Home
  >  
Section 37
  >  
Chapter 36,629

How may low-cloud radiative properties simulated in the current climate influence low-cloud feedbacks under global warming?

Brient, F.; Bony, S.

Geophysical Research Letters 39(20)

2012

ISSN/ISBN: 0094-8276
DOI: 10.1029/2012gl053265
Accession: 036628188
Download citation:  
Text
  |  
BibTeX
  |  
RIS
The influence of cloud modelling uncertainties on the projection of the tropical low-cloud response to global warming is explored by perturbing model parameters of the IPSL-CM5A climate model in a range of configurations (realistic general circulation model, aqua-planet, single-column model). While the positive sign and the mechanism of the low-cloud response to climate warming predicted by the model are robust, the amplitude of the response can vary considerably depending on the model tuning parameters. Moreover, the strength of the low-cloud response to climate change exhibits a strong correlation with the strength of the low-cloud radiative effects simulated in the current climate. We show that this correlation primarily results from a local positive feedback (referred to as the beta feedback ) between boundary-layer cloud radiative cooling, relative humidity and low-cloud cover. Based on this correlation and observational constraints, it is suggested that the strength of the tropical low-cloud feedback predicted by the IPSL-CM5A model in climate projections might be overestimated by about fifty percent.

PDF emailed within 0-6 h: $19.90




Related References

Wild, M.; Hakuba, M.Z.; Folini, D.; Dörig-Ott, P.; Schär, C.; Kato, S.; Long, C.N. 2019: The cloud-free global energy balance and inferred cloud radiative effects: an assessment based on direct observations and climate models Climate Dynamics 52(7): 4787-4812
Bretherton, C S.; Blossey, P N.; Stan, C 2014: Cloud feedbacks on greenhouse warming in the superparameterized climate model SP-CCSM4 Journal of Advances in Modeling Earth Systems 6(4): 1185-1204
Rossow, W.B.; Lacis, A.A. 1990: Global, seasonal cloud variations from satellite radiance measurements. II: cloud properties and radiative effects Journal of Climate 3(11): 1204-1253
Huang, X.; Chen, X.; Potter, G.L.; Oreopoulos, L.; Cole, J.N.S.; Lee, D.; Loeb, N.G. 2014: A Global Climatology of Outgoing Longwave Spectral Cloud Radiative Effect and Associated Effective Cloud Properties Journal of Climate 27(19): 7475-7492
Narenpitak, P; Bretherton, C S.; Khairoutdinov, M F. 2017: Cloud and circulation feedbacks in a near-global aquaplanet cloud-resolving model Journal of Advances in Modeling Earth Systems 9(2): 1069-1090
Cornet, C.; C.-Labonnote, L.; Waquet, F.; Szczap, F.; Deaconu, L.; Parol, F.; Vanbauce, C.; Thieuleux, F.; Riédi, J. 2018: Cloud heterogeneity on cloud and aerosol above cloud properties retrieved from simulated total and polarized reflectances Atmospheric Measurement Techniques 11(6): 3627-3643
Grise, K.M.; Medeiros, B. 2016: Understanding the Varied Influence of Midlatitude Jet Position on Clouds and Cloud Radiative Effects in Observations and Global Climate Models Journal of Climate 29(24): 9005-9025
Mülmenstädt, J.; Gryspeerdt, E.; Salzmann, M.; Ma, P.; Dipu, S.; Quaas, J. 2019: Separating radiative forcing by aerosol–cloud interactions and rapid cloud adjustments in the ECHAM–HAMMOZ aerosol–climate model using the method of partial radiative perturbations Atmospheric Chemistry and Physics 19(24): 15415-15429
Shupe, M.D.; Intrieri, J.M. 2004: Cloud radiative forcing of the Arctic surface: The influence of cloud properties, Surface albedo, and solar zenith angle Journal of Climate 17(3): 616-628
Ridout, J.A.; Rosmond, T.E. 1996: Global modeling of cloud radiative effects using ISCCP cloud data Journal of Climate 9(7): 1479-1496
Yamada, Y.; Satoh, M. 2013: Response of Ice and Liquid Water Paths of Tropical Cyclones to Global Warming Simulated by a Global Nonhydrostatic Model with Explicit Cloud Microphysics Journal of Climate 26(24): 9931-9945
Voigt, A.; Shaw, T.A. 2016: Impact of Regional Atmospheric Cloud Radiative Changes on Shifts of the Extratropical Jet Stream in Response to Global Warming Journal of Climate 29(23): 8399-8421
Voigt, A.; Albern, N.; Papavasileiou, G. 2019: The Atmospheric Pathway of the Cloud-Radiative Impact on the Circulation Response to Global Warming: Important and Uncertain Journal of Climate 32(10): 3051-3067
Albern, N.; Voigt, A.; Pinto, J.G. 2019: Cloud‐Radiative Impact on the Regional Responses of the Midlatitude Jet Streams and Storm Tracks to Global Warming Journal of Advances in Modeling Earth Systems 11(7): 1940-1958
Gantt, B.; Xu, J.; Meskhidze, N.; Zhang, Y.; Nenes, A.; Ghan, S.J.; Liu, X.; Easter, R.; Zaveri, R. 2012: Global distribution and climate forcing of marine organic aerosol – Part 2: Effects on cloud properties and radiative forcing Atmospheric Chemistry and Physics 12(14): 6555-6563
Paquin-Ricard, Dé; Vaillancourt, P A.; Barker, H W.; Cole, J N. S. 2016: A comparison of two representations of subgrid-scale cloud structure in a global model: radiative effects as a function of cloud characteristics Quarterly Journal of the Royal Meteorological Society 142(699): 2551-2561
Wang, L.; Bao, Q.; Wang, W.-C.; Liu, Y.; Wu, G.-X.; Zhou, L.; Li, J.; Gong, H.; Nian, G.; Li, J.; Wang, X.; He, B. 2019: Lasg Global Agcm with a Two-moment Cloud Microphysics Scheme: Energy Balance and Cloud Radiative Forcing Characteristics Advances in Atmospheric Sciences 36(7): 697-710
Liu, Y.; Wu, W.; Jensen, M.P.; Toto, T. 2011: Relationship between cloud radiative forcing, cloud fraction and cloud albedo, and new surface-based approach for determining cloud albedo Atmospheric Chemistry and Physics 11(14): 7155-7170
Lacour, A.; Chepfer, H.; Miller, N.B.; Shupe, M.D.; Noel, V.; Fettweis, X.; Gallee, H.; Kay, J.E.; Guzman, R.; Cole, J. 2018: How well Are Clouds Simulated over Greenland in Climate Models? Consequences for the Surface Cloud Radiative Effect over the Ice Sheet Journal of Climate 31(22): 9293-9312
Kerr, R.A. 2008: Global warming. Another side to the climate-cloud conundrum finally revealed Science 319(5865): 889