Water vapor sounding with the far infrared REFIR-PAD spectroradiometer from a high-altitude ground-based station during the ECOWAR campaign
Author(s)
Bianchini, G.
Istituto di Fisica Applicata “Nello Carrara,” Consiglio Nazionale delle Ricerche, Sesto Fiorentino, Italy
Palchetti, L.
Istituto di Fisica Applicata “Nello Carrara,” Consiglio Nazionale delle Ricerche, Sesto Fiorentino, Italy
Di Girolamo, P.
Dipartimento di Ingegneria e Fisica dell’Ambiente, Università della Basilicata, Potenza, Italy
Di Iorio, T.
Dipartimento di Fisica, Università di Roma “La Sapienza,” Rome, Italy
Language
English
Obiettivo Specifico
1.7. Osservazioni di alta e media atmosfera
1.10. TTC - Telerilevamento
Status
Published
JCR Journal
JCR Journal
Peer review journal
Yes
Journal
Journal of Geophysical Research
Issue/vol(year)
/116 (2011)
Publisher
American Geophysical Union
Pages (printed)
D02310
Date Issued
January 28, 2011
Last version
http://hdl.handle.net/2122/6345
Abstract
The Radiation Explorer in the Far InfraRed-Prototype for Applications and Development (REFIR-PAD) spectroradiometer was operated from the Testa Grigia Italian-Alps station in March 2007 during the Earth Cooling by Water Vapour Radiation (ECOWAR) measurement campaign, obtaining downwelling radiance spectra in the 100–1100 cm−1 range, under clear-sky conditions and in the presence of cirrus clouds. The analysis of these measurements has proven that the instrument is capable of determining precipitable water vapor with a total uncertainty of 5–7% by using the far-infrared rotational band of water. The measurement is unaffected by the presence of cirri, whose optical depth can be instead retrieved as an additional parameter. Information on the vertical profiles of water vapor volume mixing ratio and temperature can also be retrieved
for three altitude levels. The ability to measure the water vapor column with a simple,
uncooled instrument, capable of operating continuously and with a time resolution of
about 10 min, makes REFIR-PAD a very valuable instrument for meteorological and
climatological studies for the characterization of the water vapor distribution.
for three altitude levels. The ability to measure the water vapor column with a simple,
uncooled instrument, capable of operating continuously and with a time resolution of
about 10 min, makes REFIR-PAD a very valuable instrument for meteorological and
climatological studies for the characterization of the water vapor distribution.
References
Bhawar, R., et al. (2008), Spectrally resolved observations of Earth’s emission
spectrum in the H2O rotation band, Geophys. Res. Lett., 35, L04812,
doi:10.1029/2007GL032207.
Bianchini, G., and L. Palchetti (2008), Technical Note: REFIR‐PAD level
1 data analysis and performance characterization, Atmos. Chem. Phys., 8,
3817–3826.
Bianchini, G., L. Palchetti, and B. Carli (2006), A wide‐band nadir‐sounding
spectroradiometer for the characterization of the Earth’s outgoing longwave
radiation, Proc. SPIE Int. Soc. Opt. Eng., 6361, 63610A.
Bianchini, G., L. Palchetti, A. Baglioni, and F. Castagnoli (2007), Farinfrared
spectrally resolved broadband emission of the atmosphere from
Morello and Gomito mountains near Florence, Proc. SPIE Int. Soc. Opt.
Eng., 6745, 674518.
Bösenberg, J. (1998), Ground‐based differential absorption lidar for watervapor
and temperature profiling, Appl. Opt., 37, 3845–3860.
Clough, S. A., M. J. Iacono, and J. L. Moncet (1992), Line‐by‐line calculations
of atmospheric fluxes and cooling rates: Application to water
vapor, J. Geophys. Res., 97, 15,761–15,785, doi:10.1029/92JD01419.
Clough, S. A., M. W. Shephard, E. J. Mlawer, J. S. Delamere, M. J. Iacono,
K. Cady‐Pereira, S. Boukabara, and P. D. Brown (2005), Atmospheric
radiative transfer modeling: a summary of the AER codes: Short communication,
J. Quant. Spectrosc. Radiat. Transfer, 91, 233–244.
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 vapor, J. Geophys. Res., 115, D17106,
doi:10.1029/2009JD012968.
de Zafra, R. L., A. Parrish, P. M. Solomon, and J. W. Barrett (1983), A
quasi continuous record of atmospheric opacity at l = 1.1 mm over 34
days at Mauna Kea observatory, Int. J. Infrared Millimeter Waves, 4,
757–765.
Di Girolamo, P., R. Marchese, D. N. Whiteman, and B. B. Demoz (2004),
Rotational Raman Lidar measurements of atmospheric temperature in the
UV, Geophys. Res. Lett., 31, L01106, doi:10.1029/2003GL018342.
Di Girolamo, P., D. Summa, and R. Ferretti (2009), Rotational Raman
Lidar measurements for the characterization of stratosphere‐troposphere
exchange mechanisms, J. Atmos. Oceanic Technol., 26, 1742–1762.
Divakarla, M. G., C. D. Barnet, M. D. Goldberg, L. M. McMillin, E. Maddy,
W. Wolf, L. Zhou, and X. Liu (2006), Validation of Atmospheric Infrared
Sounder temperature and water vapor retrievals with matched radiosonde
measurements and forecasts, J. Geophys. Res., 111, D09S15, doi:10.1029/
2005JD006116.
Elliott, W. P., and D. J. Gaffen (1991), On the utility of radiosonde humidity
archives for climate studies, Bull. Am. Meteorol. Soc., 72, 1507–1520.
England, M. N., R. A. Ferrare, S. H. Melfi, D. N. Whiteman, and T. A.
Clark (1992), Atmospheric water vapor measurements: Comparison of
microwave radiometry and lidar, J. Geophys. Res., 97, 899–916,
doi:10.1029/91JD02384.
Fiorucci, I., et al. (2008), Measurements of low amounts of precipitable
water vapor by millimeter wave spectroscopy: An intercomparison with
radiosonde, Raman lidar, and Fourier transform infrared data, J. Geophys.
Res., 113, D14314, doi:10.1029/2008JD009831.
Gordon, I. E., L. S. Rothman, R. R. Gamache, D. Jaquemart, C. Boone, P. F.
Bernath, M. W. Shephard, J. S. Delamere, and S. A. Clough (2007),
Current updates of the water‐vapor line list in HITRAN: A new “Diet”
for air‐broadened half‐widths, J. Quant. Spectrosc. Radiat. Transfer,
108, 389–402, doi:10.1016/j.jqsrt.2007.06.009.
James, F. (1994), Minuit, function minimization and error analysis, reference
manual, D506, CERN, Geneva, Switzerland.
Kiehl, J. T., and K. E. Trenberth (1997), Earth’s Annual Global Mean
Energy Budget, Bull. Am. Meteorol. Soc., 78, 197–208.
Kneizys, F. X., E. P. Shettle, W. O. Gallery, J. H. Chetwynd Jr., L. W.
Abreu, J. E. A. Selby, R. W. Fenn, and R. A. McClatchey (1980), Atmospheric
transmittance/radiance: Computer code LOWTRAN 5, AFGLTR‐
80‐0670, Air Force Geophys. Lab., Hanscom AFB, Mass. Miloshevich, L. M., A. Paukkunen, H. Vömel, and S. J. Oltmans (2004),
Development and validation of a time‐lag correction for Vaisala radiosonde
humidity measurements, J. Atmos. Oceanic Technol., 21, 1305–
1327.
Niro, F., K. Jucks, and J.‐M. Hartmann (2005), Spectral calculations in central
and wing regions of CO2 IR bands, IV: Software and database for the
computation of atmospheric spectra, J. Quant. Spectrosc. Radiat. Transfer,
95, 469–481.
Palchetti, L., A. Barbis, J. E. Harries, and D. Lastrucci (1999), Design and
mathematical modelling of the space‐borne far‐infrared Fourier transform
spectrometer for REFIR experiment, Infrared Phys. Technol., 40,
367–377.
Palchetti, L., G. Bianchini, F. Castagnoli, B. Carli, C. Serio, F. Esposito,
V. Cuomo, R. Rizzi, and T. Maestri (2005), Breadboard of a Fouriertransform
spectrometer for the Radiation Explorer in the Far Infrared
atmospheric mission, Appl. Opt., 44, 2870–2878.
Palchetti, L., C. Belotti, G. Bianchini, F. Castagnoli, B. Carli, U. Cortesi,
M. Pellegrini, C. Camy‐Peyret, P. Jeseck, and Y. Té (2006), Technical
note: First spectral measurement of the Earth’s upwelling emission using
an uncooled wideband Fourier transform spectrometer, Atmos. Chem.
Phys., 6, 5025–5030.
Palchetti, L., G. Bianchini, B. Carli, U. Cortesi, and S. Del Bianco (2007),
Measurement of the water vapour vertical profile and of the Earth’s outgoing
far infrared flux, Atmos. Chem. Phys. Discuss., 7, 17,741–17,767.
Rizzi, R., B. Carli, J. E. Harries, J. Leotin, C. Serio, A. Sutera, B. Bizzarri,
R. Bonsignori, and S. Peskett (2001), Mission objectives and instrument
requirements for the (REFIR) Radiation Explorer in the Far‐InfraRed
mission: An outline after the end of phase B0, in Current Problems in
Atmospheric Radiation, edited by W. L. Smith and Y. M. Timofeyev,
pp. 567–570, A. Deepak, Hampton, Va.
Rothman, L. S., et al. (2005), The HITRAN 2004 molecular spectroscopic
database, J. Quant. Spectrosc. Radiat. Transfer, 96, 139–204.
Serio, C., F. Esposito, G. Masiello, G. Pavese, M. R. Calvello, G. Grieco,
V. Cuomo, H. L. Buijs, and C. B. Roy (2008), Interferometer for groundbased
observations of emitted spectral radiance from the troposphere:
Evaluation and retrieval performance, Appl. Opt., 47, 3909–3919.
Shephard, M. W., S. A. Clough, V. H. Payne, W. L. Smith, S. Kireev, and
K. E. Cady‐Pereira (2009), Performance of the line‐by‐line radiative
transfer model (LBLRTM) for temperature and species retrievals: IASI
case studies from JAIVEx, Atmos. Chem. Phys., 9, 7397–7417.
Sinha, A., and J. E. Harries (1995), Water vapour and greenhouse trapping:
The role of far infrared absorption, Geophys. Res. Lett., 22, 2147–2150,
doi:10.1029/95GL01891.
Smith, W. L., W. F. Feltz, R. O. Knuteson, H. E. Revercomb, H. M. Woolf,
and H. B. Howell (1999), The retrieval of planetary boundary layer structure
using ground‐based infrared spectral radiance measurement, J. Atmos.
Oceanic Technol., 16, 323–333.
Tobin, D. C., et al. (1999), Downwelling spectral radiance observations at
the SHEBA ice station: Water vapor continuum measurements from 17 to
26mm, J. Geophys. Res., 104, 2081–2092, doi:10.1029/1998JD200057.
Vömel, H., H. Selkirk, L. Miloshevich, J. Valverde‐Canossa, J. Valdés,
E. Kyrö, R. Kivi, W. Stolz, G. Peng, and J. A. Diaz (2007), Radiation
dry bias of the Vaisala RS92 humidity sensor, J. Atmos. Oceanic Technol.,
24, 953–963.
Wang, J. Y. (1974), On the estimation of low‐altitude water vapor profiles
from ground‐based infrared measurements, J. Atmos. Sci., 31, 513–521.
spectrum in the H2O rotation band, Geophys. Res. Lett., 35, L04812,
doi:10.1029/2007GL032207.
Bianchini, G., and L. Palchetti (2008), Technical Note: REFIR‐PAD level
1 data analysis and performance characterization, Atmos. Chem. Phys., 8,
3817–3826.
Bianchini, G., L. Palchetti, and B. Carli (2006), A wide‐band nadir‐sounding
spectroradiometer for the characterization of the Earth’s outgoing longwave
radiation, Proc. SPIE Int. Soc. Opt. Eng., 6361, 63610A.
Bianchini, G., L. Palchetti, A. Baglioni, and F. Castagnoli (2007), Farinfrared
spectrally resolved broadband emission of the atmosphere from
Morello and Gomito mountains near Florence, Proc. SPIE Int. Soc. Opt.
Eng., 6745, 674518.
Bösenberg, J. (1998), Ground‐based differential absorption lidar for watervapor
and temperature profiling, Appl. Opt., 37, 3845–3860.
Clough, S. A., M. J. Iacono, and J. L. Moncet (1992), Line‐by‐line calculations
of atmospheric fluxes and cooling rates: Application to water
vapor, J. Geophys. Res., 97, 15,761–15,785, doi:10.1029/92JD01419.
Clough, S. A., M. W. Shephard, E. J. Mlawer, J. S. Delamere, M. J. Iacono,
K. Cady‐Pereira, S. Boukabara, and P. D. Brown (2005), Atmospheric
radiative transfer modeling: a summary of the AER codes: Short communication,
J. Quant. Spectrosc. Radiat. Transfer, 91, 233–244.
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 vapor, J. Geophys. Res., 115, D17106,
doi:10.1029/2009JD012968.
de Zafra, R. L., A. Parrish, P. M. Solomon, and J. W. Barrett (1983), A
quasi continuous record of atmospheric opacity at l = 1.1 mm over 34
days at Mauna Kea observatory, Int. J. Infrared Millimeter Waves, 4,
757–765.
Di Girolamo, P., R. Marchese, D. N. Whiteman, and B. B. Demoz (2004),
Rotational Raman Lidar measurements of atmospheric temperature in the
UV, Geophys. Res. Lett., 31, L01106, doi:10.1029/2003GL018342.
Di Girolamo, P., D. Summa, and R. Ferretti (2009), Rotational Raman
Lidar measurements for the characterization of stratosphere‐troposphere
exchange mechanisms, J. Atmos. Oceanic Technol., 26, 1742–1762.
Divakarla, M. G., C. D. Barnet, M. D. Goldberg, L. M. McMillin, E. Maddy,
W. Wolf, L. Zhou, and X. Liu (2006), Validation of Atmospheric Infrared
Sounder temperature and water vapor retrievals with matched radiosonde
measurements and forecasts, J. Geophys. Res., 111, D09S15, doi:10.1029/
2005JD006116.
Elliott, W. P., and D. J. Gaffen (1991), On the utility of radiosonde humidity
archives for climate studies, Bull. Am. Meteorol. Soc., 72, 1507–1520.
England, M. N., R. A. Ferrare, S. H. Melfi, D. N. Whiteman, and T. A.
Clark (1992), Atmospheric water vapor measurements: Comparison of
microwave radiometry and lidar, J. Geophys. Res., 97, 899–916,
doi:10.1029/91JD02384.
Fiorucci, I., et al. (2008), Measurements of low amounts of precipitable
water vapor by millimeter wave spectroscopy: An intercomparison with
radiosonde, Raman lidar, and Fourier transform infrared data, J. Geophys.
Res., 113, D14314, doi:10.1029/2008JD009831.
Gordon, I. E., L. S. Rothman, R. R. Gamache, D. Jaquemart, C. Boone, P. F.
Bernath, M. W. Shephard, J. S. Delamere, and S. A. Clough (2007),
Current updates of the water‐vapor line list in HITRAN: A new “Diet”
for air‐broadened half‐widths, J. Quant. Spectrosc. Radiat. Transfer,
108, 389–402, doi:10.1016/j.jqsrt.2007.06.009.
James, F. (1994), Minuit, function minimization and error analysis, reference
manual, D506, CERN, Geneva, Switzerland.
Kiehl, J. T., and K. E. Trenberth (1997), Earth’s Annual Global Mean
Energy Budget, Bull. Am. Meteorol. Soc., 78, 197–208.
Kneizys, F. X., E. P. Shettle, W. O. Gallery, J. H. Chetwynd Jr., L. W.
Abreu, J. E. A. Selby, R. W. Fenn, and R. A. McClatchey (1980), Atmospheric
transmittance/radiance: Computer code LOWTRAN 5, AFGLTR‐
80‐0670, Air Force Geophys. Lab., Hanscom AFB, Mass. Miloshevich, L. M., A. Paukkunen, H. Vömel, and S. J. Oltmans (2004),
Development and validation of a time‐lag correction for Vaisala radiosonde
humidity measurements, J. Atmos. Oceanic Technol., 21, 1305–
1327.
Niro, F., K. Jucks, and J.‐M. Hartmann (2005), Spectral calculations in central
and wing regions of CO2 IR bands, IV: Software and database for the
computation of atmospheric spectra, J. Quant. Spectrosc. Radiat. Transfer,
95, 469–481.
Palchetti, L., A. Barbis, J. E. Harries, and D. Lastrucci (1999), Design and
mathematical modelling of the space‐borne far‐infrared Fourier transform
spectrometer for REFIR experiment, Infrared Phys. Technol., 40,
367–377.
Palchetti, L., G. Bianchini, F. Castagnoli, B. Carli, C. Serio, F. Esposito,
V. Cuomo, R. Rizzi, and T. Maestri (2005), Breadboard of a Fouriertransform
spectrometer for the Radiation Explorer in the Far Infrared
atmospheric mission, Appl. Opt., 44, 2870–2878.
Palchetti, L., C. Belotti, G. Bianchini, F. Castagnoli, B. Carli, U. Cortesi,
M. Pellegrini, C. Camy‐Peyret, P. Jeseck, and Y. Té (2006), Technical
note: First spectral measurement of the Earth’s upwelling emission using
an uncooled wideband Fourier transform spectrometer, Atmos. Chem.
Phys., 6, 5025–5030.
Palchetti, L., G. Bianchini, B. Carli, U. Cortesi, and S. Del Bianco (2007),
Measurement of the water vapour vertical profile and of the Earth’s outgoing
far infrared flux, Atmos. Chem. Phys. Discuss., 7, 17,741–17,767.
Rizzi, R., B. Carli, J. E. Harries, J. Leotin, C. Serio, A. Sutera, B. Bizzarri,
R. Bonsignori, and S. Peskett (2001), Mission objectives and instrument
requirements for the (REFIR) Radiation Explorer in the Far‐InfraRed
mission: An outline after the end of phase B0, in Current Problems in
Atmospheric Radiation, edited by W. L. Smith and Y. M. Timofeyev,
pp. 567–570, A. Deepak, Hampton, Va.
Rothman, L. S., et al. (2005), The HITRAN 2004 molecular spectroscopic
database, J. Quant. Spectrosc. Radiat. Transfer, 96, 139–204.
Serio, C., F. Esposito, G. Masiello, G. Pavese, M. R. Calvello, G. Grieco,
V. Cuomo, H. L. Buijs, and C. B. Roy (2008), Interferometer for groundbased
observations of emitted spectral radiance from the troposphere:
Evaluation and retrieval performance, Appl. Opt., 47, 3909–3919.
Shephard, M. W., S. A. Clough, V. H. Payne, W. L. Smith, S. Kireev, and
K. E. Cady‐Pereira (2009), Performance of the line‐by‐line radiative
transfer model (LBLRTM) for temperature and species retrievals: IASI
case studies from JAIVEx, Atmos. Chem. Phys., 9, 7397–7417.
Sinha, A., and J. E. Harries (1995), Water vapour and greenhouse trapping:
The role of far infrared absorption, Geophys. Res. Lett., 22, 2147–2150,
doi:10.1029/95GL01891.
Smith, W. L., W. F. Feltz, R. O. Knuteson, H. E. Revercomb, H. M. Woolf,
and H. B. Howell (1999), The retrieval of planetary boundary layer structure
using ground‐based infrared spectral radiance measurement, J. Atmos.
Oceanic Technol., 16, 323–333.
Tobin, D. C., et al. (1999), Downwelling spectral radiance observations at
the SHEBA ice station: Water vapor continuum measurements from 17 to
26mm, J. Geophys. Res., 104, 2081–2092, doi:10.1029/1998JD200057.
Vömel, H., H. Selkirk, L. Miloshevich, J. Valverde‐Canossa, J. Valdés,
E. Kyrö, R. Kivi, W. Stolz, G. Peng, and J. A. Diaz (2007), Radiation
dry bias of the Vaisala RS92 humidity sensor, J. Atmos. Oceanic Technol.,
24, 953–963.
Wang, J. Y. (1974), On the estimation of low‐altitude water vapor profiles
from ground‐based infrared measurements, J. Atmos. Sci., 31, 513–521.
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