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

Cao, Y.; Cui, Jun; Wu, Xiaoshu; Guo, Jin; Wei, Yong

doi:10.1029/2019je005970

Cited by 19 publications

(38 citation statements)

References 81 publications

(164 reference statements)

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“…Such a feature is not only seen well beyond the EUV terminator but also seen in regions where day‐to‐night plasma transport is likely more important than SW electron precipitation as a source for maintaining the nightside ionosphere (e.g., Cui et al, ; Girazian et al, ; Withers et al, ). These observations agree with earlier studies that closed magnetic loops forming near strong crustal anomalies act to hinder both SW electron precipitation and day‐to‐night plasma transport (e.g., Adams et al, ; Cao et al, ). However, NO + behaves as an exception with comparable abundances between regions with and without depletions, likely due to the replenishment of this species on the nightside by ion‐neutral chemistry (Girazian et al, ).…”

Section: Discussionsupporting

confidence: 92%

“…Despite this, the ion density differences between regions with and without depletions are still prominent, which could be interpreted by the fact that the closed magnetic loops with both footprints on the nightside should not only hinder the precipitation of SW electrons but also hinder the horizontal transport of ionospheric plasma from the dayside. This is consistent with the recent study of Cao et al () revealing that day‐to‐night transport in the Martian ionosphere tends to be suppressed in the presence of strong crustal magnetic fields.…”

Section: The Characteristics Of the Ambient Ionospheresupporting

confidence: 93%

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Energetic Electron Depletions in the Nightside Martian Upper Atmosphere Revisited

Niu

Cui

et al. 2020

JGR Space Physics

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Energetic electron depletions are a notable feature of the nightside Martian upper atmosphere. In this study, we investigate systematically the variations of the occurrence of depletions with both internal and external conditions, using the extensive Solar Wind Electron Analyzer measurements made on board the Mars Atmosphere and Volatile Evolution. In addition to the known trends of increasing occurrence with decreasing altitude and increasing magnetic field intensity, our analysis reveals that depletions are more easily observed in regions with near horizontal magnetic fields and under low solar wind (SW) dynamic pressures. We also find that below 160 km, the occurrence increases with increasing CO 2 density, a trend mostly visible in weakly magnetized regions. These observations have important implications on the formation of electron depletions: (1) Near strong magnetic anomalies, closed magnetic loops preferentially form and shield the atmosphere from direct access of SW electrons, a process that is modulated by the upstream SW condition; and (2) in weakly magnetized regions, SW electrons precipitate into the atmosphere unhindered, but at sufficiently low altitudes, they are either "absorbed" due to inelastic collisions with ambient neutrals or shielded again in response to a change in magnetic connectivity from open to closed. Our analysis further reveals that both the ionospheric plasma content and thermal electron temperature are reduced in regions with depletions compared to regions without, supporting SW electron precipitation as an important source of external energy driving the variability in the deep nightside Martian upper atmosphere and ionosphere. the Solar Wind Electron Analyzer (SWEA) on board the recent Mars Atmosphere and Volatile Evolution (MAVEN) spacecraft (Jakosky et al., 2015). Steckiewicz et al. (2017) performed a comprehensive analysis of nightside energetic electron precipitation near Mars combining the measurements made by the Mars Global Surveyor (MGS), the Mars Express (MEx), and MAVEN, identifying more than 134,500 depletions between 125 and 900 km in altitude. The fractional

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Section: Discussionsupporting

confidence: 92%

Section: The Characteristics Of the Ambient Ionospheresupporting

confidence: 93%

Energetic Electron Depletions in the Nightside Martian Upper Atmosphere Revisited

Niu

Cui

et al. 2020

JGR Space Physics

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“…Nevertheless, there are other processes that dominate at higher altitudes (typically above ∼200 km) for all SZAs, such as vertical transport (e.g., Chen et al 1978;Mendillo et al 2011;Kar et al 1996;Fox 1997Fox , 2009Cravens et al 2017;Wu et al 2019, ), which are not investigated in this study because their contribution to the TEC is smaller. In addition, at high SZAs and far from crustal field regions, dayto-night plasma transport plays an important role in shaping the Martian ionosphere near and beyond the terminator (e.g., Nĕmec et al 2010;Withers et al 2012;Cui et al 2015;Girazian et al 2017;Cao et al 2019).…”

Section: Martian Tecmentioning

confidence: 99%

“…Plasma transport into the nightside is not investigated in this study, although it should be noted that the low TEC values beyond 90 • SZA should be affected by this process (e.g., Cui et al 2015;Cao et al 2019). The Huber fits to Martian TEC as a function of SZA in the four SZA regions are shown in Fig.…”

Section: Martian Tecmentioning

confidence: 99%

“…At Earth, O + remains the most abundant ion in the F-region, with O + 2 , N + 2 , and NO + playing important roles in the E-region (Schunk and Nagy 2009). The Martian nightside ionosphere near the terminator is maintained thanks to dayto-night plasma transport (e.g., Chen et al 1978;Cui et al 2015) together with impact ionisation by precipitating electrons (e.g., Cao et al 2019), where densities of the major ions decrease with the solar zenith angle (SZA) across the terminator (e.g., Girazian et al 2017;Withers et al 2012). Far from the terminator, electron precipitation is the dominant source of ionisation, which is more important over regions of strong crustal magnetic fields (as will be described in the Section "Planetary environments") (e.g., Nĕmec et al 2010;Lillis et al 2018), and during solar storms (e.g., Sánchez-Cano et al 2019).…”

Section: Introductionmentioning

confidence: 99%

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Comparison of terrestrial and Martian TEC at dawn and dusk during solstices

Burrell

Sánchez–Cano

Witasse

et al. 2020

Earth Planets Space

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This paper used the similarities between the ionospheres on Mars and Earth, the most similar of the terrestrial planets, to examine the relative importance of photochemical and transport processes at dawn and dusk. The amount of plasma present in the ionosphere, as measured by the total electron content (TEC), was examined at different locations for both solstice seasons over a solar cycle. Using the rate of change of TEC as a function of solar zenith angle made it possible to compare the plasma production via photoionisation and loss via recombination in the main layer of each planetary ionosphere despite the extreme differences in the total quantity of plasma. This study finds that, at least to first order, the dawn and dusk TEC slopes at Mars are symmetric. This symmetry is interpreted as an indicator of photochemical equilibrium. Deviations from photochemical equilibrium in different geographic and aerographic regions were used to explore the underlying processes responsible for plasma transport. Seasonal and solar cycle variations were also examined at dusk. These variations found that differing interactions with solar forcing mechanisms resulted in a Martian ionosphere with regions that showed evidence of significant transport processes at solar maximum, while at Earth transport processes were most important at solar minimum. In general, the photochemical processes in both ionospheres behave similarly when no magnetic field is considered. The presence or absence of a magnetic field shape the production via photoionisation and loss via recombination processes in both ionospheres, especially when considering plasma transport. This study has notable implications for comparative aeronomy, as a good understanding of how the ionosphere of magnetised and un-magnetised bodies compares is important for characterising planetary environments and atmospheric evolution over long time scales.

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Mars’ plasma system. Scientific potential of coordinated multipoint missions: “The next generation”

et al. 2021

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The objective of this White Paper, submitted to ESA’s Voyage 2050 call, is to get a more holistic knowledge of the dynamics of the Martian plasma system, from its surface up to the undisturbed solar wind outside of the induced magnetosphere. This can only be achieved with coordinated multi-point observations with high temporal resolution as they have the scientific potential to track the whole dynamics of the system (from small to large scales), and they constitute the next generation of the exploration of Mars analogous to what happened at Earth a few decades ago. This White Paper discusses the key science questions that are still open at Mars and how they could be addressed with coordinated multipoint missions. The main science questions are: (i) How does solar wind driving impact the dynamics of the magnetosphere and ionosphere? (ii) What is the structure and nature of the tail of Mars’ magnetosphere at all scales? (iii) How does the lower atmosphere couple to the upper atmosphere? (iv) Why should we have a permanent in-situ Space Weather monitor at Mars? Each science question is devoted to a specific plasma region, and includes several specific scientific objectives to study in the coming decades. In addition, two mission concepts are also proposed based on coordinated multi-point science from a constellation of orbiting and ground-based platforms, which focus on understanding and solving the current science gaps.

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

Cited by 19 publications

References 81 publications

Energetic Electron Depletions in the Nightside Martian Upper Atmosphere Revisited

Energetic Electron Depletions in the Nightside Martian Upper Atmosphere Revisited

Comparison of terrestrial and Martian TEC at dawn and dusk during solstices

Mars’ plasma system. Scientific potential of coordinated multipoint missions: “The next generation”

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