Emulating GCM projections by pattern scaling: performance and unforced climate variability
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Tim Osborn, talk at HELIX 2nd annual conference, Liege, Belgium, September 2015 For more about HELIX, go to: http://helixclimate.eu/home
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Emulating GCM projections by pattern scaling: performance and unforced climate variability
- 1. EMULATING GCM PROJECTIONS BY PATTERN SCALING • PERFORMANCE • UNFORCED CLIMATE VARIABILITY Liege, September 2015 Tim Osborn, Craig Wallace Climatic Research Unit, School of Environmental Sciences, UEA, UK • With contributions from Jason Lowe, Dan Bernie Meteorological Office Hadley Centre, UK
- 2. WHAT IS PATTERN SCALING?
- 3. • Pattern scaling assumes a linear relationship between local climate change & global temperature change • A GCM-simulated “pattern of climate change” is scaled to represent any scenario of global temperature change ΔVx,t ≈ ΔTt . αx
- 4. CMIP3 x 22 CMIP5 x 23 QUMP x 17 Normalised change pa=erns ClimGen • Pa=ern scaling • Changes in precipita.on variability are included
- 5. CMIP3 x 22 CMIP5 x 23 QUMP x 17 Global temperatures Normalised change pa=erns ClimGen • Pa=ern scaling • Changes in precipita.on variability are included
- 6. CMIP3 x 22 CMIP5 x 23 QUMP x 17 Pa=ern scaling Global temperatures Normalised change pa=erns ClimGen • Pa=ern scaling • Changes in precipita.on variability are included
- 7. CMIP3 x 22 CMIP5 x 23 QUMP x 17 Pa=ern scaling Global temperatures Normalised change pa=erns ClimGen • Pa=ern scaling • Changes in precipita.on variability are included
- 8. • Pattern scaling assumes a linear relationship between local climate change & global temperature change • A GCM-simulated “pattern of climate change” is scaled to represent any scenario of global temperature change ΔVx,t ≈ ΔTt . αx • If the linear assumption is correct, the pattern-scaled climate projection should match (emulate) what the GCM would have simulated for that scenario • But, is this assumption valid?
- 9. NO
- 10. In general, NO • But, although it is not perfect, the linear relationship works quite well in many cases • The errors are real, but are often small in comparison to the many other uncertainties
- 12. Climate timeseries (observed or GCM-simulated) are climate response to forcings plus a realisation of unforced (internally- generated) climate variability We’re interested in both but prefer to deal with them separately, not least because you cannot generate a sequence of unforced variability by pattern-scaling For ClimGen, we try to obtain patterns that represent the forced climate response: • Use initial condition ensembles (where available) • Pool simulations across multiple forcing scenarios (all RCPs) • Regress change against global ΔT using all 1951-2100 data Forced climate response & unforced climate variability
- 13. GCM RCP2.6 RCP4.5 RCP6 RCP8.5 CMIP5 GCM1 CMIP5 GCM2 … … … CMIP5GCM21
- 14. Fig. 2 of Osborn et al. (in press) Climatic Change
- 15. Global temperature projection HELIX specific warming levels HadGEM2-ES (RCP8.5) 2°C 4°C 6°C A more specific evaluation of performance: One GCM (HadGEM2-ES) for specific warming levels
- 16. PATTERN SCALING PERFORMANCE • LAND AIR TEMPERATURE
- 22. PATTERN SCALING PERFORMANCE • LAND PRECIPITATION
- 25. FORCED CHANGES IN VARIABILITY • PATTERN-SCALING METRICS OF VARIABILITY
- 26. Pattern scaling: unforced climate variability changes? Pa=ern-‐scale higher moments (e.g. standard deviaGon, skew) • We divide GCM monthly precipitaGon Gmeseries by low-‐pass filter • Represent the high-‐frequency deviaGons with a gamma distribuGon • Scale changes in gamma shape parameter with ΔT Fig. 1 of Osborn et al. (in press) Climatic Change Relativechangein
- 27. How to utilise projected changes in distribution shape? Perturb the observations Example applicaGon • SE England grid cell, HadCM3 GCM, July precipitaGon • For ΔT = 3°C, pa=ern-‐scaling gives 45% reducGon in mean precipitaGon • But also 62% reducGon in gamma shape param. of monthly precipitaGon Fig. 1 of Osborn et al. (in press) Climatic Change Observed sequence Sequence x 0.55 Sequence x 0.55 Sequence x 0.55 & perturbed to have 62% lower shape
- 28. Is there agreement in GCM-simulated changes of variability? • MulG-‐model agreement of 22 CMIP3 GCMs • FracGon of models showing increased gamma shape of July precipitaGon Units: fraction Based on Osborn et al. (in press) Climatic Change
- 29. MPI-ESM-MR GCM for RCP8.5, single run Future frequency > 0.08 means the 8%ile is more frequent than during the 1951-2000 reference period See paper for equivalent results for 4, 6, 12, 20%iles Fig. 3 of Osborn et al. (in press) Climatic Change Projected changes in frequency of very dry summer months
- 32. MPI-ESM-MR GCM for RCP8.5, single run Fig. 3 of Osborn et al. (in press) Climatic Change 1951-2000 reference
- 38. CLOSING REMARKS • GCMs can be approximately emulated by pattern- scaling • Better for temperature than for precipitation • Precipitation is fine if patterns are diagnosed from suitable runs • Don’t diagnose patterns from RCP2.6 & extrapolate to large warming • Don’t falsely penalise pattern-scaling performance by evaluating against a single GCM run • Pattern-scaling has been extended to project changes in unforced climate variability • For precipitation in ClimGen, but could be extended to temperature variability • Perturb the observed monthly climate record by pattern-scaled changes in both mean & variability