Modelling the Venusian airglow

Gronoff, Guillaume; Lilensten, Jean; Simon, Cyril; Barthélemy, Mathieu; Leblanc, François; Dutuit, O.

doi:10.1051/0004-6361:20077503

Cited by 55 publications

(74 citation statements)

References 81 publications

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“…We use the TRANS-* family of codes adapted to Earth , Venus (Gronoff et al, , 2008, Mars (Simon et al, 2009), Titan (Lilensten et al, 2005;) and Jupiter (Ménager et al, 2010) as discussed below. The TRANS-* codes solve the 1-D kinetic transport Boltzmann equation for suprathermal electrons including updated elastic, ionisation, excitation and dissociative cross sections.…”

Section: Motivationmentioning

confidence: 99%

Comprehensive calculation of the energy per ion pair or <I>W</I> values for five major planetary upper atmospheres

et al. 2011

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Abstract. The mean energy W expended in a collision of electrons with atmospheric gases is a useful parameter for fast aeronomy computations. Computing this parameter in transport kinetic models with experimental values can tell us more about the number of processes that have to be taken into account and the uncertainties of the models. We present here computations for several atmospheric gases of planetological interest (CO 2 , CO, N 2 , O 2 , O, CH 4 , H, He) using a family of multi-stream kinetic transport codes. Results for complete atmospheres for Venus, Earth, Mars, Jupiter and Titan are also shown for the first time. A simple method is derived to calculate W of gas mixtures from single-component gases and is conclusively checked against the W values of these planetary atmospheres. Discrepancies between experimental and theoretical values show where improvements can be made in the measurement of excitation and dissociation cross-sections of specific neutral species, such as CO 2 and CO.

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Section: Motivationmentioning

confidence: 99%

Comprehensive calculation of the energy per ion pair or <I>W</I> values for five major planetary upper atmospheres

et al. 2011

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“…We use their profile assuming an upper boundary temperature of 200 K at 100 km. The tropospheric temperature profile is extrapolated from the tropopause (220 K at 61 km) down to the surface assuming a constant temperature lapse rate of +8.5 K km −1 , yielding a surface temperature of 740 K. Above 100 km, the temperature profile corresponds to the neutral component of the ionosphere and follow those used by Gronoff et al (2008), initially calculated by Hedin et al (1983). The pressure profile p(z) is calculated across the whole altitude range (0-400 km) assuming the atmosphere behaves as a perfect gas at hydrostatic equilibrium, p(z) = p 0 exp − dz/H(z) , where p 0 = 93 bar is the surface pressure and…”

Section: Atmospherementioning

confidence: 99%

“…Above this altitude, X CO 2 follows the model of Gronoff et al (2008). In addition to CO 2 , we are considering molecular nitrogen (X N 2 = 3.5%), molecular and atomic oxygen (O 2 and O i), carbon monoxide (CO), water (H 2 O), and sulfur dioxide (SO 2 ).…”

Section: Atmospherementioning

confidence: 99%

“…The mixing ratio profiles for CO, SO 2 , and H 2 O are extrapolated from the values from Cotton et al (2011), de Bergh et al (2006, respectively. Mixing ratios of O 2 and O i are considered to be nonzero only in the upper atmosphere, where these species are produced; there, their mixing ratio profiles follow those calculated by Gronoff et al (2008). We finally include mesospheric ozone (O 3 ) following its recent detection by Montmessin et al (2011).…”

Section: Atmospherementioning

confidence: 99%

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Transmission spectrum of Venus as a transiting exoplanet

Ehrenreich

Vidal‐Madjar

Widemann

et al. 2011

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On 5-6 June 2012, Venus will be transiting the Sun for the last time before 2117. This event is an unique opportunity to assess the feasibility of the atmospheric characterisation of Earth-size exoplanets near the habitable zone with the transmission spectroscopy technique and provide an invaluable proxy for the atmosphere of such a planet. In this letter, we provide a theoretical transmission spectrum of the atmosphere of Venus that could be tested with spectroscopic observations during the 2012 transit. This is done using radiative transfer across Venus' atmosphere, with inputs from in-situ missions such as Venus Express and theoretical models. The transmission spectrum covers a range of 0.1-5 μm and probes the limb between 70 and 150 km in altitude. It is dominated in UV by carbon dioxide absorption producing a broad transit signal of ∼20 ppm as seen from Earth, and from 0.2 to 2.7 μm by Mie extinction (∼5 ppm at 0.8 μm) caused by droplets of sulfuric acid composing an upper haze layer above the main deck of clouds. These features are not expected for a terrestrial exoplanet and could help discriminating an Earth-like habitable world from a cytherean planet.

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“…These diagnostics can be made through models such as the TRANS* family models, developed to study planetary ionospheres such as Earth (Lilensten & Blelly 2002), Mars (Witasse et al 2002(Witasse et al , 2003Simon et al 2009), Venus (Gronoff et al 2008), Titan (Lilensten et al 2005a(Lilensten et al , 2005bGronoff et al 2009aGronoff et al , 2009b, and Jupiter (Menager et al 2010). The TRANS* family models are 1D kinetic models which solve the Boltzmann equation for the suprathermal electrons along a vertical (or a magnetic field line) in the atmosphere.…”

Section: Introduction and Motivationsmentioning

confidence: 99%

Sensitivity of upper atmospheric emissions calculations to solar/stellar UV flux

Barthélemy

Cessateur

2014

J. Space Weather Space Clim.

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The solar UV (UltraViolet) flux, especially the EUV (Extreme UltraViolet) and FUV (Far UltraViolet) components, is one of the main energetic inputs for planetary upper atmospheres. It drives various processes such as ionization, or dissociation which give rise to upper atmospheric emissions, especially in the UV and visible. These emissions are one of the main ways to investigate the upper atmospheres of planets. However, the uncertainties in the flux measurement or modeling can lead to biased estimates of fundamental atmospheric parameters, such as concentrations or temperatures in the atmospheres. We explore the various problems that can be identified regarding the uncertainties in solar/stellar UV flux by considering three examples. The worst case appears when the solar reflection component is dominant in the recorded spectrum as is seen for outer solar system measurements from HST (Hubble Space Telescope). We also show that the estimation of some particular line parameters (intensity and shape), especially Lyman a, is crucial, and that both total intensity and line profile are useful. In the case of exoplanets, the problem is quite critical since the UV flux of their parent stars is often very poorly known.

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Modelling the Venusian airglow

Cited by 55 publications

References 81 publications

Comprehensive calculation of the energy per ion pair or <I>W</I> values for five major planetary upper atmospheres

Comprehensive calculation of the energy per ion pair or <I>W</I> values for five major planetary upper atmospheres

Transmission spectrum of Venus as a transiting exoplanet

Sensitivity of upper atmospheric emissions calculations to solar/stellar UV flux

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Modelling the Venusian airglow

Cited by 55 publications

References 81 publications

Comprehensive calculation of the energy per ion pair or &lt;I&gt;W&lt;/I&gt; values for five major planetary upper atmospheres

Comprehensive calculation of the energy per ion pair or &lt;I&gt;W&lt;/I&gt; values for five major planetary upper atmospheres

Transmission spectrum of Venus as a transiting exoplanet

Sensitivity of upper atmospheric emissions calculations to solar/stellar UV flux

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Product

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Comprehensive calculation of the energy per ion pair or <I>W</I> values for five major planetary upper atmospheres

Comprehensive calculation of the energy per ion pair or <I>W</I> values for five major planetary upper atmospheres