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 | active | aerosol | aerosols | age of air | aggregation | airs | albedo | algorithm | amsos | amsu | annual cycle | anomalies | aqua | ar4 | ar5 | arctic | arm | arts | arts-dev | asr | assimilation | astronomy | astrophysics | asymmetry | atmosphere | atmospheric composition | atmospheric dynamics | atmospheric profiles | atsr-2 | avhrr | bachelor thesis | backscattering | basics | bayes | bias | biomass | book | 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 | collocation | collocations | comparison | 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 | fall speed | far-infrared | faraday-voigt | fcdr | feedback | feedbacks | fingerprinting | flux uav | forcing | forest fire | fox19_airborne_amt.pdf | friend | fun | 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 | 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 | 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 | 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 | 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 | spectroscopy | 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 | wind | zeeman |

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Group references

In the Pipeline

    Articles

      2011 Back to top

    1. Kuhn, T., M. E. Earle, A. F. Khalizov, and J. J. Sloan (2011), Size dependence of volume and surface nucleation rates for homogeneous freezing of supercooled water dropletsAtmos. Chem. Phys., 11, 2853–2861, doi:10.5194/acp-11-2853-2011.

      2. 2010 Back to top

    2. Earle, M. E., T. Kuhn, A. F. Khalizov, and J. J. Sloan (2010), Volume nucleation rates for homogeneous freezing in supercooled water microdroplets: results from a combined experimental and modelling approachAtmos. Chem. Phys., 10(16), 7945–7961, doi:10.5194/acp-10-7945-2010.

    Books and Book Contributions

      Theses

        Technical Reports and Proposals

          Articles in Conference Proceedings and Newsletters

            Internal Reports

              External references

              1. Bailey, M. and J. Hallet (2003), Growth rates and habits of ice crystals between -20° and -70°J. Atmos. Sci., 61, 514–544.
              2. Bailey, M. P. and J. Hallett (2009), A Comprehensive Habit Diagram for Atmospheric Ice Crystals: Confirmation from the Laboratory, AIRS II, and Other Field StudiesJ. Atmos. Sci., 66(9), 2888–2899, doi:10.1175/2009JAS2883.1.
              3. Baran, A. J., P. J. Connolly, A. J. Heymsfield, and A. Bansemer (2010), Using in situ estimates of ice water content, volume extinction coefficient, and the total solar optical depth obtained during the tropical ACTIVE campaign to test an ensemble model of cirrus ice crystalsQ. J. R. Meteorol. Soc., doi:10.1002/qj.731.
              4. Baran, A. J. (2012), From the single-scattering properties of ice crystals to climate prediction: A way forwardAtmos. Res., 112, 45–69, doi:10.1016/j.atmosres.2012.04.010.
              5. Baran, Anthony J., Peter Hill, Kalli Furtado, Paul Field, and James Manners (2014), A Coupled Cloud Physics-Radiation Parameterization of the Bulk Optical Properties of Cirrus and its Impact on the Met Office Unified Model GlobalJ. Climate, in press, doi:10.1175/JCLI-D-13-00700.1.
              6. Baran, A. J., K. Furtado, L.-C. Labonnote, S. Havemann, J.-C. Thelen, and F. Marenco (2014), On the relationship between the scattering phase function of cirrus and the atmospheric stateAtmos. Chem. Phys. Discuss., 14, 14109–14157, doi:10.5194/acpd-14-14109-2014.
              7. Baum, B. A., D. P. Kratz, P. Yang, S. C. Ou, Y. X. Hu, P.F. Soulen, and S.-C. Tsay (2000), Remote sensing of cloud properties using MODIS airborne simulator imagery during SUCCESS. 1. Data and modelsJ. Geophys. Res., 105, 11767–11780, doi:10.1029/1999JD901089.
              8. Baum, B. A., A. J. Heymsfield, P. Yang, and S. T. Bedka (2005), Bulk Scattering Properties for the Remote Sensing of Ice Clouds. Part I: Microphysical Data and ModelsJ. Appl. Meteorol., 44, 1885–1895.
              9. Baumgardner, D. and B. E. Gandrud (1998), A comparison of the microphysical and optical properties of particles in an aircraft contrail and mountain wave cloudGeophys. Res. Lett., 25(8), 1129–1132.
              10. Benedetti, A., G. L. Stephens, and J. M. Haynes (2003), Ice cloud microphysics retrievals from millimeter radar and visible optical depth using an estimation theory approachJ. Geophys. Res., 108(D11), 4335, doi:10.1029/2002JD002693.
              11. Breon, F.-M. and B. Dubrulle (2004), Horizontally Oriented Plates in CloudsJ. Atmos. Sci., 61, 2888–2898.
              12. Brown, P. R. A. and H. A. Swann (1997), Evaluation of key microphysical parameters in three-dimensional cloud-model simulations using aircraft and multiparameter radar dataQ. J. R. Meteorol. Soc., 123, 2245–2275.
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              14. Cairo, F., G. D. Donfrancesco, M. Snels, F. Fierli, M. Viterbini, S. Borrmann, and W. Frey (2010), A comparison of light backscattering and particle size distribution measurements in tropical cirrus cloudsAtmos. Meas. Tech. Discuss., 3, 4059–4089, doi:10.5194/amtd-3-4059-2010.
              15. Chandrasekar, V., W. Li, and B. Zafar (2005), Estimation of raindrop size distribution from spaceborne radar observationsIEEE T. Geosci. Remote, 43(5), 1078–1086, doi:10.1109/TGRS.2005.846130.
              16. Chen, R., Z. Li, R. J. Kuligowski, R. Ferraro, and F. Weng (2011), A study of warm rain detection using A-Train satellite dataGeophys. Res. Lett., 38, L04804, doi:10.1029/2010GL046217.
              17. Claveau, C., A. Henry, D. Hurtmans, and A. Valentin (2001), Narrowing and broadening parameters of H2O lines perturbed by He, Ne, Kr and nitrogen in the spectral range 1850–2140 cm°-1J. Quant. Spectrosc. Radiat. Transfer, 68, 273–298.
              18. Clough, S. A., Y. Beers, G. P. Klein, and L. S. Rothman (1973), Dipole moment of water from Stark measurements of H2O, HDO, and D2OJ. Chem. Phys., 59(5), 2254–2259.
              19. Comstock, J. M., R. F. Lin, D. O. Starr, and P. Yang (2008), Understanding ice supersaturation, particle growth, and number concentration in cirrus cloudsJ. Geophys. Res., 113, D23211, doi:10.1029/2008JD010332.
              20. Considine, G. and J. A. Curry (1996), A statistical model of drop-size spectra for stratocumulus cloudsQ. J. R. Meteorol. Soc., 122, 611–634.
              21. Curtiss, L. A. and C. L. Eisgruber (1984), A theoretical study of the interaction of N2 with water molecules. (H2O)n: N2, n = 1-8.a)J. Chem. Phys., 80(5), 2022–2029.
              22. DeFrees, J. D., J. S. Blinkley, and A. D. McLean (1984), The quantum mechanical calculation of rotational spectra. A comparison of methods for C2H2, HCN, HNC, HCO+, N2H+, CO, and N2. Precictions for HCNH+, COH+, HBO, HBNH, and HBF+J. Chem. Phys., 80(8), 3720–3725.
              23. Donovan, D. P. (2003), Ice-cloud effective particle size parameterization based on combined lidar, radar reflectivity, and mean Doppler velocity measurementsJ. Geophys. Res., 108(D18), doi:10.1029/2003JD003469.
              24. Dowling, D. R. and L. F. Radke (1990), A summary of the physical properties of cirrus cloudsJ. Appl. Meteorol., 29, 970–978.
              25. Duda, D. P., J. D. Spinhirne, and W. D. Hart (1998), Retrieval of contrail microphysical properties during SUCCESS by the split-window methodGeophys. Res. Lett., 25(8), 1149–1152.
              26. Dyke, T. R. and J. S. Muenter (1973), Electric dipole moments of low J states of H2O and D2OJ. Chem. Phys., 59(6), 3125–3127.
              27. Eidhammer, T., P. J. DeMott, and S. M. Kreidenweis (2009), A comparison of heterogeneous ice nucleation parameterizations using a parcel model frameworkJ. Geophys. Res., 114, D06202, doi:10.1029/2008JD011095.
              28. Fan, J., M. Ovtchinnikov, J. M. Comstock, S. A. McFarlane, and A. Khain (2009), Ice formation in Arctic mixed-phase clouds: Insights from a 3-D cloud-resolving model with size-resolved aerosol and cloud microphysicsJ. Geophys. Res., 114, D04205, doi:10.1029/2008JD010782.
              29. Fermi, E. (1966), Molecules, Crystals, and Quantum Statistics, Dell'Accademia D'Italia.
              30. Field, P. R., R. J. Hogan, P. R. A. Brown, A. J. Illingworth, T. W. Choularton, and R. J. Cotton (2005), Parametrization of Ice Particle Size Distributions For Mid-latitude Stratiform CloudQ. J. R. Meteorol. Soc., 131, 1997–2019.
              31. Frey, W., S. Borrmann, D. Kunkel, R. Weigel, M. de Reus, H. Schlager, A. Roiger, C. Voigt, P. Hoor, J. Curtius, M. Krämer, C. Schiller, C. M. Volk, C. D. Homan, F. Fierli, G. Di Donfrancesco, A. Ulanovsky, F. Ravegnani, N. M. Sitnikov, S. Viciani, F. D'Amato, G. N. Shur, G. V. Belyaev, K. S. Law, and F. Cairo (2011), In-situ measurements of tropical cloud properties in the West African monsoon: upper tropospheric ice clouds, mesoscale convective system outflow, and subvisual cirrusAtmos. Chem. Phys., 11, 5569–5590, doi:10.5194/acp-11-5569-2011.
              32. Fu, Q. and K. N. Liou (1993), Parameterization of the Radiative Properties of Cirrus CloudsJ. Atmos. Sci., 50, 2008–2025, doi:10.1175/1520-0469(1993)050<2008:POTRPO>2.0.CO;2.
              33. Fu, Q. (1996), An Accurate Parameterization of the Solar Radiative Properties of Cirrus for Climate ModelsJ. Climate, 9(9), 2058–2082, doi:10.1175/1520-0442(1996)009<2058:AAPOTS>2.0.CO;2.
              34. Gallagher, M. W., P. J. Connolly, J. Whiteway, D. Figueras-Nieto, M. Flynn, T. W. Choularton, K. N. Bower, and J. Hacker (2005), An overview of the microphysical structure of cirrus clouds observed during EMERALD-1Q. J. R. Meteorol. Soc., 131, 1143–1169, doi:10.1256/qj.03.138.
              35. Gerber, H., C. H. Twohy, B. Gandrud, A. J. Heymsfield, G. M. McFarquhar, P. J. DeMott, and D. C. Rogers (1998), Measurements of wave-cloud microphysical properties with two new aircraft probesGeophys. Res. Lett., 25(8), 1117–1120.
              36. Goodman, J., R. F. Pueschel, E. J. Jensen, S. Verma, G. V. Ferry, S. D. Howard, S. A. Kinne, and D. Baumgardner (1998), Shape and Size of Contrails Ice ParticlesGeophys. Res. Lett., 25(9), 1327–1330, doi:10.1029/97GL03091.
              37. Hanesch, M. (1999), Fall Velocity and Shape of Snowflakes, Swiss Federal Institute of Technology.
              38. Heymsfield, A. J., S. Lewis, A. Bansemer, J. Iaquinta, L. M. Miloshevich, M. Kajikawa, C. Twohy, and M. R. Poellot (2002), A general approach for deriving the properties of cirrus and stratiform ice cloud particlesJ. Atmos. Sci., 59, 3–29.
              39. Heymsfield, A. J. and L. M. Miloshevic (2002), Parameterizations for the Cross-Sectional Area and Extinction of Cirrus Stratiform Ice Cloud ParticlesJ. Atmos. Sci., 60, 936–956.
              40. Heymsfield, A. J., S. Matrosov, and B. Baum (2003), Ice water path - optical depth relationships for cirrus and deep stratiform ice cloud layersJ. Appl. Meteorol., 42(20), 1369–1390.
              41. Heymsfield, A. J. (2003), Properties of tropical and midlatitude ice cloud particle ensembles, Part I: Median Mass Diameters and Terminal VelocitiesJ. Atmos. Sci., 60, 2592–2611.
              42. Heymsfield, A. J. (2003), Properties of tropical and midlatitude ice cloud particle ensembles, Part II: Applications for mesoscale and climate modelsJ. Atmos. Sci., 60, 2592–2611.
              43. Heymsfield, A. J., C. G. Schmitt, A. Bansemer, D. Baumgardner, E. M. Weinstock, J. T. Smith, and D. Sayres (2004), Effective Ice Particle Densities for Cold Anvil CirrusGeophys. Res. Lett., 31.
              44. Heymsfield, A. J., A. Bansemer, C. Schmitt, C. Twohy, and M. R. Poellot (2004), Effective Ice Particle Densities Derived from Aircraft DataJ. Atmos. Sci., 61, 982–1003, doi:10.1175/1520-0469(2004)061<0982:EIPDDF>2.0.CO;2.
              45. Heymsfield, A. J., L. M. Misloshevich, C. Schmitt, and A. Bansemer (2005), Homogeneous ice nucleation in subtropical convection and its influence on cirrus anvil microphysicsJ. Atmos. Sci., 62, 41–64.
              46. Heymsfield, A. J., C. Schmitt, A. Bansemer, G.-J. van Zadelhoff, M. J. McGill, C. Twohy, and D. Baumgardner (2006), Effective Radius of Ice Cloud Particle Populations Derived from Aircraft ProbesJ. Atmos. Oceanic Technol., 23, 361–380.
              47. Heymsfield, A. J. and C. D. Westbrook (2010), Advances in the Estimation of Ice Particle Fall Speeds Using Laboratory and Field MeasurementsJ. Atmos. Sci., 67, 2469–2482, doi:10.1175/2010JAS3379.1.
              48. Heymsfield, A. J. and C. M. R. Platt (1984), A Parameterization of the Particle Size Spectrum of Ice Clouds in Terms of the Ambient Temperature and the Ice Water ContentJ. Atmos. Sci., 41(5), 846–855, doi:10.1175/1520-0469(1984)041<0846:APOTPS>2.0.CO;2.
              49. Heymsfield, A. J. and L. M. Miloshevich (1995), Relative Humidity and Temperature Influences on Cirrus Formation and Evolution: Observations from Wave Clouds and FIRE IIJ. Atmos. Sci., 52, 4302–4326.
              50. Heymsfield, A. J. and G. M. McFarquhar (1996), High Albedos of Cirrus in the Tropical Pacific Warm Pool: Microphysical Interpretations from CEPEX and from Kwajalein, Marshall IslandsJ. Atmos. Sci., 53(17), 2424–2451, doi:10.1175/1520-0469(1996)053<2424:HAOCIT>2.0.CO;2.
              51. Holt, A. R., R. J. Cummings, G. J. G. Upton, and W. J. Bradford (2008), Rain rates, drop size information, and precipitation type, obtained from one-way differential propagation phase and attenuation along a microwave linkRadio Sci., 43, RS5009, doi:10.1029/2007RS003773.
              52. Ivanova, D., D. L. Mitchell, W. P. Arnott, and M. Poellot (2001), A GCM Parameterization for Bimodal Size Spectra and Ice Mass Removal Rates in Mid- latitude Cirrus CloudsAtmos. Res., 59–60, 89–113.
              53. Kärcher, B. and U. Lohmann (2002), A parameterization of cirrus cloud formations: Homogeneous freezing including the effects of arerosol sizeJ. Geophys. Res., 107, doi:10.1029/2001JD001429.
              54. Kärcher, B. and U. Lohmann (2002), A parameterization of cirrus cloud formation: Homogeneous freezing of supercooled aerosolsJ. Geophys. Res., 107, doi:10.1029/2001JD000470.
              55. Kärcher, B. (2002), Properties of subvisible cirrus clouds formed by homogeneous freezingAtmos. Chem. Phys., 2, 161–170, doi:10.5194/acp-2-161-2002.
              56. Kärcher, B. and U. Lohmann (2003), A parameterization of cirrus cloud formation: Heterogeneous freezingJ. Geophys. Res., 108, doi:10.1029/2002JD003220.
              57. Kärcher, B. and J. Ström (2003), The roles of dynamical variability and aerosols in cirrus cloud formationAtmos. Chem. Phys., 3, 823–838, doi:10.5194/acp-3-823-2003.
              58. Kärcher, B. (2004), Cirrus clouds in the tropical tropopause layer: Role of heteorogeneous ice nucleiGeophys. Res. Lett., 31.
              59. Kessler, E. (1969), On the Distribution and Continuity of Water Substance in Atmospheric CirculationMeteorological Monograph, 10, 1–84, ASIN B0007DQFF4.
              60. Khain, A. M., M. Ovtchinnikov, M. Pinsky, A. Pokrovsky, and H. Krugliak (2000), Notes on the state-of-the-art numerical modelling of cloud microphysicsAtmos. Res., 55, 159–224.
              61. Kinne, S., T. P. Ackerman, M. Shiobara, A. Uchiyama, A. J. Heymsfield, L. Miloshevich, J. Wendell, E. Eloranta, C. Purgold, and R. W. Bergstrom (1997), Cirrus Cloud Radiative and Microphysical Properties From Ground Observations and In Situ Measurements During Fire 1991 and Their Application to Exhibit Problems in Cirrus Solar Radiative Transfer ModelingJ. Atmos. Sci., 54, 2320–2344.
              62. Kneifel, Stefan, U. Löhnert, A. Battaglia, S. Crewell, and D. Siebler (2010), Snow scattering signals in ground-based passive microwave radiometer measurementsJ. Geophys. Res., 115, D16214, doi:10.1029/2010JD013856.
              63. Knollenberg, R. G. and D. M. Hunten (1980), The Microphysics of the Clouds of Venus: Results of the Pioneer Venus Particle Size Spectrometer ExperimentJ. Geophys. Res., 85(A13), 8039–8058, doi:10.1029/JA085iA13p08039.
              64. Knollenberg, R. G., K. Kelly, and J. C. Wilson (1993), Measurements of high number densities of ice crystals in the tops of tropical cumulonimbusJ. Geophys. Res., 98(D5), 8639–8664.
              65. 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.
              66. Korolev, A. V., G. A. Isaac, I. P. Mazin, and H. W. Barker (2001), Microphysical properties of continental clouds from in-situ measurementsQ. J. R. Meteorol. Soc.
              67. Korolev, A. V., G. A. Isaac, S. G. Cober, J. W. Strapp, and J. Hallett (2003), Microphysical Characterization of Mixed Phase CloudsQ. J. R. Meteorol. Soc., 129, 39–65.
              68. Korolev, A. and G. Isaac (2003), Roundness and Aspect Ratio of Particles in Ice cloudsJ. Atmos. Sci., 60, 1795–1808.
              69. Korolev, A. V. and I. P. Mazin (2003), Supersaturation of Water Vapor in CloudsJ. Atmos. Sci., 60, 2957–2974.
              70. Krämer, M., C. Rolf, A. Luebke, A. Afchine, N. Spelten, A. Costa, J. Meyer, M. Zöger, J. Smith, R. L. Herman, B. Buchholz, V. Ebert, D. Baumgardner, S. Borrmann, M. Klingebiel, and L. Avallone (2016), A microphysics guide to cirrus clouds — Part 1: Cirrus typesAtmos. Chem. Phys., 16, 3463–3483, doi:10.5194/acp-16-3463-2016.
              71. Krasnopolsky, V. A. (1985), Chemical Composition of Venus CloudsPlanet. Space Sci., 33(1), 109–117, doi:10.1016/0032-0633(85)90147-3.
              72. Kristjánsson, J. E., J. M. Edwards, and D. L. Mitchell (2000), Impact of a new scheme for optical properties of ice crystals on climates of two GCMsJ. Geophys. Res., 105(D8), 10063–10079, doi:10.1029/2000JD900015.
              73. Kuebbeler, M., M. Hildebrandt, J. Meyer, C. Schiller, T. Hamburger, T. Jurkat, A. Minikin, A. Petzold, M. Rautenhaus, H. Schlager, U. Schumann, C. Voigt, P. Spichtinger, J. F. Gayet, C. Gourbeyre, and M. Kramer (2010), Thin and subvisible cirrus and contrails in a subsaturated environmentAtmos. Chem. Phys. Discuss., 10, 31153–31186, doi:10.5194/acpd-10-31153-2010.
              74. Kumar, S. V. Sunil, K. Parameswaran, and B. V. Krishna Murthy (2003), Lidar Observations of Cirrus Cloud Near the Tropical Tropopause: General FeaturesAtmos. Res., 66, 203–227.
              75. Lawson, R. P., K. Stamnes, J. Stamnes, P. Zmarzly, J. Koskuliks, C. Roden, Q. Mo, and M. Carrithers (2010), Deployment of a Tethered Balloon System for Microphysics and Radiative Measurements in Mixed-Phase Clouds at Ny-Ålesund and South PoleJ. Atmos. Oceanic Technol., Preliminary accepted version, doi:10.1175/2010JTECHA1439.1.
              76. Lawson, R. P., S. Woods, and H. Morrison (2015), The Microphysics of Ice and Precipitation Development in Tropical Cumulus CloudsJ. Atmos. Sci., 72(6), 2429–2445, doi:10.1175/JAS-D-14-0274.1.
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