| a-train | abs lookup | absorption | absorption cross-sections | accuracy | aerosols | aggregation | airs | albedo | algorithm | amsu | annual cycle | anomalies | app: all-sky remote sensing | app: clear-sky remote sensing | app: other remote sensing | app: planets | app: radiation and climate | app: solar | app: spectroscopy | aqua | ar4 | ar5 | arctic | arm | arts | arts-dev | arts_2018_2023 | asr | assimilation | astrophysics | atmosphere | atmospheric composition | atmospheric dynamics | atmospheric modeling | atmospheric profiles | atsr-2 | avhrr | backscattering | basics | bayes | book | by: external | by: internal | calculation | calculations | calibration | calipso | ccn | cdr | ceres | cfmip | chemistry | cia | ciraclim | cirrus | cirrus anvil sublimation | cirrus cloud | cirrus clouds | cirrusstudy | ciwsir/cloudice | claus | climate | climate change | climate dynamics | climate feedbacks | climate sensitivity | climate sensivity | climate variability | climatology | cloud feedback | cloud forcing | cloud fraction | cloud ice | cloud properties | cloud radiative effects | cloud radiative forcing | cloud regimes | clouds | cloudsat | cmip3 | cmip5 | cmip6 | cmsaf | co2 | collision-induced absorption | collocation | comparison | complex probability function | computer science | continua | contrail | convection | convective clouds | convective processes | convective self-aggregation | correlated k | cosmic background | cosmic rays | cosp | cross-calibration | cth | cumulus | dardar | data bases | dda | deep convection | delta m | dimer | disort | diurnal cycle | dmsp | documentation | droplet size | dynamics | earth | earthcare | echam | ecmwf | effective radius | electromagnetism | electron content | elevation | elevation satellite-2 | emd | emissivity | enso | eof-pca-svd | erbe | error assessment | ers | eruption | esa planetary | exoplanets | extraterrestrial | faddeyeva function | fall speed | far-infrared | faraday-voigt | fcdr | feedback | feedbacks | fingerprinting | flux uav | forcing | forest fire | fox19_airborne_amt.pdf | friend | fun | function evaluation | gcm | genesis | geostationary | gerrit_erca | global warming | gnss | goes | gps | gras | graupel | greenhouse effect | groundbased | hadley circulation | hail | heating rate | heating rates | herschel | hiatus | hirs | history | hitran | hsb | humidity | hydrological sensitivity | hydrological sensivity | iasi | ice | ice clouds | ice crystal growth | ice nucleation | ice water | icesat-2 | ici | icon | icz | in situ | infrared | instruments | intercalibration | intercomparison | interference | inverse modelling | ipcc | ir/vis | iris | isccp | ismar | isotopes | itcz | iwc | iwp | iwv | jupiter | kessler scheme | lblrtm | lidar | limb effect | limb sounding | limb-correction | line-shape | linemixing | lineshape | liquid water | liquid water path | longwave radiation | low-cloud feedback | magnetic field | magnetism | mars | mas | mass-dimension relation | masters thesis | math | matlab | megha-tropiques | mendrok | mesoscale organization | meteorology | meteosat | metop | mhs | microphysics | microwave | mipas | mirs | misr | mixed phase | mls | model | modeling | models | modis | molecular opacities | molecular spectroscopy | monte carlo | mspps | msu | mth | multi-moment scheme | multisensor | mwhs | mwi | net radiation | neural network | nicam | nlte | noaa | nonsphericity | npoess | observation | ocean | ocean reflection | ocean-atmosphere interactions | odin | olr | one-moment scheme | open loop | optical | optical depth | optical properties | optics | orbital drift | orbits | ozone | pacific ocean | particle orientation | particle shape | particle size | particle size distribution | patmos-x | phase function | phd thesis | polarimetry | polarization | polder | potss | precipitation | profile datasets | programming | projection | promet | propagation modeling | python | radar | radiation | radiation profiles | radiative convective equilibrium | radiative equilibrium | radiative feedback | radiative fluxes | radiative forcing | radiative processes | radiative transfer | radiative-convective equilibrium | radiative-equilibrium | radio occultation | radiometers | radiosonde | radiosonde cloud liquid | radiosonde correction | rain | reanalysis | refractive index | relative humidity | remote sensing | retrieval | review | rodgers | rttov | sahara | sahel | sampling | sand/dust | sar | satellite | satellite missions | satellite observations | satellite simulator | sbuehler_habil | scattering | scattering databases | scintillations | scout-amma | self-aggregation | sensor geometry | seviri | shallow convection | simulated annealing | single scattering | smiles | sno | snow | snowfall | software | soil | solar | soot | sounders | spectral information | spectral integration | spectroscopic database | spectroscopic line parameters | spectroscopy | speed-dependent profiles | split window technique | ssm/i | ssm/t | ssmis | ssmt2 | stability | statistics | ste | stereo | stratosphere | submillimeter | submm | sun | supersaturation | surface | synergies | task2 | tempera | temperature | terra | thermodynamics | time series | titan | toa radiation | top of the atmosphere | total column | tovs | trade-wind clouds | trajectory analysis | trend | trmm | tropical circulation | tropical convection | tropical meteorology | tropics | tropopause | troposphere | ttl | turbulence | tutorial | two-moment scheme | upper troposphere | uth | utls | validation | vater vapor | venus | visualization | volcanic ash | walker circulation | walker rirculation | water | water cycle | water dimer | water vapor | water vapor continuum | water vapour | water vapour path | water-vapour | what: mention | what: unknown | what: use | wind | zeeman |

Hide tag cloud

Filter by author:
Filter by year:
Filter by bibtex key:
Filter by type:
Filter by keyword:
and
and
 

Filtered by keyword:climatology

There is currently a filter applied. To see the complete list of publications, clear the filter.
  1. Benson, J. L., D. M. Kass, and A. Kleinböhl (2011), Mars' north polar hood as observed by the Mars Climate SounderJ. Geophys. Res., 116, E03008, doi:10.1029/2010JE003693.
  2. Eguchi, N. and M. Shiotani (2004), Intraseasonal variations of water vapor and cirrus clouds in the tropical upper troposphereJ. Geophys. Res., 109(D18), doi:10.1029/2003JD004314.
  3. Ferraro, R. R., N. C. Grody, F. Weng, and A. Basist (1996), An Eight-Year (1987–1994) Time Series of Rainfall, Clouds, Water Vapor, Snow Cover, and Sea Ice Derived from SSM/I MeasurementsBull. Amer. Met. Soc., 77, 891–906.
  4. Goldfarb, L., P. Keckhut, M-L. Chanin, and A. Hauchecorne (2001), Cirrus climatological results from lidar measurements at OHP (44°N, 6°E)Geophys. Res. Lett., 28, 1687–1690, doi:10.1029/2000GL012701.
  5. Gultepe, I., G. A. Isaac, and S. G. Cober (2001), Ice crystal number concentration versus temperature for climate studiesInt. J. Climatol., 21, 1281–1302.
  6. Hahn, C. J., W. B. Rossow, and S. G. Warren (2001), ISCCP Cloud Properties Associated with Standard Cloud Types Identified in Individual Surface ObservationsJ. Climate, 14, 11–28.
  7. Han, Q.-Y, W. B. Rossow, and A. A. Lacis (1994), Near-global survey of effective cloud droplet radii in liquid water clouds using ISCCP dataJ. Climate, 7, 465–497.
  8. Han, Q.-Y., W. B. Rossow, J. Chou, K.-S. Kuo, and R. M. Welch (1999), The effects of aspect ratio and surface roughness on satellite retrievals of ice-cloud propertiesJ. Quant. Spectrosc. Radiat. Transfer, 63, 559–583.
  9. Jin, Y., W. B. Rossow, and D. P. Wylie (1996), Comparison of the climatologies of high-level clouds from HIRS and the ISCCPJ. Climate, 9, 2850–2879.
  10. Kahn, B. H. and J. Teixeira (2009), A Global Climatology of Temperature and Water Vapor Variance Scaling from the Atmospheric Infrared SounderJ. Climate, 22(20), 5558–5576, doi:10.1175/2009JCLI2934.1.
  11. Kidd, C., V. Levizzani, and P. Bauer (2009), A review of satellite meteorology and climatology at the start of the twenty first centuryProg. Phys. Geog., 33(4), 474–489.
  12. Liao, X., W. B. Rossow, and D. Rind (1995), Comparison between SAGE II and ISCCP high-level clouds. Part I: Global and zonal mean cloud amountsJ. Geophys. Res., 100, 1121–1135.
  13. Liao, X., W. B. Rossow, and D. Rind (1995), Comparison between SAGE II and ISCCP high-level clouds. Part II: Locating cloud topsJ. Geophys. Res., 100, 1137–1147.
  14. Lieberman, R. S., D. A. Ortland, and E. S. Yarosh (2003), Climatology and interannual variability of diurnal water vapor heatingJ. Geophys. Res., 108(D3), doi:10.1029/2002JD002308.
  15. Lin, B. and W. B. Rossow (1996), Seasonal Variation of Liquid and Ice Water Path in Nonprecipitating Clouds over Oceans.J. Climate, 9, 2890–2902.
  16. Lin, B. and W. B. Rossow (1997), Precipitation water path and rainfall rate estimates for oceans using special sensor microwave imager and International Satellite Cloud Climatology Project dataJ. Geophys. Res., 102, 9359–9374.
  17. Maltagliati, Luca, Dmitrij V. Titov, Thérèse Encrenaz, Riccardo Melchiorri, Francois Forget, Horst U. Keller, and Jean-Pierre Bibring (2011), Annual survey of water vapor behavior from the OMEGA mapping spectrometer onboard Mars ExpressIcarus, 213(2), 480–495, doi:10.1016/j.icarus.2011.03.030.
  18. Menzel, W. P. and D. P. Wylie (2003), HIRS observations of a decline in high clouds since 1995, proceedings of ITSC XII, 27 Feb –5 Mar 2002, Lorne, Australia.
  19. Noel, V., H. Chepfer, M. Haeffelin, and Y. Morille (2006), Classification of Ice Crystal Shapes in Midlatitude Ice Clouds from Three Years of Lidar Observations over the SIRTA ObservatoryJ. Atmos. Sci., 63(11), 2978–2991.
  20. Paltridge, C. W. and C. M. R. Platt (1976), Radiative processes in meteorology and climatologyElsevier Publ., 161–165.
  21. Peixoto, J. P. and A. H. Oort (1996), The Climatology of Relative Humidity in the AtmosphereJ. Climate, 9, 3443–3463.
  22. Randel, D. L., T. H. Vonder Haar, M. A. Ringerud G. L. Stephens, T. J. Greenwald, and C. L. Combs (1996), A New Global Water Vapor DatasetBull. Amer. Met. Soc., 1233–1246.
  23. Rossow, W. B. and E. Duenas (2004), International Satellite Cloud Climatology Project (ISCCP) web site: An online resource for researchBull. Amer. Met. Soc., 85, 167–172, doi:10.1175/BAMS-85-2-167.
  24. Rossow, W. B. and R. A. Schiffer (1991), ISCCP Cloud Data ProductsBull. Amer. Met. Soc., 72, 2–20.
  25. Rossow, W. B. and R. A. Schiffer (1999), Advances in Understanding Clouds From ISCCPBull. Amer. Met. Soc., 80(11), 2261–2288.
  26. Sassen, K. and J. R. Campbell (2001), A Midlatitude Cirrus Cloud Climatology from the Facility for Atmospheric Remote Sensing. Part I: Macrophysical and Synoptic PropertiesJ. Atmos. Sci., 58, 481–496.
  27. Sassen, K. and S. Benson (2001), A Midlatitude Cirrus Cloud Climatology from the Facility for Atmospheric Remote Sensing. Part II: Microphysical Properties Derived from Lidar DepolarizationJ. Atmos. Sci., 58, 2103–2112.
  28. Sassen, K. and J. M. Comstock (2001), A Midlatitude Cirrus Cloud Climatology from the Facility for Atmospheric Remote Sensing. Part III: Radiative PropertiesJ. Atmos. Sci., 58, 2113–2127.
  29. Sassen, K., K.-N. Liou, Y. Takano, and V. I. Khvorostyanov (2003), Diurnal effects in the composition of cirrus cloudsGeophys. Res. Lett., 30, doi:1029/2003GL017034.
  30. Sassen, K. and B. S. Cho (1992), Subvisual-Thin Cirrus Lidar Dataset for Satellite Verification and Climatological ResearchJ. Appl. Meteorol., 1275–1285.
  31. Scott, N. A., A. Chedin, R. Armante, J. Francis, C. J. Stubenrauch, J.-P. Chaboureau, F. Chevallier, C. Claud, and F. Cheruy (1999), Characteristics of the TOVS Pathfinder Path-B DatasetBull. Amer. Met. Soc., 12, 2679–2701.
  32. Soden, B. J. and F. P. Bretherton (1993), Upper Tropospheric Relative Humidity From the GOES 6.7 μm Channel: Method and Climatology for July 1987J. Geophys. Res., 98(D9), 16,669–16,688.
  33. Soden, B. J. and F. P. Bretherton (1996), Interpretation of TOVS water vapor radiances in terms of layer-average relative humidities: Method and climatology for the upper, middle, and lower troposphereJ. Geophys. Res., 101(D5), 9333–9343, doi:10.1029/96JD00280.
  34. Ström, J., M. Seifert, B. Kärcher, J. Ovarlez, A. Minikin, J.-F. Gayet, R. Krejci, A. Petzold, F. Auriol, W. Haag, R. Busen, U. Schumann, and H. C. Hansson (2003), Cirrus cloud occurrence as function of ambient relative humidity: a comparison of observations obtained during the INCA experimentAtmos. Chem. Phys., 3, 1807–1816, doi:10.5194/acp-3-1807-2003.
  35. Stubenrauch, C. J. and F. Eddounia (2001), Cloud property survey from satellite observations using vertical sounders (TOVS Path-B) and Imagers (ISCCP)Workshop on Ion-Aerosol-Cloud Interactions Proceed. CERN, Geneva, 18-20 April 2001, CERN Yellow report CERN-2001-007, 63-74.
  36. Stubenrauch, C. J., F. Eddounia, and L. Sauvage (2005), Cloud heights from TOVS Path-B: Evaluation using LITE observations and distributions of highest cloud layersJ. Geophys. Res., 110, D19203, doi:10.1029/2004JD005447.
  37. Stubenrauch, C. J. and U. Schumann (2005), Survey of Cirrus and atmospheric properties from TOVS Path-B: Natural variability and impact of air traffic on cirrus coverage14th International TOVS Study Conference Proceed., Beijing, China, 25 May-1 Jun.
  38. Stubenrauch, C. J., W. B. Rossow, F. Cheruy, N. A. Scott, and A. Chedin (1999), Clouds as Seen by Satellite Sounders (3I) and Imagers (ISCCP). Part I: Evaluation of Cloud ParametersJ. Climate, 12, 2189–2213.
  39. Stubenrauch, C. J., A. Chedin, R. Armante, and N. A. Scott (1999), Clouds as seen by Satellite Sounders (3I) and Imagers (ISCCP). Part II: A New Approach for Cloud Parameter Determination in the 3I AlgorithmsJ. Climate, 12, 2214–2223.
  40. Stubenrauch, C. J., W. B. Rossow, N. A. Scott, and A. Chedin (1999), Clouds as Seen by Satellite Sounders (3I) and Imagers (ISCCP). Part III: Spatial Heterogeneity and Radiative EffectsJ. Climate, 12, 3419–3442.
  41. Toohey, M. and T. von Clarmann (2013), Climatologies from satellite measurements: the impact of orbital sampling on the standard error of the meanAtmos. Meas. Tech., 6, 937–948, doi:10.5194/amt-6-937-2013.
  42. Wang, P. H., P. Minnis, M. P. McCormick, G. S. Kent, and K. M. Skeens (1996), A 6-Year Climatology of Cloud Occurrence Frequency from Stratospheric Aerosol and Gas Experiment II Observations (1985-1990)J. Geophys. Res., 101, 29407–29429.
  43. Winker, D. M. and C. R. Trepte (1998), Laminar cirrus observed near the tropical tropopause by LITEGeophys. Res. Lett., 25(17), 3351–3354.
  44. Wu, X., J. J. Bates, and S. J. S. Khalsa (1993), A Climatology of the Water Vapor Band Brightness Temperatures from NOAA Operational SatellitesJ. Climate, 6, 1282–1300.
  45. Wylie, D. P., D. L. Jackson, W. P. Menzel, and J. J. Bates (2005), Trends in global cloud cover in two decades of HIRS observationsJ. Climate, 18, 3021–3031.
  46. Wylie, D. P., W. P. Menzel, and K. I. Strabala (1994), Four years of global cirrus cloud statistics using HIRSJ. Climate, 7(12), 1972–1986.
  47. Wylie, D., P. Piironen, W. Wolf, and E. Eloranta (1995), Understanding satellite cirrus cloud climatologies with calibrated lidar optical depthsJ. Atmos. Sci., 52, 4327–4343.
  48. Wylie, D. P. and P.-H. Wang (1997), Comparison of cloud frequency data from the high-resolution infrared radiometer sounder and the Stratospheric Aerosol and Gas Experiment IIJ. Geophys. Res., 102, 29893–29900.
  49. Wylie, D. P. and W. P. Menzel (1999), Eight years of cloud statistics using HIRSJ. Climate, 12, 170–184.
  50. Zender, C. S. and P. Chylek (1998), A Global Climatology of O2 O2, O2 N2, and (H2O)2 Abundance and Absorption, National Center for Atmospheric Research, Dalhouse University, Eight ARM Science Team Meeting Proceedings.
  51. Zender, C. S. (1999), Global climatology of abundance and solar absorption of oxygen collision complexesJ. Geophys. Res., 104(D20), 24,471–24,484.