1 Changes in global net radiative imbalance 1985-2012 Richard P. Allan, Chunlei Liu (University of Reading/NCAS Climate); Norman Loeb (NASA Langley); Matt.

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Presentation transcript:

1 Changes in global net radiative imbalance Richard P. Allan, Chunlei Liu (University of Reading/NCAS Climate); Norman Loeb (NASA Langley); Matt Palmer (Met Office) GEWEX 7 th International Conference, 16 th July 2014

At what rate is Earth heating? Trenberth et al. (2014) J Clim o C Surface Temperature Upper ocean (Wm -2 )

Combining Earth Radiation Budget data and Ocean Heat Content measurements Tie 10-year CERES record with SORCE TSI and ARGO-estimated heating rate minor additional storage terms Variability relating to ENSO reproduced by CERES and ERA Interim Ocean heating rate sensitive to dataset and sampling What about prior to 2000? Loeb et al. (2012) Nat. Geosci.Loeb et al. (2012) Nat. Geosci. See also Hansen et al. (2011) ACPHansen et al. (2011) ACP unpublished Loeb et al. (2012) Nat. Geosci.

Reconstructing global radiative fluxes prior to 2000 ERBS/CERES variability CERES monthly climatology ERA Interim spatial anomalies Combine CERES/ARGO accuracy, ERBS WFOV stability and reanalysis circulation patterns to reconstruct radiative fluxes ERBS WFOV CERES ERA Interim

Use reanalyses or models to bridge gaps in record (1993 and 1999/2000) ERA Interim trends suspect. Use model… UPSCALE simulations (obs. SST, sea ice & realistic radiative forcings) “OBS” Net less sensitive to method than OLR/ASR Outgoing Longwave Radiation Anomalies (Wm -2 )

Changes in imbalance in models & observations 0.62±0.43 Wm -2 Imbalance: (Wm -2 ) Allan et al. (2014) in prep Volcano La Niña El Niño 0.34±0.67 Wm -2

Outgoing Longwave Radiation

Absorbed Shortwave Radiation

NET Radiation

Preliminary results Heating of Earth continues at rate of ~ 0.6 Wm -2 Current variability in TOA radiation ( ) Net radiative flux imbalance fairly stable –Requires anchoring to ARGO ocean heating rate + minor terms –Influence of Pinatubo and ENSO –~ 0.3 Wm -2 higher in than period Distinct East Pacific signal in ΔT and ΔN Radiative forcing alone can’t explain surface warming slowdown: internal variability important Next steps: combining with reanalyses energy transports to estimate surface fluxes

CERES/Argo Net Flux Surface Flux Estimates of Surface Flux

Changes in Earth’s Energy balance Key variable linking radiative forcing/ feedbacks and ocean heat uptake Global energy and water cycle coupling –Fast and slow precipitation responses O’Gorman et al. (2012); Allan et al. (2014) Surv. Geophys O’Gorman et al. (2012); Allan et al. (2014) Diagnostic of changes in cloud, aerosol, etc Diagnosing Earth’s Energy Pathways in the Climate system: DEEP-C projectDEEP-C project N=ΔF–ΔT/λ D ΔTΔT

Earth Radiation Budget Satellite Data Wong et al. (2006) J ClimWong et al. (2006) J Clim; Wielicki et al. (2002) ScienceWielicki et al. (2002) Science 20°N to 20°S

Reconstructed Net Flux (Wm -2 ) 0.62 Wm -2 See also: Wong et al. (2006) J Clim; Wielicki et al. (2002) ScienceWong et al. (2006) J ClimWielicki et al. (2002) Science

+ve RF trend 0 RF trend -ve RF trend Use AR5 RF Analysis using simple energy balance model N=ΔF–YΔT D ΔT N ΔTΔT ΔTdΔTd

Combined CERES/Argo data Incoming Solar: SORCE Level 3 V10 Reflected Shortwave/Outgoing Longwave from EBAF –(v2.6r  v2.8  V3…) Added errors in quadrature to give ± 0.43 Wm -2 –Argo m dOHCA/dt = 0.47 ± 0.38 Wm -2 ( ) –>2000m ~ 0.07 ± 0.05 Wm -2 –Heating/melting ice, heating land/atmos ~ 0.04 ± 0.02 Wm -2 –CERES standard error ± 0.2 Wm -2 Jan 2001-Dec 2010: 0.50 ± 0.43 Wm -2 (EBAF V2.6r) March 2000 – February 2013: 0.60 ± 0.43 Wm -2 (EBAF V2.8) CERES scanner data: cloud mask  clear-sky fluxes; not possible for ERBS wide-field of view

Updated CERES satellite data Issues with sampling, radiance to flux conversion, calibration, etc Correction for degradation of shortwave filter Correction also improves physical consistency of trends in daytime longwave We used version CERES_EBAF-TOA_Ed2.6r; currently v2.8

Is the temperature record wrong or are computer models inaccurate? Can comparisons tell us about how sensitive climate is to radiative forcing? e.g. Otto et al. (2013) Nature GeosciOtto et al. (2013) Nature Geosci Spatial infilling of data gaps influences trends in surface temperature (Cowtan & Way, 2013 QJRMS) and ocean heat content (Lyman & Johnson 2014 J. Clim.)Cowtan & Way, 2013 QJRMSLyman & Johnson 2014 J. Clim.) Graph by Chunlei Liu

Changes in top of atmosphere radiative fluxes since 1985 Net Imbalance Anomaly (Wm -2 ) Research in DEEP-C project at Reading…DEEP-C project Chunlei Liu

Wong et al. (2006) J Clim