1 / 14

Cloud-climate feedbacks: what we think we know and why we think we know it

Cloud-climate feedbacks: what we think we know and why we think we know it. David Mansbach 14 April 2006. T 2 4. T 2 4. T 2 <T 0 (slightly). T 1 <T 0. T 1 4. T 1 4. T 0 4. Clouds, in general and today Greenhouse effect, albedo effect, and satellite measurements

portia
Télécharger la présentation

Cloud-climate feedbacks: what we think we know and why we think we know it

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Cloud-climate feedbacks:what we think we know and why we think we know it David Mansbach 14 April 2006 T24 T24 T2<T0 (slightly) T1<T0 T14 T14 T04

  2. Clouds, in general and today • Greenhouse effect, albedo effect, and satellite measurements • Cloud changes in a perturbed climate • Very wide range of scales and processes involved • Modeling • Parameterize clouds and take GHG-forced runs as a predictions • Parameterizations inspired by physical principles but lead to errors compared to validation • Observations • Understand observed cloud changes to variability of specific conditions • Merge observed cloud tendencies with modeled large-scale changes or conceptually suggested changes • Trade-offs

  3. Longwave forcing: cloud greenhouse effect and cloud albedo effect • Thickness, water/ice distribution, sun angle affect how much cloud reflects sunlight (its albedo) • As a cloud gets thicker, it acts like a blackbody: absorbing at all wavelengths and emitting according to T4 • Higher clouds -- in cold upper atmosphere -- emit less IR/longwave radiation to space, and keep more energy in the Earth system T24 T2<<T0 T24 T2<T0 (slightly) T1<T0 T14 T14 T04

  4. Bony et al. 2004/Emanuel 1994 Increasing SST Tropical and extratropical clouds Area of ascent is small; area of decent is large Cloud cover is greater in areas of descent, and lower in altitude Bony et al. 2006/Cotton 1990 Frontal systems form a variety of clouds Nature strength of storms determines clouds

  5. Annual ERBE Net Radiative Cloud Forcing • Define cloud radiative forcing at any point as the difference in outgoing radiation with a cloud present minus that with clear sky • Satellite data such as ERBE show net effect of cloud forcing is dominated by SW effect; CRF ~ -20 W m-2 So now we just need to decide how clouds will change in the future... from Randall, 2004

  6. Changing clouds, changing cloud radiative forcing • Overall effects of clouds depend on myriad processes -- ie, thermodynamic, microphysical, optical, convective, dynamic • Many effects can be hypothesized • ie CO2x2 -> more evaporation, -> more cloud liquid water -> more SW reflectivity -> negative feedback (ie Somerville and Remer 1984) • cf: CO2x2 -> warmer SST -> breakup of SC, greater areas of deep convection -> positive feedback • Cloud processes operate on some small scales -- think of a thunderstorm in the distance or wispy clouds overhead • More condensed water generally means more optically thick clouds -- ie, more absorption and emission of longwave -- and affects refletion • Shortwave reflectivity also depends on number of droplets -- sunlight will be reflected more if there are many small droplets (also leads to interplay with aerosols!) from NASA

  7. That’s why we have models • to look at global CRF changes, try using a global model • although scales of individual clouds might be ~100m or ~1 km, climate model resolution ~100km • parameterizations link large-scale climate to cloud properties based on observations and theory • also conserve important properties, such as moisture, energy, etc. • easier said than done -- larger-scale conditions do not necessarily fully determine actual cloud fields; radiative impacts and feedbacks could be considerable • GCM-simulated current cloud climatology is often obviously unrealistic CTP Schmidt et al 2006

  8. Different cutting-edge models also don’t agree precisely Although spread is large, modern models predict a positive cloud feedback to global warming, meaning that future cloud forcing is less negative (clouds will not cool the Earth system as much as today) clouds total water vapor aerosols lapse rate lapse rate w/water vapor Bony et al. 2006

  9. Concntrating on different models’ cloud response to forcing SCRF SCRF LCRF LCRF SCRF SCRF LCRF LCRF Williams et al. 2006

  10. Using observations to inform discussion of clouds in future climate • Using years of satellite and reanalysis data, plot average cloud properties as functions of temperature advection and vertical velocity • These data are for conditions of SST and lower-tropospheric static stability in “normal”/moderate conditions • This allows for a sort of empirical partial derivative of various cloud properties Norris + Iacobellis (2 slides) - compositing methods and diff regimesfinal estimates in ‘most likely’ scenarios Norris and Iacobellis 2005

  11. for mid-troposphere vertical velocity for stronger storm track for surface temperature advection • even if GCM clouds are unrealistic, dynamical predictions can be combined with CRF observations • General inferences from past polar amplification and known storm dynamics, as well as a GCM (Dai et al. 2001), suggest storm track weakening (less extreme vertical velocity) along with warmer SST and little change in vertical stability -> less cloudiness, thinner clouds • modeled temperature changes would lead to less broad marine stratocumulus and less marine fog -> less SW CRF, positive forcing Norris and Iacobellis 2005

  12. net SW flux net LW flux net precip flux weak storms moderate storms strong storms Other observations relevant to midlatitude CRF changes Tselioudis and Rossow, 2006

  13. net SW flux net LW flux net precip flux weak storms moderate storms strong storms Implications of observed CRF tendencies • a GCM (Carnell and Senior 1998) predicts fewer weak and moderate storms, but more strong storms • implied additional SW cooling is 0 to 3.5 W m-2in different areas (fewer clouds, but more reflective) • implied additional LW warming is 0.1 to 2.2 W m-2(fewer clouds, but higher) • overall increase in strength dominates, leads to global cloud COOLING of ~1 W m-2 • analysis of cloud response to circulation and temperature changes is consistent with other study, but choice of modeled circulation changes are different • if these midlatitude changes were factored into Norris & Iacobellis’s figures, total CRF would still be positive, but less so, because of thermodynamic response

  14. Annual ERBE Net Radiative Cloud Forcing Tradeoffs • Global feedbacks of clouds unknown; depends on myriad processes on various scales • Physical mechanisms can be hypothesized to support SW and LW feedbacks of any sign • The latest round of models predict positive cloud feedback; some observational analysis shows consistent physical reasoning for this • Model spread is large; model clouds still have many errors • How predictable are clouds really?

More Related