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

      2002 Back to top

    1. Kuhn, T., A. Bauer, M. Godon, S. A. Buehler, and K. Kuenzi (2002), Water vapor continuum: Absorption measurements at 350 GHz and model calculationsJ. Quant. Spectrosc. Radiat. Transfer, 74(5), 545–562, doi:10.1016/S0022-4073(01)00271-0.

    Books and Book Contributions

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        Technical Reports and Proposals

          Articles in Conference Proceedings and Newsletters

            Internal Reports

              External references

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              10. Barton, I. J. (1991), Infrared continuum water vapor absorption coefficients derived from satellite dataAppl. Opt., 30(21), 2929–2934.
              11. Bauer, A. and M. Godon (2001), Continuum for H2O-X mixtures in the H2O spectral window at 239 GHz; X=C2H4, C2H6 Are collision-induced absorption processes involved?J. Quant. Spectrosc. Radiat. Transfer, 69, 277–290.
              12. Bauer, A., B. Duterage, and M. Godon (1986), Temperature dependence of water-vapor absorption in the wing of the 183 GHz lineJ. Quant. Spectrosc. Radiat. Transfer, 36(4), 307–318.
              13. Bauer, A. and M. Godon (1991), Temperature dependence of water-vapor absorption in linewings at 190 GHzJ. Quant. Spectrosc. Radiat. Transfer, 46(3), 211–220.
              14. Bauer, A., M. Godon, J. Carlier, Q. Ma, and R. H. Tipping (1993), Absorption by H2O and H2O-N2 Mixtures at 153 GHzJ. Quant. Spectrosc. Radiat. Transfer, 50(5), 463–475.
              15. Bauer, A., M. Godon, and Q. Ma (1995), Water vapor absorption in the atmospheric window at 239 GHzJ. Quant. Spectrosc. Radiat. Transfer, 53(4), 411–423.
              16. Bauer, A., M. Godon, J. Carlier, and R. R. Gamache (1996), Absorption of a H2O-CO2 Mixture in the Atmospheric Windows at 239 GHz; H2O-CO2 Linewidths and ContinuumJ. Molec. Spectro., 45–57.
              17. Bauer, A., M. Godon, J. Carlier, and R. R. Gamache (1998), Continuum in the Windows of the Water Vapor Spectrum. Absorption of H2O-Ar at 239 GHz and Linewidth CalculationsJ. Quant. Spectrosc. Radiat. Transfer, 59(3–5), 273–285.
              18. 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.
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              20. Ben-Reuven, A. (1965), Transition from Resonant to Nonresonant Line Shape in Microwave AbsorptionPhys. Rev., 14(10), 349–351.
              21. Bennartz, R. and U. Lohmann (2001), Impact of improved near infrared water vapor line data on absorption of solar radiation in GCMsGeophys. Res. Lett., 28(24), 4591–4594.
              22. Beringer, R. (1946), The Absorption of One-Half Centimeter Electromagnetic Waves in OxygenPhys. Rev., 70(1 and 2), 53–57.
              23. Bernath, P., M. Carleer, S. Fally, A. Jenouvrier, A. C. Vandaele, C. Hermans, M.-F. Merienne, and R. Colin (1998), The Wulf bands of oxygenChem. Phys. Lett., 297, 293–299.
              24. Betzler, K. (2002), Fabry-Perot Interferometer, Universitaet Osnabrueck.
              25. Birnbaum, G. and A. A. Maryott (1962), Collision-Induced Microwave Absorption in Compressed Gases. II. Molecular Electric Quadrupole MomentsJ. Chem. Phys., 36(8), 2032–2036.
              26. Birnbaum, G. (1966), Theory of Microwave Nonresonant Absorption and Relaxation in GasesPhys. Rev., 150(1), 101–109.
              27. Birnbaum, G. and E. R. Cohen (1976), Theory of line shape in pressure-induced absorptionCan. J. Phys., 54, 593–602.
              28. Birnbaum, G., A. Borysow, and A. Buechele (1993), Collision-induced absorption in mixtures of symmetrical linear and tetrahedral molecules: Methane-nitrogenJ. Chem. Phys., 99(5), 3234–3243.
              29. Birnbaum, G., A. Borysow, and G. S. Orton (1996), Collision-Induced Absorption of H2-H2 and H2-He in the Rotational and Fundamental Bands for Planetary ApplicationsIcarus, 123, 4–22.
              30. Birnbaum, G. (1111), Collision Induced Spectroscopy: Absorption and Light Scattering, Gaithersburg MD, University of Texas at Austin, University of Manitoba.
              31. Bohren, C. and D. R. Huffman (1998), Absorption and Scattering of Light by Small Particles, Wiley Science Paperback Series.
              32. Boissoles, J., C. Boulet, R. H. Tipping, A. Brown, and Q. Ma (2003), Theoretical calculation of the translation-rotation collision-induced absorption in N2-N2, O2-O2, and N2-O2 pairsJ. Quant. Spectrosc. Radiat. Transfer, 82, 505–516.
              33. Boissoles, J., R. H. Tipping, and C. Boulet (1994), Theoretical Study of the Collision-Induced Fundamental Absorption Spectra of N2-N2 Pairs for Temperatures between 77 and 297 KJ. Quant. Spectrosc. Radiat. Transfer, 51(4), 615–627.
              34. Borysow, A. (2002), Collision-induced absorption in the infrared: A data base for modelling planetary and stellar atmospheres, University of Copenhagen.
              35. Borysow, A. and L. Frommhold (1986), Collision-Induced Rototranslational Absorption Spectra of N2-N2 Pairs for Temperatures from 50 to 300 KAstrophys. J., 311, 1043–1057.
              36. Borysow, A. and L. Frommhold (1986), Theoretical Collision-Induced Rototranslational Absorption Spectra for Modeling Titan's Atmosphere: H2-N2 PairsAstrophys. J., 303, 495–510.
              37. Borysow, A. and L. Frommhold (1986), Theoretical Collision-Induced Rototranslational Absorption Spectra for the outer Planets: H2-CH4 PairsAstrophys. J., 304, 849–865.
              38. Borysow, A. and M. Moraldi (1992), Effects of Anisotropic Interaction on Collision-Induced Absorption by Pairs of Linear MoleculesPhys. Rev. L, 68(25), 3686–3689.
              39. Bosisio, A. V. and G. Drufuca (2003), Retrieval of two-dimensional absorption coefficient structure from a scanning radiometer at 23.8 GHzRadio Sci., 38(3), doi:10.1029/2002RS002628.
              40. Bosomworth, D. R. and H. P. Gush (1965), Collision-Induced Absorption of Compressed Gases in the far infrared, Part ICan. J. Phys., 43, 729–750.
              41. Bosomworth, D. R. and H. P. Gush (1965), Collision-Induced Absorption of Compressed Gases in the far infrared, Part IICan. J. Phys., 43, 751–769.
              42. Boulet, C. and D. Robert (1982), Short time behavior of the dipole autocorrelation function and molecular gases absorption spectrumJ. Chem. Phys., 77(8), 4288–4299.
              43. Boulet, C. (1111), On some Aspects of Molecular Broadening, from Resonance to the far Wings, Universite de Rennes.
              44. Brindley, H. E. and J. E. Harries (1998), The Impact of Far I.R. Absorption on clear sky greenhouse forcing: sensitivity studies at high spectral resolutionJ. Quant. Spectrosc. Radiat. Transfer, 60(2), 151–180.
              45. Brown, W. B. and H. A. Gebbie (1992), Millimetre Wave Absorption by Aqueous Aerosol ClustersInfrared Phys., 33(5), 359–371.
              46. Buffey, I. P., W. B. Brown, and H. A. Gebbie (1990), A Theoretical Study of the Infrared Absorption Spectra of Large Water ClustersJ. Chem. Soc. Far. Trans., 86(13), 2357–2360.
              47. Buontempo, U., S. Cunsolo, and G. Jacucci (1975), The far infrared absorption spectrum of N2 in the gas and liquid phasesJ. Chem. Phys., 63(6), 2570–2576.
              48. Burch, D. E. (1968), Absorption of Infrared Radiant Energy by CO2 and H2O. III. Absorption by H2O between 0.5 and 36 cm-1 ( 287 μ – 2 cm)J. Optical Soc. o. Am., 58(10), 1383–1394.
              49. Burkhalter, J. H., R. S. Anderson, W. V. Smith, and W. Gordy (1949), A Preliminary Report on the Fine Structue of the Microwave Absoprtion Spectrum of Oxygen, Duke University.
              50. Burkhalter, J. H., R. S. Anderson, W. V. Smith, and W. Gordy (1950), The Fine Structur of the Microwave Absorption Spectrum of OxygenPhys. Rev., 79(4), 651–655.
              51. Carlon, H. R. (1978), Phase transition changes in the molecular absorption coefficient of water in the infrared: evidence for clustersAppl. Opt., 17(20), 3192–3193.
              52. Carlon, H. R. (1981), Infrared water vapor continuum absorption: equilibria of ions and neutral water clustersAppl. Opt., 20(8), 1316–1322.
              53. Cavalieri, S., E. Arimondo, and M. Matera (1992), Modification of the far-wing absorption profile due to collisional coherencePhys. Rev., 45(11), 8005–8010.
              54. Cheruy, F. and N. A. Scott (1995), Contribution to the development of radiative transfer models for high spectral resolution observations in infraredJ. Quant. Spectrosc. Radiat. Transfer, 53(6), 597–611.
              55. Chylek, P. and D. J. W. Geldart (1997), Water vapor dimers and atmospheric absorption of electromagnetic radiationGeophys. Res. Lett., 24(16), 2015–2018.
              56. Chylek, P., Q. Fu, H. C. W. Tso, and D. J. W. Geldart (1999), Contribution of water vapor dimers to clear sky absorption of solar radiationTellus, 51, 304–313.
              57. 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.
              58. Clough, S. A., F. X. Kneizys, and R. W. Davies (1989), Line Shape and the Water Vapor ContinuumAtmos. Res., 23, 229–241, doi:10.1016/0169-8095(89)90020-3.
              59. Collins, W. D., J. K. Hackney, and D. P. Edwards (2002), An updated parameterization for infrared emission and absorption by water vapor in the National Center for Atmospheric Research Community Atmosphere ModelJ. Geophys. Res., 107(D22), doi:10.1029/2001JD001365.
              60. Crawford, M. F., H. L. Welsh, and J. L. Locke (1949), Infra-Red Absorption of Oxygen and Nitrogen Induced by Intermolecular Forces, University of Toronto.
              61. Dagg, I. R., G. E. Reesor, and J. L. Urbaniak (1975), Collision Induced Absorption in N2, CO2, and H2 at 2.3 cm-1Can. J. Phys., 53, 1764–1776.
              62. Dagg, I. R., G. E. Reesor, and M. Wong (1978), A microwave cavity measurement of collision-induced absorption in N2 and CO2 at 4.6 cm-1Can. J. Phys., 56, 1037–1045.
              63. Dagg, I. R., A. Anderson an S. Yan, W. Smith, and L. A. A. Read (1985), Collision-induced absorption in nitrogen at low temperaturesCan. J. Phys., 63, 625–631.
              64. Daniel, J. S., S. Solomon, R. W. Sanders, R. W. Portmann, D. C. Miller, and W. Madsen (1999), Implications for water monomer and dimer solar absorption from observations at Boulder, ColoradoJ. Geophys. Res., 104(D14), 16,785–16,791.
              65. Danos, M. and S. Geschwind (1953), Broadening of Microwave Absorption Lines Due to Wall CollisionsPhys. Rev., 91(5), 1159–1162.
              66. Davis, G. R. (1993), The far infrared continuum absorption of water vaporJ. Quant. Spectrosc. Radiat. Transfer, 50(6), 673–694.
              67. de Pater, I. and S. T. Massie (1985), Models of the Millimeter-Centimeter Spectra of the Giant PlanetsIcarus, 62(1), 143–171, doi:10.1016/0019-1035(85)90177-0.
              68. Drayson, S. R. (1976), Rapid computation of the Voigt profileJ. Quant. Spectrosc. Radiat. Transfer, 16, 611–614.
              69. Dudhia, A., P. E. Morris, and R. J. Wells (2002), Fast monochromatic radiative transfer calculations for limb soundingJ. Quant. Spectrosc. Radiat. Transfer, 74(6), 745–756, doi:10.1016/S0022-4073(01)00285-0.
              70. Dumesh, B. S. and L. A. Surin (1996), Two highly sensitive microwave cavity spectrometersRev. Sci. Inst., 67(10), 3458–3465.
              71. Elsasser, W. M. (1938), Far Infrared Absorption of Atmospheric Water VaporAstrophys. J., 87(5), 497–507.
              72. Elsasser, W. M. (1938), Note on Atmospheric Absorption Caused by the Rotational Water BandPhys. Rev., 53, 768.
              73. Emery, R. J., P. Moffat, R. A. Bohlander, and H. A. Gebbie (1975), Measurements of anomalous atmospheric absorption in the wavenumber range 4 cm-1–15cm-1J. Atm. Terr. Phys., 37, 587–594.
              74. Emery, R. J., A. M. Zavody, and H. A. Gebbie (1980), Measurements of atmospheric absorption in the range 5-17 cm-1 and its temperature dependenceJ. Atm. Terr. Phys., 42, 801–807.
              75. English, S. J., C. Guillou, C. Prigent, and D. C. Jones (1994), Aircraft measurements of water vapour continuum absorption millimetre wavelengthsQ. J. R. Meteorol. Soc., 120, 603–625.
              76. English, S. J., D. C. Jones, P. J. Rayer, T. J. Hewison, R. W. Saunders, C. Guillou, C. Prigent, J. Wang, and G. Anderson (1995), Observations of water vapour absorption using airborne microwave radiometers at 89 and 157 GhzIEEE, 1395–1404.
              77. Erukhimova, T. L. and E. V. Suvorov (2001), Retrieval of Ozone-Denisty and Atmospheric-Temperature Profiles using the Spectra of Microwave Absorption in two Rotational Ozone LinesRadiophys. Quant. Elec., 44(1–2), 129–136.
              78. Evans, G. T. and V. Vaida (2000), Aggregation of water molecules: Atmospheric implicationsJ. Chem. Phys., 113(16), 6652–6659.
              79. Filippov, N. N., V. P. Ogibalov, and M. V. Tonkov (2002), Line mixing effect on the pure CO2 absorption in the 15 μm regionJ. Quant. Spectrosc. Radiat. Transfer, 72, 315–325.
              80. Fogarty, W. E. (1975), Total Atmospheric Absorption at 22.2 GHzIEEE Trans. Antennas Propag., 441–445.
              81. 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.
              82. Fowler, B. W. and C. C. Sung (1976), Inadequacy of the statistical many-body model for molecular infrared absorption in the far wingsPhys. Rev., 13(6), 2318–2321.
              83. Gagliardi, G., G. Rusciano, and L. Gianfrani (2000), Narrow H218O lines and new absolute frequency references in the near-IRJ. Opt. A: Pure Appl. Opt., 2, 310–313.
              84. Gaiduk, V. I. (2003), The Theory of the Second Relaxation Region in Liquid WaterOpt. Spectro., 94(2), 199–208.
              85. Gamache, R.R., S. Kennedy, R. Hawkins, and L.S. Rothman (2000), Total internal partition sums for molecules in the terrestrial atmosphereJ. Molec. Struct., 407–425.
              86. Gao, B.-C., K. Meyer, and P. Yang (2004), A new concept on remote sensing of cirrus optical depth and effective ice particle size using strong water vapor absorption channels near 1.38 and 1.88 micrometerIEEE T. Geosci. Remote, 42(9), 1891–1899.
              87. Godon, M., A. Bauer, and R. R. Gamache (2000), The Continuum of Water Vapor Mixed with Methane: Absolute Absorption at 239 GHz and Linewidth CalculationsJ. Molec. Spectro., 202, 293–202.
              88. Godon, M., J. Carlier, and A. Bauer (1992), Laboratory studies of water vapor absorption in the atmospheric window at 213 GHzJ. Quant. Spectrosc. Radiat. Transfer, 47(4), 275–285.
              89. Gokhale, B. V. and M. W. P. Strandberg (1951), Line Breadths in the 5-mm Microwave Absorption of Oxygen, Massachusetts Institute of Technology.
              90. Golovko, V. F. (2000), Dispersion formula and continuous absorption of water vaporJ. Quant. Spectrosc. Radiat. Transfer, 65, 621–644.
              91. Golovko, V. F. (2001), Continuous absorption of water vapor and a problem of the absorption enhancement in the humid atmosphereJ. Quant. Spectrosc. Radiat. Transfer, 69, 431–446.
              92. Golubiatnikov, G. Y., M. A. Koshelev, and A. F. Krupnov (2003), Reinvestigation of pressure broadening parameters at 60-GHz band and single 118.75 GHz oxygen lines at room temperatureJ. Molec. Spectro., 222, 191–197.
              93. Grant, W. B. (1990), Water vapor absorption coefficients in the 8–13 μm spectral region: a critical reviewAppl. Opt., 29(4), 451–463.
              94. Greenblatt, G. D., J. J. Orlando, J. B. Burkholder, and A. R. Ravishankara (1990), Absorption Measurements of Oxygen Between 330 and 1140 nmJ. Geophys. Res., 95(D11), 18,577–18,582.
              95. Groenenboom, G. C., E. M. Mas, R. Bukowski, K. Szalewicz, P. E. S. Wormer, and A. van der Avoird (2000), Water Pair and Three-Body Potential of Spectroscopic Quality from Ab Initio CalculationsPhys. Rev. L, 84(18), 4072–4075.
              96. Gross, E. P. (1955), Inertial Effects and Dielectric RelaxationJ. Chem. Phys., 23(8), 1415–1423.
              97. Gross, E. P. and J. Otieno-Malo (1972), Collision Broadening of Rotational SpectrumJ. Chem. Phys., 57(6), 2229–2239.
              98. Gruszka, M. and A. Borysow (1997), Roto-Translational Collision-Induced Absorption of CO2 for the Atmosphere of Venus at Frequencies from 0 to 250 cm-1, at Temperatures from 200 to 800 KIcarus, 172–177.
              99. Hannon, S., L. L. Strow, and W. W. McMillan (1996), Atmospheric Infrared Fast Transmittance Models: A Comparison of Two Approaches, University of Maryland Baltimore Country.
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