Increasing the deficit (10 10 -10 12 ) Resolution (10 3 -10 5 ) –x100 horiz, x10 timestep, x5-10 vert Completeness (10 2 ) –Biogeochem (30-100 tracers) Fidelity (10 2 ) –Better cloud processes, dynamic land, others Increase length/number of runs(10 3 ) –Run length (x100) –Number of scenarios/ensembles (x10)

29. Storage Atmosphere –T85 29 GB/sim-yr, 0.08 GB/tracer –T170 110 GB/sim-yr, 0.3 GB/tracer Ocean –1  1.7 GB/sim-yr, 0.2 GB/tracer –0.1  120 GB/sim-yr, 17 GB/tracer

31. Beyond Moore’s Law Algorithms –50% of past improvements –Tracer-friendly algorithms (inc remap advect) –Subgrid schemes –Implicit or other methods

32. Remapping Advection monotone multiple tracers free 2 nd order

33. Subgrid Orography Scheme Reproduces orographic signature without increasing dynamic resolution Realisitic precipitation, snowcover, runoff Month of March simulated with CCSM

34. Comparison of sea ice shear (%/day) from CICE (a,c) and ‘old’ (b,d) models Feb 20, 1987 Feb 26, 1987 (a) (c) (b) (d)

35. Beyond Moore’s Law New architectures –Improved single-processor performance –Scaling vs. throughput