All Publications

Below is the combined list of references from refs_sat.bib and refs_external.bib. It is intended for our group's internal use.

| 2c-ice | a-train | abs lookup | absorption | absorption cross-sections | accuracy | active | aerosol | aerosols | age of air | aggregation | airs | albedo | algorithm | amsos | 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 | astronomy | astrophysics | asymmetry | atmosphere | atmospheric composition | atmospheric dynamics | atmospheric modeling | atmospheric profiles | atsr-2 | avhrr | bachelor thesis | backscattering | basics | bayes | bias | biomass | 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 | cliccs | climate | climate change | climate dynamics | climate feedbacks | climate sensitivity | climate sensivity | climate variability | climatology | cloud feedback | cloud forcing | cloud fraction | cloud ice | cloud ice mission | cloud optical thickness | cloud properties | cloud radiative effects | cloud radiative forcing | cloud regimes | cloud top pressure | cloudice mission | clouds | cloudsat | clustering | cmip3 | cmip5 | cmip6 | cmsaf | co2 | collision-induced absorption | collocation | collocations | comparison | complex probability function | computer science | continua | contrail | convection | convective clouds | convective processes | convective self-aggregation | correlated k | cosmic background | cosmic rays | cosp | cost 723 qjrms | cross-calibration | cth | cumulus | dardar | data assimilation | data bases | dda | deep convection | delta m | dimer | disort | diurnal cycle | dlr-smiles | dmsp | documentation | doppler | droplet size | dynamics | earth | earthcare | ec earth | echam | ecmwf | effective radius | electromagnetism | electron content | elevation | elevation satellite-2 | emd | emde | 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 | fuzzy inference system | fuzzy logic | gcm | genesis | geostationary | gerrit_erca | global warming | gnss | goes | gps | gras | graupel | gravitational lensing | greenhouse effect | ground-based | groundbased | habil | hadley circulation | hail | hamburg | heating rate | heating rates | herschel | hiatus | hirs | history | hitran | hsb | humidity | hydrological sensitivity | hydrological sensivity | hydrometeors | iasi | ice | ice clouds | ice crystal growth | ice nucleation | ice water | icesat-2 | ici | icon | icz | in situ | infrared | infrared sounder | instruments | inter-calibration | intercalibration | intercomparison | interference | inverse modelling | ipcc | ir | ir/vis | iris | isccp | ismar | isotopes | itcz | iwc | iwp | iwv | john | jupiter | kalpana | kessler scheme | lblrtm | licentiate thesis | 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 | master thesis | masters thesis | math | matlab | megha-tropiques | mendrok | mesoscale organization | meteorology | meteosat | methane ocean | metop | mhs | microphysics | microwave | microwave humidity | microwave radiometry | milz | mipas | mirs | misr | mixed phase | mls | model | modeling | models | modis | molecular opacities | molecular spectroscopy | monte carlo | moon | 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 | orbital drift correction | orbits | ozone | pacific ocean | particle orientation | particle shape | particle size | particle size distribution | passive | patmos-x | phase function | phd thesis | planetary evolution | 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 | radiometer | radiometers | radiosonde | radiosonde cloud liquid | radiosonde correction | radiosonde corrections | rain | reanalysis | refractive index | relative humidity | remote sensing | retrieval | retrievals | 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 | sreerekha | ssm/i | ssm/t | ssmis | ssmt2 | stability | stars | statistics | ste | stereo | stratosphere | submillimeter | submm | sun | supersaturation | surface | synergies | synergy | task2 | tempera | temperature | terra | thermodynamics | time series | titan | tkuhn | 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 | uthmos | utls | validation | vater vapor | venus | visualization | volcanic ash | walker | 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 |

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Group references

In the Pipeline

    Articles

      2010 Back to top

    1. Takagi, M., K. Suzuki, H. Sagawa, P. Baron, J. Mendrok, Y. Kasai, and Y. Matsuda (2010), Influence of CO2 line profiles on radiative and radiative-convective equilibrium states of the Venus lower atmosphereJ. Geophys. Res., E06014, doi:10.1029/2009JE003488.

      2. 2006 Back to top

    2. Buehler, S. A., A. von Engeln, E. Brocard, V. O. John, T. Kuhn, and P. Eriksson (2006), Recent developments in the line-by-line modeling of outgoing longwave radiationJ. Quant. Spectrosc. Radiat. Transfer, 98(3), 446–457, doi:10.1016/j.jqsrt.2005.11.001.

    Books and Book Contributions

      Theses

        Technical Reports and Proposals

          Articles in Conference Proceedings and Newsletters

            Internal Reports

              External references

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              2. Allan, R. P. (2011), Combining satellite data and models to estimate cloud radiative effect at the surface and in the atmosphereMet. Appl., 18, 324–333, doi:10.1002/met.285.
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              8. Becker, G. E. and S. H. Autler (1946), Water Vapor Absorption of Electromagnetic Radiation in the Centimeter Wave-Length RangePhys. Rev., 70(5–6), 300–307.
              9. Bell, T. L., M.-D. Chou, A. Y. Hou, and R. S. Lindzen (2002), ReplyBull. Amer. Met. Soc., 598–600.
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              12. Bohren, C. F. and E. E. Clothiaux (2006), Fundamentals of Atmospheric Radiation, WILEY-VCH Verlag GmbH & Co. KGaA, ISBN 3-527-40503-8.
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              16. Choi, Y-S. and C-H. Ho (2006), Radiative effect of cirrus with different optical properties over the tropics in MODIS and CERES observationsGeophys. Res. Lett., 33, L21811, doi:10.1029/2006GL027403.
              17. Clement, A. C. and B. Soden (2005), The Sensitivy of the Tropical-Mean Radiation BudgetJ. Climate, 18, 3189–3203.
              18. Clough, S. A., M. W. Shephard, E. J. Mlawer, J. S. Delamere, M. Iacono, K. Cady-Pereira, S. Boukabara, and P. D. Brown (2005), Atmospheric radiative transfer modeling: a summary of the AER codesJ. Quant. Spectrosc. Radiat. Transfer, 91(2), 233–244, doi:10.1016/j.jqsrt.2004.05.058.
              19. Collins, W. D., V. Ramaswamy, M. D. Schwarzkopf, Y. Sun, R. W. Portmann, Q. Fu, S. E. B. Casanova, J.-L. Dufresne, D. W. Fillmore, P. M. D. Forster, V. Y. Galin, L. K. Gohar, W. J. Ingram, D. P. Kratz, M.-P. Lefebvre, J. Li, P. Marquet, V. Oinas, Y. Tsushima, T. Uchiyama, and W. Y. Zhong (2006), Radiative forcing by well-mixed greenhouse gases: Estimates from climate models in the Intergovernmental Panel on Climate Change (IPCC) Fourth Assessment Report (AR4)J. Geophys. Res., 111, D14317, doi:10.1029/2005JD006713.
              20. Costales, J. B., G. F. Smoot, C. Witebsky, and G. De Amici (1986), Simultaneous measurements of atmospheric emissions at 10, 33, and 90 GHzRadio Sci., 21(1), 47–55.
              21. Czarnecki, Paulina, Lorenzo Polvani, and Robert Pincus (2023), Sparse, Empirically Optimized Quadrature for Broadband Spectral IntegrationJournal of Advances in Modeling Earth Systems, 15(10), e2023MS003819, doi:https://doi.org/10.1029/2023MS003819.
              22. Czekala, H. (1998), Effects of ice particle shape and orientation on polarized microwave radiation for off-nadir problemsGeophys. Res. Lett., 25(10), 1669–1672.
              23. DeAngelis, A. M., X. Qu, M. D. Zelinka, and AlexHall (2015), An observational radiative constraint on hydrologic cycle intensificationNature, 528, 249–253, doi:10.1038/nature15770.
              24. Delamere, J. S., S. A. Clough, V. H. Payne, E. J. Mlawer, D. D. Turner, and R. R. Gamache (2010), A far-infrared radiative closure study in the Arctic: Application to water vaporJ. Geophys. Res., 115, D17106, doi:10.1029/2009JD012968.
              25. Ellingson, R. G. and W. J. Wiscombe (1996), The Spectral Radiance Experiment (SPECTRE): Project Description and Sample ResultsBull. Amer. Met. Soc., 77(9), 1967–1985.
              26. Eriksson, P. (2003), Atmospheric longwave radiation, Insti. foer Radio- och Rymdvetenskap.
              27. ESA (2001), The Five Candidate Earth Explorer Core Missions - EarthCARE- Earth Clouds, Aerosols and Radiation Explorer, European Space Agency Agence spatiale europeenne.
              28. Flerchinger, G. N., W. Xaio, D. Marks, T. J. Sauer, and Q. Yu (2009), Comparison of algorithms for incoming atmospheric long-wave radiationWat. Res. Res., 45, W03423, doi:10.1029/2008WR007394.
              29. Fomin, B. A., T. A. Udalova, and E. A. Zhitnitskii (2004), Evolution of spectroscopic information over the last decade and its effect on line-by-line calculations for validation of radiation codes for climate modelsJ. Quant. Spectrosc. Radiat. Transfer, 86(1), 73–85.
              30. Fomin, B. A. (1995), Effective Interpolation Technique for Line-by-Line Calculations of Radiation Absorption in GasesJ. Quant. Spectrosc. Radiat. Transfer, 53(6), 663–669, doi:10.1016/0022-4073(95)00029-K.
              31. Foster, J. L., J. S. Barton, A. T. C. Chang, and D. K. Hall (2000), Snow Crystal Orientation Effects on the Scattering of Passive Microwave RadiationIEEE Geosci. Remote Sens., 38(5), 2430–2434.
              32. Gallagher, A. (1996), Line Shape and Radiation Transfer, University of Colorado and National Institute of Standards and Technology.
              33. Gayet, J.-F., J. Ovarlez, V. Shcherbakov, J. Strom, U. Schumann, A. Minikin, F. Auriol, A. Petzold, and M. Monier (2004), Cirrus cloud microphysical and optical properties at southern and northern midlatitudes during the INCA experimentJ. Geophys. Res., 109, doi:10.1029/2004JD004803.
              34. Gebbie, H. A. (1957), Detection of Submillimeter Solar RadiationPhys. Rev., 107, 1194–1195.
              35. Goody, R. M. and Y. L. Yung (1989), Atmospheric Radiation: Theoretical Basis, Oxford University Press, ISBN 0-19-510291-6.
              36. Goody, R. and A. Sobel (1996), A Graduate Radiation Course Based upon Numerical MethodsBull. Amer. Met. Soc., 77(12), 2919–2924.
              37. Hall, J. T. (1967), Attenuation of Millimeter Wavelength Radiation by Gaseous WaterAppl. Opt., 6(8), 1391–1398.
              38. Han, Q., W. B. Rossow, J. Chou, and R. M. Welch (1998), Global Survey of the Relationships of Cloud Albedo and Liquid Water Path with Droplet Size Using ISCCPJ. Climate, 11, 1516–1528.
              39. Hansen, J., D. Johnson, A. Lacis, S. Lebedeff, P. Lee, D. Rind, and G. Russell (1981), Climate impact of increasing atmospheric carbon dioxideScience, 213(4511), 957–966.
              40. Harries, J. E., H. E. Brindley, P. J. Sagoo, and R. J. Bantges (2001), Increases in greenhouse forcing inferred from the outgoing longwave radiation spectra of the Earth in 1970 and 1997Nature, 410, 355–357.
              41. Harries, J. E. (1997), Atmospheric radiation and atmospheric humidityJ. Quant. Spectrosc. Radiat. Transfer, 123(544), 2173–2186.
              42. Harrop, B. E. and D. L. Hartmann (2015), The Relationship between Atmospheric Convective Radiative Effect and Net Energy Transport in the Tropical Warm PoolJ. Climate, 28(21), 8620–8633, doi:10.1175/JCLI-D-15-0151.1.
              43. Harrop, B. E. and D. L Hartmann (2016), The role of cloud radiative heating within the atmosphere on the high cloud amount and top-of-atmosphere cloud radiative effectJ. Adv. Model. Earth Syst., 8, 1391–1410, doi:10.1002/2016MS000670.
              44. Harshvardhan, R. C. E. Jr. (1995), Simple parameterizations of the radiative properties of cloud layers: a reviewAtmos. Res., 35, 113–125.
              45. Hartmann, D. L. and D. A. Short (1980), On the use of earth radiation budget statistics for studies of clouds and climateJ. Atmos. Sci., 37, 1233–1249.
              46. Heastie, R. and D. H. Martin (1962), Collision-Induced Absorption of Submillimeter Radiation by Non-Polar Atmospheric GasesCan. J. Phys., 40, 122–127.
              47. Held, I. M. and B. J. Soden (2000), Water Vapor Feedback and Global WarmingAnnu. Rev. Energy Environ., 25, 441–475.
              48. Herman, G. F., M.-L.C. Wu, and W.T. Johnson (1980), The effect of clouds on the Earth's solar and infrared radiation budgetsJ. Atmos. Sci., 37, 1251–1261.
              49. Herring, D. (2002), Does the Earth Have an Iris Analog?, EOStudy.
              50. Hovenier, J. W. and C. V. M. van der Mee (1996), Testing Scattering Matrices: A Compendium of RecipesJ. Quant. Spectrosc. Radiat. Transfer, 55(4), 649–661.
              51. Iacono, M. J., E. J. Mlawer, and S. A. Clough (2000), Impact of an improved longwave radiation model, RRTM, on the energy budget and thermodynamic properties of the NCAR community climate model, CCM3J. Geophys. Res., 105(D11), 14,873–14,890.
              52. Ide, K., H. Le Treut, Z.-X. Li, and M. Ghil (2001), Atmospheric radiative equilibria. Part II: bimodal solutions for atmospheric optical propertiesClimate Dynamics, 18, 29–49.
              53. Iwasa, Y., Y. Abe, and H. Tanaka (2004), Global Warming of the Atmosphere in Radiative-Convective EquilibriumJ. Atmos. Sci., 61, 1894–1910.
              54. Kaplan, L. D. (1959), Inference of Atmospheric Structure from Remote Radiation MeasurementsJ. Optical Soc. o. Am., 49(10), 1004–1007.
              55. Kiehl, J. T. and Kevin E. Trenberth (1997), Earth's Annual Global Mean Energy BudgetBull. Amer. Met. Soc., 2(78), 197–208.
              56. Kim, D. and V. Ramanathan (2008), Solar radiation budget and radiative forcing due to aerosols and cloudsJ. Geophys. Res., 113(D02), D02203, doi:10.1029/2007JD008434.
              57. Knapp, K. R. (2012), Intersatellite bias of the high-resolution infrared radiation sounder water vapor channel determined using ISCCP B1 dataJ. Appl. Rem. Sens., 6(1), 1–19, doi:10.1117/1.JRS.6.063523.
              58. Koch, D., Y. Balkanski, S. E. Bauer, R. C. Easter, S. Ferrachat, S. J. Ghan, C. Hoose, T. Iversen, A. Kirkevåg, J. E. Kristjansson, X. Liu, U. Lohmann, S. Menon, J. Quaas, M. Schulz, Ø. Seland, T. Takemura, and N. Yan (2011), Soot microphysical effects on liquid clouds, a multi-model investigationAtmos. Chem. Phys., 11, 1051–1064, doi:10.5194/acp-11-1051-2011.
              59. Lal, M. (2001), A model study of the atmospheric heating rates due to O3, H2O and O2Indian J. of Radio & Space Physics, 30, 254–259.
              60. van Lammeren, A., et al. (1999), Clouds and Radiation: Intensive Experimental Study of clouds and Radiation in the Netherlands (CLARA), Proc. Symposium Remote Sensing of Cloud Parameters: Retrieval and Validation.
              61. Lau, K.-M., C.-H. Ho, and I.-S. Kang (1998), Anomalous Atmospheric Hydrologic Processes Associated with ENSO: Mechanisms of Hydrologic Cycle-Radiation InteractionJ. Climate, 11, 800–815.
              62. Learner, R. C. M., W. Zhong, J. D. Haigh, D. Belmiloud, and J. Clarke (1999), The Contribution of Unknown Weak Water Vapor Lines to the Absorption of Solar RadiationGeophys. Res. Lett., 26(24), 3609–3612, doi:10.1029/1999GL003681.
              63. L'Ecuyer, T. S., N. B. Wood, T. Haladay, G. L. Stephens, and P. W. Stackhouse Jr. (2008), Impact of clouds on atmospheric heating based on the R04 CloudSat fluxes and heating rates data setJ. Geophys. Res., 113, D00A15, doi:10.1029/2008JD009951.
              64. Lesht, B. M. and J. C. Liljegren (1996), Comparison of Precipitable Water Vapor Measurements Obtained by Microwave Radiometry and Radiosondes at the Southern Great Plains Cloud and Radiation Testbed Site, Argonne National Laboratory, Pacific Northwest National Laboratory.
              65. Lindzen, R. S., M.-D. Chou, and A. Y. Hou (2001), Does the Earth Have an Adaptive Infrared Iris?Bull. Amer. Met. Soc., 82(3), 417–432.
              66. Lindzen, R. S., M.-D. Chou, and A. Y. Hou (2002), Comment on "No Evidence for Iris"Bull. Amer. Met. Soc., 345–349.
              67. Lio, F., G. J. Smallwood, and O. L. Guelder (2001), Application of the statistical narrow-band correlated-k method to non-grey gas radiation in CO2-H2O mixtures: approximate treatment of overlapping bandsJ. Quant. Spectrosc. Radiat. Transfer, 68, 401–417.
              68. Liou, K. N. (2002), An Introduction to Atmospheric Radiation, Elsevier Science (USA), ISBN 0-12-451451-0.
              69. Liou, K. N. (2002), An Introduction to Atmospheric Radiation, chap. Light scattering by atmospheric particulates, Academic Press.
              70. Liou, K.-N. and Q. Zheng (1984), A Numerical Experiment on the Interactions of Radiation, Clouds and Dynamic Processes in a General Circulation ModelJ. Atmos. Sci., 41(9), 1513–1536, doi:10.1175/1520-0469(1984)041<1513:ANEOTI>2.0.CO;2.
              71. Liou, K. N. (1992), Radiation and Cloud Processes in the Atmosphere: Theory, Observation and Modeling, Oxford University Press, ISBN 978-0195049107.
              72. Liu, F., G. J. Smallwood, and O. L. Guelder (2001), Application of the statistical narrow-band correlated-k method to non-grey gas radiation in CO2-H2O mixtures: approximate treatments of overlapping bandsJ. Quant. Spectrosc. Radiat. Transfer, 68, 401–417, doi:10.1016/S0022-4073(00)00033-9.
              73. Liu, Q., F. Weng, and Y. Han (2008), Conversion issues between microwave radiance and brightness temperatureJ. Quant. Spectrosc. Radiat. Transfer, 109, 1943–1950, doi:10.1016/j.jqsrt.2008.03.001.
              74. Liu, C. C. and R. L. Dougherty (1999), Development of Radiative Transfer Equations for the Scattering of Polarized Light in a Plane-Parallel MediumJ. Quant. Spectrosc. Radiat. Transfer, 61(1), 1–18.
              75. Loeb, N. G., S. Kato, and B. A. Wielicki (2002), Defining Top-of-the-Atmosphere Flux Reference Level for Earth Radiation Budget StudiesJ. Climate, 15, 3301–3309.
              76. Loeb, N. G., S. Kato N. Manalo-Smith, and D. R. Doelling (2005), Angular Distribution Models for Top-of-Atmosphere Radiative Flux Estimation from the Clouds and the Earth's Radiant Energy System Instrument on the Terra Satellite. Part II: ValidationJ. Atmos. Oceanic Technol.
              77. Loeb, N. G., S. Kato, K. Loukachine, and N. Manalo-Smith (2005), Angular Distribution Models for Top-of-Atmosphere Radiative Flux Estimation from the Clouds and the Earth's Radiant Energy System Instrument on the Terra Satellite. Part I: MethodologyJ. Atmos. Oceanic Technol., 22, 338–35.
              78. Mapes, B. E. (2016), Gregarious convection and radiative feedbacks in idealized worldsJ. Adv. Model. Earth Syst., 8(2), 1029–1033, doi:10.1002/2016MS000651.
              79. Marion, J. B. and M. A. Heald (1980), Classical Electromagnetic Radiation, University of Maryland, Swarthmore College.
              80. Markov, V. N., Y. Xu, and W. Jaeger (1998), Microwave-submillimeter wave double-resonance spectrometer for the investigation of van der Waals complexesRev. Sci. Inst., 69(12), 4061–4067.
              81. Miller, P. F. and H. A. Gebbie (1993), Stimulated Emission of Atmospheric Water Vapour between 2cm-1 and 30cm-1 Photoinduced by Infrared RadiationInfrared Phys., 34(1), 23–31.
              82. Miller, P. F. and H. A. Gebbie (1993), Temporal Effects in Millimetre Wave Aerosol Spectra and the Influence of Infrared RadiationInfrared Phys., 34(2), 143–152.
              83. Morcrette, J.-J., L. Illari, E. Klinker, H. Le Treut, M. Miller, P. Rasch, and M. Tiedtke (1991), Clouds and radiation, European Centre for Medium-Range Weather Forecasts.
              84. Muehler, D. and R. Weiss (1973), Balloon Measurements of the Far-Infrared Background RadiationPhys. Rev., 7(2), 326–344.
              85. Mugnai, A., P. Coppo, N. Grant, A. Slingo, L. Vial, P. Zimmermann, R. Bordi, A. Sutera, S. Tibaldi, J. Harries, M. Debois, and K. Kuenzi (1999), Report of the Pre-Phase A Industrial Study for a Cloud and Radiation Monitoring Satellite (Clouds), xxxx.
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