Three‐dimensional Hall MHD simulation of lunar minimagnetosphere: General characteristics and comparison with Chang'E‐2 observations

Xie, Luhua; Li, Lei; Zhang, Yiteng; Feng, Yutong; Wang, Xin‐Yue; Zhang, Aibing; Kong, Lingxue

doi:10.1002/2015ja021647

Cited by 21 publications

(18 citation statements)

References 33 publications

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“…Such a multi-dipole effect was also found in the recent Hall MHD simulations done by Xie et al (2015), in which the lunar crustal field was modeled by five dipoles with a surface strength of 480 nT and a mini-magnetosphere could form even near the subsolar region. Furthermore, Xie et al (2015) found that the formation of LMM favors higher SZA and smaller ion inertia length, and the simulation results are consistent with the observations by both LP and Chang'E-2. Additionally, the reflected solar wind ions can help to slow down and compress the solar wind flow, and also play a role in the formation of LMM (Fatemi et al, 2014;Halekas et al, 2014).…”

supporting

confidence: 71%

“…However, later studies showed that the non-dipolar nature of the lunar crustal fields makes them have a larger lateral extent than a dipole, which could enhance the efficiency to stand off the solar wind and reduce the field strength needed to form a mini-magnetosphere (Harnett & Winglee, 2003). Such a multi-dipole effect was also found in the recent Hall MHD simulations done by Xie et al (2015), in which the lunar crustal field was modeled by five dipoles with a surface strength of 480 nT and a mini-magnetosphere could form even near the subsolar region. Furthermore, Xie et al (2015) found that the formation of LMM favors higher SZA and smaller ion inertia length, and the simulation results are consistent with the observations by both LP and Chang'E-2.…”

mentioning

confidence: 78%

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Inside a Lunar Mini‐Magnetosphere: First Energetic Neutral Atom Measurements on the Lunar Surface

Xie

Zhang

et al. 2021

Geophysical Research Letters

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Without a global magnetic field or a significant atmosphere, the Moon was previously thought to have a simple interaction with the solar wind, in which the impinging solar wind ions could be completely absorbed by the lunar surface on the dayside, leaving a lunar wake on the nightside (Colburn et al., 1971;Ness et al., 1968). However, later observations showed that the Moon possesses a large number of local magnetic anomalies, which were first observed by the Apollo missions (

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confidence: 71%

mentioning

confidence: 78%

Inside a Lunar Mini‐Magnetosphere: First Energetic Neutral Atom Measurements on the Lunar Surface

Xie

Zhang

et al. 2021

Geophysical Research Letters

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“…In addition, some current peaks may be associated with local magnetic anomalies. Lunar magnetic anomalies are thought to be able to prevent the incoming solar wind and reduce the solar wind flux on the lunar surface (Deca et al, 2016; Xie et al, 2015). As a result, they can change the flux of backscattered solar wind and lead to a disturbance in the LDEX current, as discussed by (Walker et al, 2017).…”

Section: Dust Fountain Observed By Ladeementioning

confidence: 99%

Lunar Dust Fountain Observed Near Twilight Craters

Xie

Zhang

et al. 2020

Geophysical Research Letters

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Lunar horizon glows observed by the Apollo missions suggested a dense dust exosphere near the lunar terminator. But later missions failed to see such a high-density dust exosphere. Why the Apollo missions could observe so large number of dust grains remains a mystery. For the first time, we report five dust enhancement events observed by the Lunar Dust Experiment on board Lunar Atmosphere and Dust Environment Explorer mission, which happen near a twilight crater with dust densities comparable to the Apollo measurements. Moreover, the dust densities are larger on the downstream side of the crater and favor a higher solar wind temperature, consistent with an electrostatic dust lofting from the negatively charged crater floor. We also check the Apollo observations and find similar twilight craters, suggesting that the so-called dust exosphere is not a global phenomenon but just a local electrified dust fountain near twilight craters. Plain Language Summary With in situ dust measurements, we find that a shadowed crater near the terminator can dramatically change the surface electrical environment and bring a dense dust cloud surrounding the crater, which should be carefully assessed by engineers for future lunar explorations. Moreover, our findings have the general implications in studying the dust environment near large topographic features (mountains and deep craters) of all kinds of airless bodies. On the other hand, the electrostatic mechanism has been improved in recent years. Stubbs et al. (2006) proposed a dynamic fountain model, in which the like-charged dust grains with radii of 0.01-0.1 μm could be RESEARCH LETTER

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“…Numerous investigations have explored the potential mechanisms at work within crustal magnetic anomalies with laboratory experiments [ Wang et al , , ] and numerical simulations, including magnetohydrodynamic (MHD) [e.g., Harnett and Winglee , , ; Xie et al , ], hybrid [ Fatemi et al , , ; Jarvinen et al , ; Giacalone and Hood , ; Poppe et al , ], and kinetic/particle‐in‐cell methodologies [e.g., Poppe et al , ; Deca et al , , ; Zimmerman et al , ; Bamford et al , ]. These simulations have suggested that large‐scale ambipolar and/or Hall electrostatic fields may be the primary mechanism of proton reflection from lunar crustal magnetic fields, rather than magnetic reflection.…”

Section: Introductionmentioning

confidence: 99%

ARTEMIS observations of the solar wind proton scattering function from lunar crustal magnetic anomalies

et al. 2017

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Despite their small scales, lunar crustal magnetic fields are routinely associated with observations of reflected and/or backstreaming populations of solar wind protons. Solar wind proton reflection locally reduces the rate of space weathering of the lunar regolith, depresses local sputtering rates of neutrals into the lunar exosphere, and can trigger electromagnetic waves and small‐scale collisionless shocks in the near‐lunar space plasma environment. Thus, knowledge of both the magnitude and scattering function of solar wind protons from magnetic anomalies is crucial in understanding a wide variety of planetary phenomena at the Moon. We have compiled 5.5 years of ARTEMIS (Acceleration, Reconnection, Turbulence and Electrodynamics of the Moon's Interaction with the Sun) observations of reflected protons at the Moon and used a Liouville tracing method to ascertain each proton's reflection location and scattering angles. We find that solar wind proton reflection is largely correlated with crustal magnetic field strength, with anomalies such as South Pole/Aitken Basin (SPA), Mare Marginis, and Gerasimovich reflecting on average 5–12% of the solar wind flux while the unmagnetized surface reflects between 0.1 and 1% in charged form. We present the scattering function of solar wind protons off of the SPA anomaly, showing that the scattering transitions from isotropic at low solar zenith angles to strongly forward scattering at solar zenith angles near 90°. Such scattering is consistent with simulations that have suggested electrostatic fields as the primary mechanism for solar wind proton reflection from crustal magnetic anomalies.

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Three‐dimensional Hall MHD simulation of lunar minimagnetosphere: General characteristics and comparison with Chang'E‐2 observations

Cited by 21 publications

References 33 publications

Inside a Lunar Mini‐Magnetosphere: First Energetic Neutral Atom Measurements on the Lunar Surface

Inside a Lunar Mini‐Magnetosphere: First Energetic Neutral Atom Measurements on the Lunar Surface

Lunar Dust Fountain Observed Near Twilight Craters

ARTEMIS observations of the solar wind proton scattering function from lunar crustal magnetic anomalies

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