Influence of local ionization on ionospheric densities in Titan's upper atmosphere

Sagnières, Luc; Galand, M.; Cui, Jun; Lavvas, P.; Vigren, Erik; Vuitton, V.; Yelle, R. V.; Wellbrock, A.; Coates, A. J.

doi:10.1002/2014ja020890

Cited by 11 publications

(21 citation statements)

References 66 publications

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“…It follows, similar to the situation addressed in the previous paragraph, that in order for the dayside and nightside comparisons of + N 2 production rates to become similar (i.e., for S day and S night to become similar), the solar EUV fluxes would need to be reduced (which would bring an issue on dayside + CH 4 production rate comparisons) and/or the suprathermal electron fluxes would need to be somewhat enhanced with respect to the CAPS/ELS measurements across the energy bins contributing the greatest to the ionization of N 2 . We note that Richard et al (2015a) found better agreement between dayside + N 2 production rates calculated from their solar energy deposition model and empirical chemical model than did Sagnières et al (2015). This is most likely due to a combination of various factors: the calibration factor for INMS ion number densities (updated factor used by Sagnières et al), different CH 4 and N 2 number densities, the correction factor in the empirical model from the inclusion of minor reactions, and a different solar flux model.…”

Section: Model-observation Comparison Of Electron Number Densities Inmentioning

confidence: 70%

“…Modeled + N 2 production rates on the dayside are higher (by a factor of ∼1.5-2) than derived from an empirical chemical model. On the nightside the situation is reversed, with the modeled production rates being lower than values from the empirical chemical model by a multiplicative factor of ∼0.4-0.7 (Sagnières et al 2015). 3.…”

Section: Summary and Concluding Remarksmentioning

confidence: 93%

“…This is most likely due to a combination of various factors: the calibration factor for INMS ion number densities (updated factor used by Sagnières et al), different CH 4 and N 2 number densities, the correction factor in the empirical model from the inclusion of minor reactions, and a different solar flux model. These differences are discussed in depth in Section 4.6 of Sagnières et al (2015).…”

Section: Model-observation Comparison Of Electron Number Densities Inmentioning

confidence: 99%

“…Likewise P e,night changes linearly with systematic changes across the utilized suprathermal electron spectra (taken from measurements by CAPS/ELS). Sagnières et al (2015) compared + N 2 and + CH 4 production rates derived from their TIMED/SEE-based solar energy deposition model with production rates derived from an empirical chemical model driven by number densities of neutrals and (short-lived) ions measured by the INMS and laboratory-derived rate coefficients for key ion-neutral reactions. Below 1200 km the + N 2 production rates derived from the solar energy deposition model agreed in shape but were a factor of S day ∼ 1.5-2 higher than corresponding output values from the empirical chemical model (on the contrary, a good agreement was found between the model outputs of + CH 4 production rates).…”

Section: Model-observation Comparison Of Electron Number Densities Inmentioning

confidence: 99%

“…The Solar Dynamics Observatory (SDO) was not yet operational during the investigated flybys, but it was for T83 and T86 (Woods et al 2012). Sagnières et al (2015) reported that for the latter flybys, the + N 2 (and + CH 4 ) production rates calculated along the Cassini trajectories were found to differ by less than 10% when using the solar flux from the SDO/EUV Variability Experiment instrument compared with TIMED/SEE. The extrapolation in distance of the solar EUV flux (measured) near Earth to Titan neglects EUV extinction (expected negligible) and does not correct for the phase difference between the objects.…”

Section: Regarding Uncertainties In Measurementsmentioning

confidence: 99%

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Suprathermal Electrons in Titan’s Sunlit Ionosphere: Model–observation Comparisons

Vigren

Galand

Wellbrock

et al. 2016

ApJ

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The dayside ionosphere of the Saturnian satellite Titan is generated mainly from photoionization of N 2 and CH 4 . We compare model-derived suprathermal electron intensities with spectra measured by the Cassini Plasma Spectrometer/Electron Spectrometer (CAPS/ELS) in Titanʼs sunlit ionosphere (altitudes of 970-1250 km) focusing on the T40, T41, T42, and T48 Titan flybys by the Cassini spacecraft. The model accounts only for photoelectrons and associated secondary electrons, with a main input being the impinging solar EUV spectra as measured by the Thermosphere Ionosphere Mesosphere Energy and Dynamics/Solar EUV Experiment and extrapolated to Saturn. Associated electron-impact electron production rates have been derived from ambient number densities of N 2 and CH 4 (measured by the Ion Neutral Mass Spectrometer/Closed Source Neutral mode) and related energy-dependent electron-impact ionization cross sections. When integrating up to electron energies of 60 eV, covering the bulk of the photoelectrons, the model-based values exceed the observationally based values typically by factors of ∼3 ± 1. This finding is possibly related to current difficulties in accurately reproducing the observed electron number densities in Titanʼs dayside ionosphere. We compare the utilized dayside CAPS/ELS spectra with ones measured in Titanʼs nightside ionosphere during the T55-T59 flybys. The investigated nightside locations were associated with higher fluxes of high-energy (>100 eV) electrons than the dayside locations. As expected, for similar neutral number densities, electrons with energies <60 eV give a higher relative contribution to the total electron-impact ionization rates on the dayside (due to the contribution from photoelectrons) than on the nightside.

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Section: Model-observation Comparison Of Electron Number Densities Inmentioning

confidence: 70%

Section: Summary and Concluding Remarksmentioning

confidence: 93%

Section: Model-observation Comparison Of Electron Number Densities Inmentioning

confidence: 99%

Section: Model-observation Comparison Of Electron Number Densities Inmentioning

confidence: 99%

Section: Regarding Uncertainties In Measurementsmentioning

confidence: 99%

See 3 more Smart Citations

Suprathermal Electrons in Titan’s Sunlit Ionosphere: Model–observation Comparisons

Vigren

Galand

Wellbrock

et al. 2016

ApJ

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Solar cycle variations in ion composition in the dayside ionosphere of Titan

et al. 2016

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One Titanian year spans over two complete solar cycles, and the solar irradiance has a significant effect on ionospheric densities. Solar cycle 24 has been one of the quietest cycles on record. In this paper we show data from the Cassini ion and neutral mass spectrometer (INMS) and the radio and plasma wave science Langmuir probe spanning the time period from early 2005, at the declining phase of solar cycle 23, to late 2015 at the declining phase of solar cycle 24. Densities of different ion species measured by the INMS show a consistent enhancement for high solar activity, particularly near the ionospheric peak. The density enhancement is best seen in primary ion species such as CH3+ rather than heavier ion species such as HCNH+. Unlike at Earth, where the ionosphere and atmosphere thermally expand at high solar activity, at Titan the altitude of the ionospheric peak decreases, indicating that the underlying neutral atmosphere was less extensive. Among the major ion species, CH5+ shows the largest decrease in peak altitude, whereas heavy ions such as C3H5+ show very little decrease. We also calculate the ion production rates using a theoretical model and a simple empirical model using INMS data and show that these effectively predict the increased ion production rates at high solar activity.

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Titan's ionosphere: A survey of solar EUV influences

et al. 2017

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Effects of solar EUV on positive ions and heavy negative charge carriers (molecular ions, aerosol, and/or dust) in Titan's ionosphere are studied over the course of almost 12 years, including 78 flybys below 1400 km altitude between TA (October 2004) and T120 (June 2016). The Radio and Plasma Wave Science/Langmuir Probe‐measured ion charge densities (normalized by the solar zenith angle) show statistically significant variations with respect to the solar EUV flux. Dayside charge densities increase by a factor of ≈2 from solar minimum to maximum, while nightside charge densities are found to anticorrelate with the EUV flux and decrease by a factor of ≈3–4. The overall EUV dependence of the ion charge densities suggest inapplicability of the idealized Chapman theory below 1200 km in Titan's ionosphere. Nightside charge densities are also found to vary along Titan's orbit, with higher values in the sunward magnetosphere of Saturn compared to the magnetotail.

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Influence of local ionization on ionospheric densities in Titan's upper atmosphere

Cited by 11 publications

References 66 publications

Suprathermal Electrons in Titan’s Sunlit Ionosphere: Model–observation Comparisons

Suprathermal Electrons in Titan’s Sunlit Ionosphere: Model–observation Comparisons

Solar cycle variations in ion composition in the dayside ionosphere of Titan

Titan's ionosphere: A survey of solar EUV influences

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