Transport of solar wind plasma onto the lunar nightside surface

Vorburger, Audrey; Würz, Peter; Barabash, S.; Futaana, Yoshifumi; Wieser, Martin; Bhardwaj, Anil; Dhanya, M. B.; Asamura, Kazushi

doi:10.1002/2016gl071094

Cited by 9 publications

(14 citation statements)

References 26 publications

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“…We show that out of these reflected protons from the SPA, a certain fraction of them indeed reaches the nightside, and also, we quantified the flux and energy of such a population. Recent studies have shown that due to the interaction of protons in near wake region with the nightside lunar surface, energetic neutral atoms are produced (Vorburger et al, ), and that the nightside surface charging can be affected due to the emission of secondary electrons (Nishino et al, ). The plasma in the near wake region generate instabilities and significantly affect the electromagnetic environment of Moon (Nishino et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…The indirect transport include the entry of solar wind scattered from dayside lunar surface to the near wake region (Nishino, Fujimoto, et al, ; Wang et al, ) and also the solar wind scattered from Earth's bow shock (Nishino et al, ). Further, new population of protons is found in the near lunar wake whose source(s) is(are) yet to be identified (Dhanya et al, , ; Vorburger et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…The indirect transport include the entry of solar wind scattered from dayside lunar surface to the near wake region Wang et al, 2010) and also the solar wind scattered from Earth's bow shock (Nishino et al, 2017). Further, new population of protons is found in the near lunar wake whose source(s) is(are) yet to be identified (Dhanya et al, 2016(Dhanya et al, , 2017Vorburger et al, 2016). 10.1029/2018GL079330 observational evidence so far for such a process, and also, the energy and flux of such a population in near wake are not known. In the following, we demonstrate the first observational evidence for this process.…”

Section: Introductionmentioning

confidence: 99%

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First Observation of Transport of Solar Wind Protons Scattered From Magnetic Anomalies Into the Near Lunar Wake: Observations by SARA/Chandrayaan‐1

Dhanya

Bhardwaj

Alok

et al. 2018

Geophysical Research Letters

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We report the first observational evidence for the transport of the solar wind protons scattered from the lunar magnetic anomaly (LMA) into the near wake region from SWIM/Sub‐keV Atom Reflecting Analyzer (SARA) aboard Chandrayaan‐1. These protons with high angular spread are observed in the near wake region for specific orientations of interplanetary magnetic field. The typical energy range is 600–1,000 eV, which is either smaller or comparable to that of solar wind. Using our backtracing model, the source region of these protons is found to be the large LMA at South Pole‐Aitken basin on the dayside, suggesting that these are solar wind protons forward scattered from LMA at the South Pole‐Aitken. The flux of these protons is ∼5 × 10−4 of the solar wind proton flux, which is comparable to the proton population in near wake due to other known processes. Such protons can significantly affect the electromagnetic environment in near wake region.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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First Observation of Transport of Solar Wind Protons Scattered From Magnetic Anomalies Into the Near Lunar Wake: Observations by SARA/Chandrayaan‐1

Dhanya

Bhardwaj

Alok

et al. 2018

Geophysical Research Letters

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“…In general, ions in a supersonic flow do not have direct access to the near-Moon wake, though a variety of entry mechanisms are discussed (Nishino et al 2009a(Nishino et al , 2009b, Halekas et al 2014a). Thus, the nightside of the Moon is generally subject to much lower (but not completely zero) incident fluxes of ions and electrons compared with those on the dayside when the Moon, which is located in the solar wind and magnetosheath, as has been observed in energetic neutral atom reflection ratios (Vorburger et al 2016). The situation is more complicated in the terrestrial magnetotail, where both sunward and anti-sunward flows commonly exist (Troshichev et al 1999;Øieroset et al 2002).…”

Section: Lunar Space Environmentmentioning

confidence: 99%

Particles and Photons as Drivers for Particle Release from the Surfaces of the Moon and Mercury

et al. 2022

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The Moon and Mercury are airless bodies, thus they are directly exposed to the ambient plasma (ions and electrons), to photons mostly from the Sun from infrared range all the way to X-rays, and to meteoroid fluxes. Direct exposure to these exogenic sources has important consequences for the formation and evolution of planetary surfaces, including altering their chemical makeup and optical properties, and generating neutral gas exosphere. The formation of a thin atmosphere, more specifically a surface bound exosphere, the relevant physical processes for the particle release, particle loss, and the drivers behind these processes are discussed in this review.

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“…The ions interact with and perturb the ambient solar wind flow (Fatemi et al, 2014;Harada et al, 2014;Halekas et al, 2012Halekas et al, , 2014Halekas et al, , 2017. The ions travel on cycloid trajectories that can bring them thousands of kilometers upstream of the Moon (Futaana et al, 2003;Holmström et al, 2010), or give them access to the lunar wake and the night side surface (Fatemi et al, 2014;Futaana et al, 2010;Nishino et al, 2009;Vorburger et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

ARTEMIS Observations of Solar Wind Proton Scattering off the Lunar Surface

et al. 2018

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We study the scattering of solar wind protons off the lunar surface, using ion observations collected over 6 years by the ARTEMIS satellites at the Moon. We show the average scattered proton energy spectra, directional scattering distributions, and scattering efficiency, for different solar wind incidence angles and impact speeds. We find that the protons have a scattering distribution that is similar to existing empirical models for scattered hydrogen energetic neutral atoms, with a peak in the backward direction (toward the Sun). We provide a revised model for the scattered proton energy spectrum. We evaluate the positive to neutral charge state ratio by comparing the proton spectrum with existing models for scattered hydrogen. The positive to neutral ratio increases with increasing exit speed from the surface but decreases with increasing impact speed. Combined, these counteracting effects result in a scattering efficiency that decreases from ~0.5% at 300 km/s solar wind speed to ~0.3% at 600 km/s solar wind speed.

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Transport of solar wind plasma onto the lunar nightside surface

Cited by 9 publications

References 26 publications

First Observation of Transport of Solar Wind Protons Scattered From Magnetic Anomalies Into the Near Lunar Wake: Observations by SARA/Chandrayaan‐1

First Observation of Transport of Solar Wind Protons Scattered From Magnetic Anomalies Into the Near Lunar Wake: Observations by SARA/Chandrayaan‐1

Particles and Photons as Drivers for Particle Release from the Surfaces of the Moon and Mercury

ARTEMIS Observations of Solar Wind Proton Scattering off the Lunar Surface

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