The Impact of Crustal Magnetic Fields on the Thermal Structure of the Martian Upper Atmosphere

et al. 2018

ApJL

Self Cite

Combining the Mars Atmosphere and Volatile Evolution measurements of neutral atmospheric density, solar EUV/X-ray flux, and differential photoelectron intensity made during 240 nominal orbits, we calculate the ionization efficiency, defined as the ratio of the secondary (photoelectron impact) ionization rate to the primary (photon impact) ionization rate, in the dayside Martian upper atmosphere under a range of solar illumination conditions. Both the CO 2 and O ionization efficiencies tend to be constant from 160km up to 250km, with respective median values of 0.19±0.03 and 0.27±0.04. These values are useful for fast calculation of the ionization rate in the dayside Martian upper atmosphere, without the need to construct photoelectron transport models. No substantial diurnal and solar cycle variations can be identified, except for a marginal trend of reduced ionization efficiency approaching the terminator. These observations are favorably interpreted by a simple scenario with ionization efficiencies, as a first approximation, determined by a comparison between relevant cross sections. Our analysis further reveals a connection between regions with strong crustal magnetic fields and regions with high ionization efficiencies, which are likely indicative of more efficient vertical transport of photoelectrons near magnetic anomalies.

Section: Discussion and Concluding Remarksmentioning

confidence: 88%

Section: Calculation Of Ionization Efficiencymentioning

confidence: 99%

Ionization Efficiency in the Dayside Martian Upper Atmosphere

et al. 2018

ApJL

Self Cite

“…Here the neutral temperature is obtained from the isothermal fitting to the respective CO 2 densities measured by the NGIMS in the Closed Source Neutral mode (Mahaffy, Benna, Elrod, et al, ). Only the inbound NGIMS data are used to avoid possible contamination by wall adsorption and chemistry (Cui et al, ). The above parameterization of the ion temperature is likely subject to considerable uncertainties, but these uncertainties should not be important for the purpose of the present study due to the dominance of the magnetic pressure gradient force (see below).…”

Section: Force Balance and Implications On Bulk Ion Flowmentioning

confidence: 99%

The Morphology of the Topside Martian Ionosphere: Implications on Bulk Ion Flow

et al. 2019

JGR Planets

Self Cite

Prior to the Mars Atmosphere and Volatile Evolution mission, the only information on the composition of the Martian ionosphere came from the Viking Retarding Potential Analyzer data, revealing the presence of substantial ion outflow on the dayside of Mars. Extensive measurements made by the Mars Atmosphere and Volatile Evolution Neutral Gas and Ion Mass Spectrometer allow us to examine the morphology of the Martian ionosphere not only in unprecedented detail but also on both the dayside and the nightside of the planet. Above 300 km, various ionospheric species present a roughly constant density scale height around 100 km on the dayside and 180 km on the nightside. An evaluation of the ion force balance, appropriate for regions with near‐horizontal magnetic field lines, suggests the presence of supersonic ion outflow predominantly driven by the ambient magnetic pressure, with characteristic dayside and nightside flow velocities of 4 and 20 km/s, respectively, both referred to an altitude of 500 km. The corresponding total ion outflow rates are estimated to be 5 × 1025 s−1 on the dayside and 1 × 1025 s−1 on the nightside. The data also indicate a prominent variation with magnetic field orientation in that the ion distribution over regions with near‐vertical field lines tends to be more extended on the dayside but more concentrated on the nightside, as compared to regions with near‐horizontal field lines. These observations should have important implications on the pattern of ion dynamics in the vicinity of Mars.

“…The spherical nature of the atmosphere is taken into full account (Smith & Smith, ). Only the inbound portion of each orbit is included to avoid contamination by possible reactions on the NGIMS antechamber walls (e.g., Cui et al, ). The photoionization rate profiles obtained for all orbits are then combined to construct the median distribution of the photoionization rate with respect to altitude and SZA for each of the four geophysical conditions.…”

Section: Implications On Plasma Sourcesmentioning

confidence: 99%

Structural Variability of the Nightside Martian Ionosphere Near the Terminator: Implications on Plasma Sources

Cao

et al. 2019

JGR Planets

Self Cite

With the aid of the Neutral Gas and Ion Mass Spectrometer measurements made onboard the Mars Atmosphere and Volatile Evolution, we examine the morphology of the nightside Martian ionosphere near the terminator at 150–250 km in terms of the extension into darkness for a selected set of ion species: O 2+, NO+, HNO+, N 2+/CO+, CO 2+, and HCO+. Our analysis reveals several interesting characteristics, including the presence of dawn‐dusk and north‐south asymmetries and the variability among different species. A full interpretation of the Neutral Gas and Ion Mass Spectrometer observations relies on the combination of impact ionization by precipitating electrons and day‐to‐night plasma transport, as two important sources of plasma in the nightside Martian ionosphere near the terminator. The former partially contributes to the north‐south asymmetry, whereas the latter favorably explains not only the dawn‐dusk asymmetry but also NO+ and HCO+ as two exceptions which are more extended into darkness as compared to the other species on the dusk side. A comparison between the two plasma sources further indicates that the effect of day‐to‐night transport tends to be suppressed over the southern hemisphere. The above results highlight the impacts of crustal magnetic fields on the structural variability of the nightside Martian ionosphere near the terminator, manifest as the shielding of precipitating electrons and the suppression of day‐to‐night transport, both by the presence of strong magnetic anomalies clustering over the southern hemisphere of the planet.