Retrieval of O&amp;lt;sub&amp;gt;2&amp;lt;/sub&amp;gt;(&amp;lt;sup&amp;gt;1&amp;lt;/sup&amp;gt;Σ) and O&amp;lt;sub&amp;gt;2&amp;lt;/sub&amp;gt;(&amp;lt;sup&amp;gt;1&amp;lt;/sup&amp;gt;Δ) volume emission rates in the mesosphere and lower thermosphere using SCIAMACHY MLT limb scans

Zarboo, Amirmahdi; Bender, Stefan; Burrows, J. P.; Orphal, J.; Sinnhuber, Miriam

doi:10.5194/amt-11-473-2018

Cited by 18 publications

(14 citation statements)

References 52 publications

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“…These VER profile shapes are very similar. The weak dependencies of VER and O 2 ( a 1 Δ g ) number density on the solar zenith angle are consistent with previous studies (Wiensz, ; Zarboo et al, ), because the ozone photolysis is optically thin at the airglow altitudes. The insignificant variations of VER and O 2 ( a 1 Δ g ) also indicate that the gravity waves do not have a strong impact on the overall intensity of O 2 ( a 1 Δ g ) airglow.…”

Section: Resultssupporting

confidence: 92%

“…However, OSIRIS only has two channels in the O 2 a 1 Δ g band and therefore provides little constraint on the spectral shape of airglow. Zarboo et al () retrieved mesosphere/thermosphere (50–150 km) airglow emission spectra using SCIAMACHY limb observations assuming no self‐absorption, whereas O 2 ( a 1 Δ g ) airglow is also present in the stratosphere with significant self‐absorption. As such, we propose a physics‐based method to model high‐resolution airglow emission spectrum using available spectroscopic parameters from the HIgh‐resolution TRANsmission molecular absorption database 2016 (HITRAN2016; Gordon et al, ).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Reevaluating the Use of O₂ a¹Δ_g Band in Spaceborne Remote Sensing of Greenhouse Gases

Sun

Gordon

Sioris

et al. 2018

Geophysical Research Letters

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Although the O2a1Δg band has long been used in ground‐based greenhouse gas remote sensing to constrain the light path, it is challenging for nadir spaceborne sensors due to strong mesosphere/stratosphere airglow. Spectroscopic simulations using upper state populations successfully reconstruct the airglow spectra with excellent agreement with SCanning Imaging Absorption spectroMeter for Atmospheric CHartographY limb observations (residual root‐mean‐square <0.7%). The accurate knowledge of airglow spectrum enables retrieval of O2(a1Δg) number density, volume emission rate, and temperature. For nadir spaceborne observations, the a1Δg airglow will lead to a negative bias of ∼10% to O2 column, if not considered. However, when properly included, the airglow spectral feature can be adequately separated from O2 absorption (mean bias <0.1%) at the spectral resolution of modern spaceborne spectrometers.

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Section: Resultssupporting

confidence: 92%

Section: Introductionmentioning

confidence: 99%

Reevaluating the Use of O₂ a¹Δ_g Band in Spaceborne Remote Sensing of Greenhouse Gases

Sun

Gordon

Sioris

et al. 2018

Geophysical Research Letters

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“…In a recent study to retrieve the volume emission rates of O 2 ( 1 Δ) and O 2 ( 1 Σ) in the mesosphere and lower thermosphere, Zarboo et al (2018) have used a special mode of SCIAMACHY: the MLT limb scan mode, dedicated to the study of the mesosphere and lower thermosphere in the region 50-150 km. This mode was used only twice a month from July 2008 until April 2012.…”

Section: Description Of Sciamachy Investigation Of O 2 ( 1 δ) Emissionmentioning

confidence: 99%

“…are respectively for the foreground segment and the background segment the optical thickness of O 2 absorption from the segment to the observer, along the LOS. 10 Zarboo et al (2018) have also used the SCIAMACHY limb scans in order to retrieve the vertical profile of the O 2 * emissivity. However, their technique is quite different.…”

Section: The Case With Absorption: a Modified Onion-peeling Techniquementioning

confidence: 99%

“…We list below a few commonly used absorption bands and their potential contamination by airglow. Zarboo et al (2018) have retrieved form SCIAMACHY limb observations the VER of the emission by the O 2 20 molecule excited in the 1 Σ state when it decays to the fundamental in the O 2 band A at 0.76 µm (their figure 5).…”

Section: Contamination Of Absorption Measurements By Airglow Emissionsmentioning

confidence: 99%

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The use of O₂ 1.27 µm absorption band revisited for GHG monitoring from space and application to MicroCarb

Bertaux

Hauchecorne

Lefèvre

et al. 2019

Preprint

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Abstract. Monitoring CO2 from space is essential to characterize the spatio/temporal distribution of this major greenhouse gas, and quantify its sources and sinks. The mixing ratio of CO2 to dry air can be derived from the CO2/O2 column ratio. The O2 column is usually derived form its absorption signature on the solar reflected spectra over the O2 A-band (i.e. OCO-2, Tanso/Gosat, Tansat). As a result of atmospheric scattering, the atmospheric path length varies with the aerosols load, their vertical distribution, and their optical properties. The spectral distance between the O2 A-band (0.76 µm) and the CO2 absorption band (1.6 µm) results in significant uncertainties due to the varying spectral properties of the aerosols over the globe. There is another O2 absorption band at 1.27 µm with weaker lines than in the A-band. As the wavelength is much nearer to the CO2 and CH4 bands, there is less uncertainty when using it as a proxy of the atmospheric path length to the CO2 and CH4 bands. This O2 band is used by the TCCON network implemented for the validation of space-based GHG observations. However, this absorption band is contaminated by the spontaneous emission of the excited molecule O2*, which is produced by the photo-dissociation of O3 molecules in the stratosphere and mesosphere. From a satellite looking nadir, this emission has a similar shape as the absorption signal that is used. In the frame of the CNES MicroCarb project, scientific studies have been performed in 2016–2018 to explore the problems associated to this O2* airglow contamination and methods to correct it. A theoretical synthetic spectrum of the emission was derived from a new approach, based on A21 Einstein coefficients information contained in the line-by-line HITRAN 2016 data base. The shape of our synthetic spectrum is fully validated when compared to O2* airglow spectra observed by SCIAMACHY/ENVISAT in limb viewing. We have designed an inversion scheme of SCIAMACHY limb viewing spectra, allowing to determine the vertical distribution of the Volume Emision Rate of the O2* airglow. The VER profiles and corresponding integrated nadir intensities were both compared to a model of the emission based on the chemical-transport model REPROBUS. The airglow intensities depend mostly on the Solar Zenith Angle (both in model and data) and the model underestimate the observed emission by ∼ 15 %. This is fully confirmed with SCIAMACHY nadir viewing measurements over the oceans: in such conditions, we have disentangled and retrieved the nadir O2* emission in spite of the moderate spectral resolving power (∼ 860). It is shown that with the MicroCarb spectral resolution power (25,000) and SNR, the contribution of the O2* emission at 1.27 µm to the observed spectral radiance in nadir viewing may be disentangled from the lower atmosphere/ground absorption signature with a great accuracy. Simulations with 4ARCTIC radiative transfer inversion tool have shown that the CO2 mixing ratio may be retrieved with the accuracy required for quantifying the CO2 natural sources and sinks (pressure level error ≤ 1 hPa, XCO2 accuracy better than 0.4 ppmv) with only the O2 1.27 µm band. As a result of these studies (at an intermediate phase), it was decided to include this band (B4) in the MicroCarb design, while keeping the O2 A band for reference (B1). Our approach is very similar (likely identical), to the approach of Sun et al. (2018) who also analysed the potential of the O2 1.27 µm band and concluded favourably for GHG monitoring from space. We advocate for the inclusion of this O2 band on other GHG monitoring future space missions, such as GOSAT-3 and EU/ESA CO2-M missions, for a better GHG retrieval.

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Dayglow O2 Atm emission observations at equatorial and low latitudes by WINDII

Shepherd,

Shepherd

2023

Journal of Atmospheric and Solar-Terrestrial Physics

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Retrieval of O<sub>2</sub>(<sup>1</sup>Σ) and O<sub>2</sub>(<sup>1</sup>Δ) volume emission rates in the mesosphere and lower thermosphere using SCIAMACHY MLT limb scans

Cited by 18 publications

References 52 publications

Reevaluating the Use of O₂ a¹Δ_g Band in Spaceborne Remote Sensing of Greenhouse Gases

Reevaluating the Use of O₂ a¹Δ_g Band in Spaceborne Remote Sensing of Greenhouse Gases

The use of O₂ 1.27 µm absorption band revisited for GHG monitoring from space and application to MicroCarb

Dayglow O2 Atm emission observations at equatorial and low latitudes by WINDII

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Retrieval of O&lt;sub&gt;2&lt;/sub&gt;(&lt;sup&gt;1&lt;/sup&gt;Σ) and O&lt;sub&gt;2&lt;/sub&gt;(&lt;sup&gt;1&lt;/sup&gt;Δ) volume emission rates in the mesosphere and lower thermosphere using SCIAMACHY MLT limb scans

Cited by 18 publications

References 52 publications

Reevaluating the Use of O2 a1Δg Band in Spaceborne Remote Sensing of Greenhouse Gases

Reevaluating the Use of O2 a1Δg Band in Spaceborne Remote Sensing of Greenhouse Gases

The use of O2 1.27 µm absorption band revisited for GHG monitoring from space and application to MicroCarb

Dayglow O2 Atm emission observations at equatorial and low latitudes by WINDII

Contact Info

Product

Resources

About

Retrieval of O<sub>2</sub>(<sup>1</sup>Σ) and O<sub>2</sub>(<sup>1</sup>Δ) volume emission rates in the mesosphere and lower thermosphere using SCIAMACHY MLT limb scans

Reevaluating the Use of O₂ a¹Δ_g Band in Spaceborne Remote Sensing of Greenhouse Gases

Reevaluating the Use of O₂ a¹Δ_g Band in Spaceborne Remote Sensing of Greenhouse Gases

The use of O₂ 1.27 µm absorption band revisited for GHG monitoring from space and application to MicroCarb