Magnetic Topology Response to the 2003 Halloween ICME Event at Mars

Xu, Shaosui; Curry, S.; Mitchell, David; Luhmann, J. G.; Lillis, R. J.; Dong, Chuanfei

doi:10.1029/2018ja026118

Cited by 18 publications

(41 citation statements)

References 83 publications

(134 reference statements)

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“…Our analysis of the SWEA electron energy spectra, combined with the SWIA‐based estimates of the upstream SW condition, confirms the scenario proposed recently by Weber et al () that under high SW dynamic pressures, the compression of the Martian magnetosphere leads to a more open magnetic field topology, which allows easier SW access to the ionosphere (see Figures 7–10). Our results, while obtained from a large data set mostly under quiet SW conditions, are also consistent with the reported SW modulation of magnetic connectivity near Mars under extreme SW conditions such as during the passage of an ICME (e.g., Xu et al, , ).…”

Section: Discussionsupporting

confidence: 92%

“…The SW control of electron depletions is presented in Figure in terms of the distribution of depletions with respect to altitude and SW dynamic pressure, including all SWEA measurements made at SZA>120°. The figure reveals a systematic decrease in the probability of observing electron depletions with increasing SW dynamic pressure, which is an expected trend because under high SW dynamic pressures, the compression of the Martian magnetosphere leads to a more open magnetic field topology, which allows easier SW access to the ionosphere (e.g., Ma, Fang, Nagy, et al, ; Xu et al, ; Xu et al, ; Weber et al, ). Our result is also fully compatible with the observed SW control of the MGS‐based downward energetic electron flux (e.g., Lillis & Brain, ) and the MAVEN‐based electron impact ionization frequency (Lillis et al, ), both on the nightside of Mars.…”

Section: Variations Of Electron Depletionsmentioning

confidence: 82%

“…Near strong crustal magnetic anomalies, the preferred formation of closed magnetic loops effectively shields the atmosphere from direct access of SW electrons at all altitudes examined here (e.g., Ma et al, , ). Such a shielding should also be strongly modulated by the upstream SW condition in that under high SW dynamic pressures, the compression of the Martian magnetosphere leads to a more open magnetic field topology, which allows easier SW access to the ionosphere (e.g., Ma, Fang, Nagy, et al, ; Weber et al, ; Xu et al, , ). In weakly magnetized regions, it is likely that SW electrons are able to precipitate into the atmosphere unhindered, but their intensity is substantially reduced at low altitudes due to energy degradation via inelastic collisions with atmospheric neutrals.…”

Section: Discussionmentioning

confidence: 99%

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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: Variations Of Electron Depletionsmentioning

confidence: 82%

Section: Discussionmentioning

confidence: 99%

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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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“…Interpretation of our findings is somewhat limited because MARSIS cannot measure vector components of the magnetic field, nor bulk properties of the topside ionospheric plasma. Nonetheless, it is well known that high solar wind dynamic pressures compress the Martian plasma environment (Crider et al, ; Edberg et al, ; Halekas et al, , ; Ma et al, ; Opgenoorth et al, ), allowing for stronger, and deeper penetrating, draped and open magnetic fields (Crider et al, , ; Fowler et al, ; Jakosky et al, ; Xu et al, , ). In such a scenario, the topside ionosphere can be depleted due to higher ion escape rates, driven by stronger magnetic tension and pressure gradient forces (Cravens et al, ; Halekas et al, ; Wu et al, ), increased pickup ion escape, and enhanced ion outflow.…”

Section: Discussionmentioning

confidence: 99%

The Effects of Solar Wind Dynamic Pressure on the Structure of the Topside Ionosphere of Mars

Girazian

Halekas

Morgan

et al. 2019

Geophysical Research Letters

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We use Mars Atmosphere and Volatile EvolutioN observations of the upstream solar wind, and Mars Express observations of ionospheric electron densities and magnetic fields, to study how the topside ionosphere (>320 km) of Mars is affected by variations in solar wind dynamic pressure. We find that high solar wind dynamic pressures result in the topside ionosphere being depleted of plasma at all solar zenith angles, coincident with increased induced magnetic field strengths. The depletion of topside plasma in response to high solar wind dynamic pressures is observed in both weak and strong crustal magnetic field regions. Taken together, our results suggest that high solar wind dynamic pressures lead to ionospheric compression, increased ion escape, and reduced day‐to‐night plasma transport in the high‐altitude nightside ionosphere.

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“…Because the upstream solar wind conditions drive the interaction with the Martian obstacle, “extreme” space weather events, such as coronal mass ejections (CMEs) and high pressure pulses from solar wind stream interactions, have been observed to drastically alter the Martian magnetosphere and drive substantial enhancements of ionospheric escape to space (Curry et al, ; Edberg et al, ; Futaana et al, ; Jakosky et al, ; Luhmann et al, ; Lundin et al, ; Ma et al, ; Ma et al, ; Opgenoorth et al, ). Recent studies by Xu et al () and Xu, Fang, et al () investigated the response of magnetic topology driven by the arrival of CMEs at Mars in 2003 and 2017, respectively, showing that draped magnetic field lines were observed at much deeper altitudes in the ionosphere compared to the quiet time conditions prior to the arrival of each CME. The authors postulated that extreme space weather events may thus expose a greater portion of the Martian ionosphere to open and draped field lines, contributing to the previously reported enhancements of ionospheric escape rates in the aforementioned studies.…”

Section: Introductionmentioning

confidence: 99%

The Penetration of Draped Magnetic Field Into the Martian Upper Ionosphere and Correlations With Upstream Solar Wind Dynamic Pressure

Fowler

Lee

et al. 2019

JGR Space Physics

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Open and draped magnetic field topologies are important at Mars because they can provide ionospheric particles a path to escape to space. Four years of Mars Atmosphere and Volatile EvolutioN data are analyzed in this study, demonstrating that the altitude at which the ionospheric density drops below 10 2 cm −3 is essentially coincident with the altitude down to which open and draped magnetic field lines are observed in the ionosphere. During times of enhanced solar wind dynamic pressure, a greater fraction of the magnetic topology was observed as open or draped (as opposed to closed) above densities of 10 2 cm −3 . The altitudes at which the ionospheric density fell below 10 2 cm −3 , and the magnetic field topology transitioned from closed to open or draped, also decreased during higher dynamic pressure conditions. Times of enhanced solar wind dynamic pressure thus appear to drive greater penetration of draped magnetic field into the ionosphere, enhancing the rate of reconnection between draped and crustal magnetic fields and producing more open field. Such observations may have implications for the long-term evolution of the Martian ionosphere; the historic solar wind is thought to have been denser and faster than present-day conditions, and "quiet time" conditions may have been equivalent to extreme dynamic pressure events today. Depending on past atmospheric conditions at Mars, draped topology may have routinely penetrated deep into the ionosphere, and quiet time rates of ionospheric escape to space may thus have been much greater for early Mars than today.

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Magnetic Topology Response to the 2003 Halloween ICME Event at Mars

Cited by 18 publications

References 83 publications

Energetic Electron Depletions in the Nightside Martian Upper Atmosphere Revisited

Energetic Electron Depletions in the Nightside Martian Upper Atmosphere Revisited

The Effects of Solar Wind Dynamic Pressure on the Structure of the Topside Ionosphere of Mars

The Penetration of Draped Magnetic Field Into the Martian Upper Ionosphere and Correlations With Upstream Solar Wind Dynamic Pressure

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