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Claudia Stubenrauch Laboratoire de Météorologie Dynamique, IPSL/CNRS, France thanks to contributions from many colleagues Cloud Properties from Satellite.

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Presentation on theme: "Claudia Stubenrauch Laboratoire de Météorologie Dynamique, IPSL/CNRS, France thanks to contributions from many colleagues Cloud Properties from Satellite."— Presentation transcript:

1 Claudia Stubenrauch Laboratoire de Météorologie Dynamique, IPSL/CNRS, France thanks to contributions from many colleagues Cloud Properties from Satellite Observations: what has been achieved ? ISCCP at 30, 22-24 Apr 2013, CUNY

2  continuing exploitation of A-Train synergy: vertical structure, thermodynamic phase  GEWEX assessments of clouds & of radiative fluxes essential for climate studies & model evaluation  continuing exploitation of ISCCP weather states  synergetic climate & process studies : aerosol – cloud –precipitation – radiation - dynamics coupled with modelling  new missions (IASI, Megha-Tropiques, etc) -> many exciting presentations during this symposium !

3 Outline  Interpretation of retrieved cloud properties: How does the use of different instruments affect averages & distributions of cloud properties? (What did we learn from GEWEX Cloud Assessment ?)  Synergy of passive & active remote sensing: statistical models of cloud vertical structure (important for radiative flux computation in atmosphere & at surface) - ISCCP model based on radiosonde obs, evaluated with CALIPSO-CloudSat (Wang & Rossow 1995, Rossow et al. 2004)(Rossow & Zhang 2010) - classification of IWC profiles  Synergy of variables: upper tropospheric humidity – cirrus (improvement of vertical resolution by IASI)

4 Copyright: 1998 Wadsworth Publishing Company; C. Donald Ahrens, Essentials of Meteorology Cumulus (low fair weather clouds) Cumulonimbus (vertically extended) Clouds are extended objects of many very small liquid / ice particles of many very small liquid / ice particles Cirrus (high ice clouds) Cloud structures over Amazonia bulk quantities at spatial & temporal scales to resolve weather & climate variability satellite radiometers

5 Space-based Global Observing System Megha- Tropiques Geostationary satellites (fixed along equator) : frequent observation (30min-3hours), but 5-6 satellites to cover whole Earth Polar orbiting satellites (heliosynchoneous) : observations at same local time, twice per day to resolve diurnal cycle: ISCCP uses combination of both!

6 Satellite radiometers measure (>1980) emitted, reflected, scattered emitted, reflected, scattered radiation cloud detection inverse radiative transfer cloud properties  information on uppermost cloud layers  ‘radiative’ cloud height  perception of cloud scenes depends on instrument / retrieval performance on thin Ci => cloud property accuracy scene dependent : most difficult scenes: thin Ci overlying low clouds, low contrast with surface (thin Ci, low cld, polar regions ) Cloud properties from space lidar - radar synergy -> information on all cloud layers; however: sparse sampling lidar : sensitive to thin (subvis) Ci, however: only ‘apparent’ cloud base (COD<3) Active instruments (A-Train, > 2005)

7 IR-NIR-VIS Radiometers good spatial resolution (1-5km), multi-spectral channels (1-8) 1) COD (day, assumption on microphysics),CT, CP 2) CWP, CRE (day, VIS-NIR difference) IR Sounders 15km res, CO 2 absorption band : sensitive to thin Ci (COD>0.1), day&night no 1) CP,CEM (no assumption on microphysics) 2) spectral difference (8-12  m) -> CRE, CWP (only Ci) multi-angle VIS-SWIR Radiometers 1/20km res, sensitive to clouds with COD>2, Rayleigh scattering, O 2 abs. band, only day multi-angle scattering -> cloud top (CZ) polarization -> CT independent phase lidar, CO 2 sounding, IR spectrum IR-VIS imagers solar spectrum thin Ci over low clouds : Interpretation of Cloud height  20% of all cloudy scenes (CALIPSO) How does this affect climatic averages & distributions ? Instruments exploiting the EM spectrum

8 Cloud Assessment http://climserv.ipsl.polytechnique.fr/gewexca global gridded L3 data (1° lat x 1° long) : monthly averages, variability, Probability Density Functions relatively new retrieval versions: PATMOS-x PATMOS-x ( AVHRR)1982-2009 (Heidinger et al. 2012, Walther et al. 2012) ATSR-GRAPE ATSR-GRAPE 2003-2009 (Sayer et al. 2011) ISCCP ISCCP GEWEX cloud dataset 1984-2007 (Rossow and Schiffer 1999) MODIS-ST eam MODIS-CERES MODIS-S cience T eam 2001-2009 (Menzel et al.2008; Platnick et al. 2003) MODIS-CERES 2001-2009 (Minnis et al. 2011) TOVS Path-B TOVS Path-B 1987-1994 (Stubenrauch et al. 1999, 2006; Rädel et al. 2003) AIRS-LMD AIRS-LMD 2003-2009 (Stubenrauch et al. 2010; Guignard et al. 2012) HIRS-NOAA HIRS-NOAA 1982-2008 (Wylie et al. 2005) MISR MISR 2001-2009 (DiGirolamo et al. 2010) POLDER POLDER 2006-2008 (Parol et al. 2004; Ferlay et al. 2010) complementary cloud information: CALIPSO-ST eam CALIPSO-S cience T eam 2007-2008 (Winker et al. 2009) CALIPSO-GOCCP CALIPSO-GOCCP 2007-2008 (Chepfer et al. 2010) WCRP report 23/2012; Stubenrauch et al. BAMS 2013 2005-2012

9 9 Interprétation des propriétés nuageuses Global averages & ocean-land differences Cloud ‘radiative’ Temperature: 260 ± 2 K synoptic (day-to-day) variability : 15-20 K inter-annual variability : 2 K 7-9 K warmer over ocean than over land global ocean-land Cloud Amount (Cover): 0.68 ± 0.03 for clouds with COD>0.1 + 0.05 subvisible Ci, -> 0.56 (clds with COD > 2) synoptic (day-to-day) variability : 0.25-0.30 inter-annual variability : 0.025 0.10-0.15 larger over ocean than over land Effective Cloud Amount: 0.50 ± 0.05 (weighted by cloud IR emissivity) synoptic (day-to-day) variability : 0.26-0.28 0.05-0.12 larger over ocean than over land Cloud Top Temperature250 K Cloud Top Temperature (including subvis Ci): 250 K

10 10 A-Train Synergy: cloud top - ‘radiative’ height  High clouds (even optically thick ones) need up to 3 km to attain COD of 1, (esp. in tropics)  Low clouds seem to have sharper cloud tops than high-level clouds as fct of ‘ apparent’ Cloud Vertical extent (COD  3) distributions for low- & high clouds Stubenrauch et al. ACP 2010 cloud top (CALIPSO) – ‘radiative’ height (AIRS) ‘radiative height’ corresponds to height where COD reaches ~1

11 CAHR + CAMR + CALR = 1 global 11 CALIPSO only considers uppermost layers to better compare with other datasets CAHR (hgh clds out of all clds) depends on sensitivity to thin Ci (30% spread) 42% 42% are high clouds (COD>0.1) -> 20% with COD>2 (MISR, POLDER) 16% 16% (±5%) are midlevel clouds thin Ci over low cloud misidentified as midlevel clouds by ISCCP, ATSR, POLDER 42%60% 42% are single-layer low clouds, 60% are low clouds (MISR, CALIPSO, surface observer) How many of detected clouds are high, midlevel & low clouds? ocean-land eff high cloud amount agrees : 0.17 -> another sign of missing thin cirrus 20%10% 20% more low clouds over ocean; 10% more high / midlevel clouds over land, optically thinner over land, -> effective cloud amount similar

12 I nter T ropical C onvergence Z one: high convection + cirrus anvils stratocumulus winter storm tracks ©1994 Encyclopaedia Britannica Inc. Sun / atmospheric circulation -> geographical cloud distribution MODIS-CEMODIS-CEMODIS-CEMODIS-CE uncertainty on regional variability:

13 latitudinal & seasonal ! variations similar ! (except polar regions & HIRS CALR over ocean) high-level clouds single-layer low clouds Latitudinal & seasonal variations  CAHR CALR 

14 Complex Empirical Orthogonal Functions, project. on distorted diurnal harmonics  Low clouds over land: significant diurnal cycle, max early afternoon  Low clouds over ocean: max in early morning  High clouds: max in evening  Mid clouds: max in early morning or late at night  Cirrus: increase during afternoon & persist during night, thickening TOVS analysis Stubenrauch et al. 2006 Diurnal cycle of clouds Cairns, 1995 near noon early evening

15 Diurnal differences afternoon – morning Diurnal cycle on average smaller than regional differences & seasonal cycle slightly more clouds in the morning over ocean, more clouds in the afternoon over land CAHR difference negligible over ocean, slightly larger in the afternoon over NH midlatitude land

16 Global CA / CT anomalies in time global CA within ±0.025, CT within ±2K (~ interannual mean variability) Investigation of possible artifacts in ISCCP cloud amounts (W. B. Rossow, Ann. 2 of WCRP report) radiance calibration changes radiance calibration changes geographic coverage changes geographic coverage changes day-night coverage changes day-night coverage changes satellite viewing geometry changes satellite viewing geometry changes Conclusion: Conclusion: these causes reduce magnitude of CA variation only by 1/3

17 17 Thermodynamic phase & retrieval of optical / microphysical properties Retrieval of optical / bulk microphysical properties needs thermodynamic phase distinction: polarization (POLDER, CALIPSO) multi-spectral (PATMOS-x, MODIS, ATSR) temperature (ISCCP, AIRS, TOVS) R VIS -> COD R VIS & R SWIR -> COD & CRE (smaller particles reflect more) assumptions in radiative transfer: particle habit, size distribution, phase WP = 2/3 x COD x  x CRE (vertically hom.) IR: small ice crystals in semi-transparent Ci lead to slope of CEM’s between 8 & 12  m Choi et al. 2010 CALIPSO Zheng, PhD 2010 POLDER

18 Effective Cloud Particle radii: Liquid: 14 ± 1  m Ice: 25 ± 2  m Liquid: max around ~ 11  m Ice: max around 32  m / 27  m IR sounders, ISCCP / MODIS-ST, ATSR-GRAPE linked to retrieval filtering of optically thicker clouds & less to different channels (3.7 / 2.1 / 1.6  m) -> only retrieved near cloud top Bulk microphysical properties effective radius partly cloudy pixels? ice? liquid or large COD? Cloud Water Path: Liquid: 30 – 60 gm -2 Ice: 60 – 120 gm -2 distributions depend on retrieval filtering & partly cloudy fields (MODIS-ST, ATSR retrieval filtering COD > 1) water path

19 Interpretation of cloud climatologies in terms of TOA fluxes use COD-CP histograms (monthly 1° x 1° map resolution) in radiative transfer Cloud Radiative Effect per cloud type (each scene 100%): (Chen et al. J. Climate 2000 ; using GISS radiative transfer code) -25-87-126 -29-81-99 -34-75-85 316061 132221 488 5-28-66 -16-59-78 -30-67-77 CP COD SW CRE 0.210.090.04 0.130.110.03 0.190.180.03 0.130.170.08 0.030.080.06 0.240.180.03 0.290.110.0 0.120.060.0 0.170.240.0 ISCCPPATMOSxAIRS-LMD LW CRE net CRE ISCCP properties included in radiative flux computations -> FD dataset (Zhang et al. 1995, 1997, 2004, etc) differences in COD-CP distributions lead to differences in radiative effects (transformation of IR emissivity to COD -> COD underestimation of SW effect)

20 Comparison of cloud radiative effects at TOA Comparison of cloud radiative effects at TOA (M. Zelinka) using radiative transfer code of Fu & Liou (fixed re L: 10  m, I: 30  m), transform COD to LWC / IWC for corresponding CP layer (like in Zelinka et al. J. Climate 2012 ) (GEWEX CA COD-CP histograms are not weighted by CA) Wm -2 AIRS – ISCCP LW radiative effect similar, SW effect underestimated by AIRS (because of saturation when transforming emissivity to optical depth) preliminary

21 Clouds with same IWP may have different IWC and De profiles -> influence on radiation ? IWCDe IWC De IWC De A-Train Synergy: Classification of IWC profiles Is it possible to give a shape probability in dependence of cloud properties or atmospheric properties? -> analysis using AIRS - lidar-radar GEOPROF - liDARraDAR data (Mace et al. 2009) (Delanoë & Hogan 2010) increasing IWC compared to const. IWC leads to stronger cooling of atmosphere

22 constant trapecialower triangle upper triangle IWC profile classes & dependency on IWP IWP (g/m2) (occurrence) constanttrapecialow trianupp trian 0-10 (51%) 54%20%10%16% 10-30 (29%) 31%48%13%8% 30-100 (17%) 28%56%14%3% 100-300 (3%) 26%51%21%2% 300-1000 (<1%) 38%35%26%1% const & trapecia correspond to 80% of the profiles lower triangle increases with IWP from 10 to 25% upper triangle only for IWP < 30 g/m2 strong vertical wind might affect occ of low / upp trianges nearly independent of location / season ! Feofilov et al., EGU 2013 using const. instead of increasing IWC profile might underestimate radiative cooling of atmosphere by 1 – 2 Wm -2

23 Detection of ice supersaturation (ISS) IR Sounders retrieve water vapour within atmospheric layers of km’s => underestimation of RH ice : AIRS peak for cirrus at 70% (instead of 100%) improved spectral resolution : IASI peak for cirrus at 80-85% Lamquin et al., ACP 2012 ISS often occurs in vertical layers < 500 m saturated region RHi (%), radiosondes AIRS IASI tropics AIRS IASI

24 Conclusions  Satellite instruments: unique possibility to study cloud properties over long period  GEWEX Cloud Assessment:  first coordinated intercomparison of L3 cloud products of 12 global ‘state of the art’ datasets  common database facilitates further assessments, climate studies & model evaluation  ISCCP: only dataset that directly resolves diurnal cycle (3-hourly) & covers whole globe  geographical distributions, latitudinal & seasonal variations agree well  accuracy is scene & instrument dependent (interpretation of cloud height): differences can be mostly understood by different performance to identify Ci (problems in some retrieval methods, misidentification water-ice clouds)  histograms are important (esp. for optical and microphysical properties)  cloud products adequate for model evaluation & monitoring regional variability  longterm datasets -> robust statistics & explore rare events  global monitoring of cloud properties very difficult  even if instantaneous cloud properties are not very accurate, synergy of different variables provides invaluable potential for improving understanding of clouds next step: GEWEX integrated dataset

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