Post on 28-Mar-2015
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Evaluating water vapour in HadAM3 using 20 years of satellite data
Richard Allan, Mark RingerMet Office, Hadley Centre for Climate Prediction and
ResearchTHANKS TO Tony Slingo (ESSC) and John Edwards
– RH distribution and variability crucial to water vapour and cloud feedback
– Importance of water vapour feedback
» strong positive feedback
» robust physical basis
» links to cloud feedback
– HadAM3 Simulations of UTH radiances
– Evaluation of HadAM3 using satellite data
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dIv
dOLR/dRH
(Wm-2%-1)
RH (%)
Sensitivity of OLR to RH (using ERA-15) (Allan et al. 1999, QJ, 125, 2103)
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Robust nature of the water vapour feedback
Insensitive to resolution (Ingram 2002, J Clim,15, 917-921)
Feedback inferred after Pinatubo consistent with observations and climate change experiments
From Soden et al 2002, Science, 296, 727.
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Is water vapour feedback really consistent between models?
- dOLRc/dTs ~ 2 Wm-2K-1; dOLR/dTs uncertain
Cess et al. 1990, JGR, 95, 16601.
? Consistent water vapour feedback, inconsistent cloud feedback
-Same dOLRc/dTs in GFDL /HadAM3 models (~2 Wm-2K-1), differing height dependent T and q response...
Allan et al. 2002, JGR, 107(D17), 4329, doi:10.1029/2001JD001131.
Also, evidence that models cannot simulate recent changes in:
- temperature lapse rate (Brown et al, 2000, GRL, 27, 997; Gaffen et al 2000, Science, 287, 1242)
- cloud radiative effects (Wielicki et al, 2002, Science, 295, 841)
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Large changes in OLR from 7 independent satellite instruments (Wielicki et al, 2002)
HadAM3/HadCM3 cannot simulate recent changes in cloudy portion of tropical radiation budget even when current climate forcings are applied (Allan & Slingo 2002, GRL, 29(7), doi:
10.1029/2001GL014620)
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Experiment &Observations
- Ensemble of AMIP-type HadAM3 runs
- Standard res, 19 levels, 1978-1999 - HadISST SST/sea ice forcing
- Radiance code active each rad-time-step (see Ringer et al. (2002) QJ, accepted for details)
- Additional forcings run
- Multiple satellite measurements provide: - column water vapour, CWV
[SMMR 1979-84, SSM/I 1987-99] - clear-sky OLR
[ERBS (1985-89), ScaRaB (1994/5), CERES (1998)]
- UTH channel brightness temperature, T6.7 [HIRS 1979-1998]
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Climatological mean over 60oS-60oN oceans
The mean HadAM3 value is shown and then the HadAM3 minus observation climatological bias is calculated as the mean and the RMS difference of all grid-points within the region considered that contain valid observational values.
BT12 (1979-98); OLRc (1985-89); CWV (1979-84;1988-98)
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OBSERVATIONS HadAM3
500
T6.7
OLRc
CWV
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OBSERVATIONS HadAM3
500
T6.7
OLRc
CWV
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DJF (HadAM3-OBS) JJA
500
T6.7
OLRc
CWV
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Interannual monthly anomalies over the tropical oceans
-Remove effects of changes in dynamic regime on the local variability by averaging over tropical oceans.
-Maximise reliability of satellite data
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Interannual monthly anomalies over the tropical oceans (+additional
forcings)
- Additional forcings (volcanic, solar, ozone, GHG)
- clear-sky OLR highly sensitive to volcanic aerosol and decadal trends in well mixed greenhouse gases
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T_6.7 bias (K) OLRc bias (Wm-2)
Sensitivity to clear-sky sampling: Jan 1998
Type II “Type I”Climatological differences:
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Clear-sky sampling: interannual variability
Light blue: Type I (weighted by clear-sky fraction)
Dark Blue: Type II (unweighted mean)
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Summary Simulations of satellite brightness
temperatures sensitive to RH Consistent decadal variability
suggests small RH realistic Clear-sky sampling important for
infrared channel climatologies but not interannual variability
Overactive circulation in HadAM3
Note of caution:– can multiple satellite intercalibration
artificially remove decadal trends?
– Changes in atmos. T also influences T6.7
decadal fluctuations