1. Changes in Water Vapour, Clear-sky Radiative Cooling and Precipitation
Richard P. Allan
Environmental Systems Science Centre, University of Reading, UK
Thanks to Brian Soden

2. Climate Impacts
How the hydrological cycle responds to a radiative imbalance is crucial to society (e.g. water supply, agriculture, severe weather)

3. Changing character of precipitation
Convective rainfall draws in moisture from surroundings
Moisture is observed & predicted to increase with warming ~7%K-1 (e.g. Soden et al. 2005, Science)
Thus convective rainfall also expected to increase at this rate (e.g. Trenberth et al BAMS)

4. Changes in Q expected to be ~3 Wm-2K-1 (e.g. Allen and Ingram, 2002)
Global precipitation (P) changes constrained by atmospheric net radiative cooling (Q)
Changes in Q expected to be ~3 Wm-2K-1 (e.g. Allen and Ingram, 2002)
7 % K-1
- Changes in P with warming estimated to be ~3%K-1
- Consistent with model estimates (~2%K-1)
∆P (%)
∆T (K)
Held and Soden (2006) J. Clim

5. Precipitation linked to clear-sky longwave radiative cooling of the atmosphere

6. Increased moisture enhances atmospheric radiative cooling to surface
ERA40 NCEP
dSNLc/dCWV ~ 1 ─ 1.5 W kg-1
SNLc = clear-sky surface net down longwave radiation
CWV = column integrated water vapour
Allan (2006) JGR 111, D22105

7. Increase in clear-sky longwave radiative cooling to the surface
∆SNLc (Wm-2)
CMIP3
CMIP3 volcanic
NCEP ERA40
SSM/I-derived
~ +1 Wm-2 per decade

8. Tropical Oceans dCWV/dTs ~2 ─ 4 mm K-1 dSNLc/dTs ~3 ─ 5 Wm-2K-1 AMIP3
CMIP3 non-volcanic
CMIP3 volcanic
Reanalyses/ Observations

9. Increase in atmospheric cooling over tropical ocean descent ~4 Wm-2K-1
AMIP3
CMIP3 non-volcanic
CMIP3 volcanic
Reanalyses/ Observations

10. Increased moisture (~7%/K) Increased radiative cooling
 increased convective precipitation
Increased radiative cooling
 smaller mean rise in precipitation (~3%/K)
Implies reduced precipitation in subsidence regions (less light rainfall?)
Locally, mixed signal from the above
Method: Analyse separately precipitation over the ascending and descending branches of the tropical circulation

11. Tropical Precipitation Response
Model precipitation response smaller than the satellite observations
see also Wentz et al. (2007) Science
GPCP CMAP
AMIP3
Allan and Soden, 2007, GRL

12. Tropical Subsidence regions dP/dt ~ -0.1 mm day-1 decade-1)
OCEAN LAND
AMIP SSM/I GPCP CMAP
Allan and Soden, 2007, GRL

13. Projected changes in Tropical Precipitation
Allan and Soden, 2007, GRL

14. Conclusions
Heavy rainfall and areas affected by drought expected to increase with warming [IPCC 2007]
Heavy precipitation increases with moisture ~7%K-1
Mean Precipitation constrained by radiative cooling
Models simulate increases in moisture (~7%K-1) and clear-sky LW radiative cooling (3-5 Wm-2K-1)
But large discrepancy between observed and simulated precipitation responses…
Model inadequacies or satellite calibration/algorithm problems?
Changes in evaporation and wind-speed over ocean at odds with models? (Yu and Weller, 2007 BAMS; Wentz et al. 2007, Science; Roderick et al GRL)
Observing systems: capturing decadal variability problematic

15. Extra slides…

16. Outline Clear-sky radiative cooling: Earth’s radiation budget Method:
radiative convective balance
atmospheric circulation
Earth’s radiation budget
Understand clear-sky budget to understand cloud radiative effect
Method:
analyse relationship between water vapour, clear-sky radiative cooling and precipitation
Satellite observations, reanalyses, climate models (atmosphere-only/fully coupled)

17. Models reproduce observed increases in total column water vapour
Atmosphere-only and fully coupled climate models are able to reproduce the observed variations in column integrated water vapour and its dependence on surface temperature over the oceans.
Integrated water vapour is a key variable since it affects:
Precipitation over convective regions
Radiative cooling of the atmosphere to the surface
Global precipitation through a combination of the above
Strongly positive water vapour feedback
With regards to the last point, column integrated water vapour is sensitive to moisture in the lower troposphere while changes in moisture throughout the middle and upper troposphere are more important for water vapour feedback and it is important to ensure that models accurately capture changes in water vapour at these levels.

18. Tropical Oceans Ts CWV LWc SFC 1980 1985 1990 1995 2000 2005 ERA40
NCEP
SRB
HadISST Ts
CWV
LWc
SFC
SMMR, SSM/I
Derived:SMMR, SSM/I, Prata)
Allan (2006) JGR 111, D22105

19. Clear-sky OLR with surface temperature: + ERBS, ScaRaB, CERES; SRB
Calibration or sampling?

20. Tropical Oceans ERA40 NCEP SRB Surface Net LWc HadISST Clear-sky OLR
Clear-sky Atmos LW cooling
QLWc
HadISST
ERBS, ScaRaB, CERES
Derived
Allan (2006) JGR 111, D22105

21. Linear least squares fit
ERA40 NCEP
Linear least squares fit
Tropical ocean: descending regime
Dataset dQLWc/dTs Slope
ERA ±0.5 Wm-2K-1
NCEP 4.2±0.3 Wm-2K-1
SRB 3.6±0.5 Wm-2K-1
OBS 4.6±0.5 Wm-2K-1

22. Implications for tropical precipitation (GPCP)?
GPCP P
ERA40 QLWc
OBS QLWc
Pinatubo?

23. Comparison of AMIP3 models, reanalyses and observations over the tropical coeans

24. Also considering coupled model experiments including greenhouse gas and natural forcings

25. Clear-sky vs resolution

26. Sensitivity study
Based on GERB- SEVIRI OLR and cloud products over ocean:
dOLRc/dRes ~0.2 Wm-2km-0.5
Suggest CERES should be biased low by ~0.5 Wm-2 relative to ERBS

27. Links to precipitation