Airborne and satellite remote sensing of the mid-infrared water vapour continuum

Newman, Stuart M.; Green, Paul D.; Ptashnik, Igor V.; Gardiner, Tom; Coleman, Marc D.; McPheat, Robert

doi:10.1098/rsta.2011.0223

Cited by 19 publications

(19 citation statements)

References 34 publications

(74 reference statements)

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“…This model is a semi‐empirical formulation which includes ad hoc line profile parameters adjusted to account for experimental constraints. As consequence of the difficulty to measure weak broadband absorption signals, the available experimental information is scarce and consists mainly of laboratory [ Burch , ; Burch and Alt , ; Burch , ; Cormier et al ., ; Baranov et al , ] and field measurements in the microwave and midinfrared regions [ Newman et al ., ] which have the strongest impact on the radiative fluxes [ Clough et al ., ; Costa and Shine , ]. The major constraint of the MT_CKD self‐continuum in the 10 µm window is an analysis of field measurements [e.g., Turner et al ., ].…”

Section: Introductionmentioning

confidence: 99%

Accurate laboratory determination of the near‐infrared water vapor self‐continuum: A test of the MT_CKD model

et al. 2016

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The semi‐empirical MT_CKD model of the absorption continuum of water vapor is widely used in atmospheric radiative transfer codes of the atmosphere of Earth and, recently, of exoplanets but lacks of experimental validation in the atmospheric windows. Recent laboratory measurements by Fourier transform Spectroscopy led to self‐continuum cross sections much larger than the MT_CKD values in the near‐infrared transparency windows. We report on accurate measurements by Cavity Ring Down Spectroscopy (CRDS) and Optical Feedback‐Cavity‐Enhanced Absorption Spectroscopy (OF‐CEAS) at selected spectral points of the transparency windows centered around 4.0, 2.1, and 1.25 µm. The temperature dependence of the absorption continuum at 4.38 µm is measured in the 23–39°C range. The self‐continuum water vapor absorption is derived either from the baseline variation of water vapor spectra recorded for a series of pressure values over a small spectral interval or from baseline monitoring at fixed laser frequency during pressure ramps. After subtraction of the local water monomer lines contribution, self‐continuum cross sections, Cs, are determined with an accuracy better than 10% from the pressure squared dependence of the continuum absorption measured up to about 15 Torr. Together with our previous measurements in the 2.1 and 1.6 µm windows, the present results provide a unique set of water vapor cross sections for testing the MT_CKD model in four transparency windows. Although showing some important deviations of the absolute values (up to about a factor 4), our accurate measurements validate the overall frequency dependence of the most recent version (V2.8) of the MT_CKD model.

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Section: Introductionmentioning

confidence: 99%

Accurate laboratory determination of the near‐infrared water vapor self‐continuum: A test of the MT_CKD model

et al. 2016

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“…Another far-wing theory, based on asymptotic semi-classical approach (Nesmelova et al 1986;Bogdanova Ju and Rodimova 2010;Klimeshina et al 2011), shows a much better agreement with experimental data in the 4-lm window at high temperatures (*350 K) than Tipping and Ma (1995). However, at room temperature, this model also strongly underestimates the self-continuum in this window (Klimeshina et al 2011).…”

Section: Post-2000mentioning

confidence: 60%

“…An integral representation of the absorption coefficient of spectral lines, developed earlier by adopting a quantum-mechanical formalism in the works of Anderson (1949) and Tsao and Curnutte (1962), was applied to specifically develop a far-wing approximation within a statistical approach in Fomin and Tvorogov (1973). Tvorogov and Nesmelova (1976) suggested an alternative far-wing model based on the semi-classical asymptotic approach, fully developed later by Nesmelova et al (1986). In general, theoretical far-wing models of the continuum developed in that period were characterised by a number of adjustable parameters fit to experimental data, which, however, did not always guarantee that they would agree with experimental data at different temperatures or wavenumbers.…”

Section: -1980mentioning

confidence: 99%

The Water Vapour Continuum: Brief History and Recent Developments

2012

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“…It is a semi-empirical formulation based on ad hoc (line-profile) parameters adjusted to measured spectra. The latter consist mainly of laboratory (eg [361][362][363][364], see [357]) and field (eg [365]) measurements in spectral regions that have [366,367] the strongest impact on the radiative fluxes in the Earth atmosphere. The 10 µm window has been studied for decades (eg [357,362,[368][369][370]) and a strong constraint of the MT_CKD self continuum (ie pure H 2 O) in this region comes from field measurements (eg [371]).…”

Section: The Mt_ckd Water-vapor Continuummentioning

confidence: 99%

Recent advances in collisional effects on spectra of molecular gases and their practical consequences

Hartmann

Tran

Armante

et al. 2018

Journal of Quantitative Spectroscopy and Radiative Transfer

100

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Airborne and satellite remote sensing of the mid-infrared water vapour continuum

Cited by 19 publications

References 34 publications

Accurate laboratory determination of the near‐infrared water vapor self‐continuum: A test of the MT_CKD model

Accurate laboratory determination of the near‐infrared water vapor self‐continuum: A test of the MT_CKD model

The Water Vapour Continuum: Brief History and Recent Developments

Recent advances in collisional effects on spectra of molecular gases and their practical consequences

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