Imaging Plasma Density Structures in the Soft X-Rays Generated by Solar Wind Charge Exchange with Neutrals

Sibeck, D. G.; Allen, R. C.; Aryan, Homayon; Bodewits, Dennis; Brandt, P. C.; Branduardi‐Raymont, G.; Brown, G. V.; Carter, Jennifer; Collado‐Vega, Y. M.; Collier, M. R.; Connor, H. K.; Cravens, T. E.; Ezoe, Yuichiro; Fok, M. C. H.; Galeazzi, M.; Gutynska, O.; Holmström, Mats; Hsieh, S. W.; Ishikawa, Kumi; Koutroumpa, Dimitra; Küntz, K. D.; Leutenegger, Maurice A.; Miyoshi, Yoshizumi; Porter, F. S.; Purucker, Michael E.; Read, A. M.; Raeder, J.; Robertson, I. P.; Samsonov, A. A.; Sembay, S.; Snowden, S. L.; Thomas, Nicholas E.; Steiger, R. von; Walsh, Brian M.; Wing, Simon

doi:10.1007/s11214-018-0504-7

Cited by 83 publications

(109 citation statements)

References 553 publications

(597 reference statements)

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“…As the plasma is hot and dense downstream of the Earth's bow shock and the neutral density is larger, the soft X‐ray emissivity becomes stronger in the magnetosheath. This scenario has been confirmed by sporadic observations from astronomical satellites (Carter & Sembay, 2008; Carter et al, 2010, 2011; Fujimoto et al, 2007; Snowden et al, 2009) and investigated by numerical studies based on global magnetohydrodynamic (MHD) simulations (Connor & Carter, 2019; Robertson & Cravens, 2003; Robertson et al, 2006; Sibeck et al, 2018; Sun et al, 2015, 2019; Whittaker et al, 2016).…”

Section: Introductionmentioning

confidence: 67%

Deriving the Magnetopause Position from the Soft X‐Ray Image by Using the Tangent Fitting Approach

et al. 2020

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Imaging is one of the essential techniques to observe astronomical structures. While analyzing the observed images, it is a challenge in many scientific fields to reconstruct the 3-D structures from 2-D image(s). This report discusses this challenge in the context of reconstructing the structure of the Earth's magnetosphere from the X-ray image and presents a new technique. Specifically, it finds the optimum match of tangent directions derived from the X-ray image and the parameterized magnetopause function. We name this approach as the tangent fitting approach (TFA). TFA is further validated based on the magnetohydrodynamic (MHD) simulations of the X-ray images with different viewing geometries. TFA enables the reconstruction of the large-scale magnetopause from a single X-ray image, applicable to time-dependent situations such as cases during magnetic storms. It is also noted that TFA has a potential broader application to remote sensing data, for instance, energetic neutral atom (ENA) observations. Lastly, this new approach is compared with other magnetopause reconstruction approaches. With the advent of soft X-ray imaging enabling global observation of the magnetopause, it is critical to have appropriate techniques to extract information about the boundaries from the observed images, because

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Section: Introductionmentioning

confidence: 67%

Deriving the Magnetopause Position from the Soft X‐Ray Image by Using the Tangent Fitting Approach

et al. 2020

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“…Recently, a novel approach was proposed to remotely detect the large‐scale magnetopause: soft X‐ray imaging (Branduardi‐Raymont et al, , ; Collier et al, ; Sibeck et al, ; Walsh et al, ). The basic mechanism for soft X‐ray emissions in the magnetosheath and cusp regions is the solar wind charge exchange (SWCX) process.…”

Section: Introductionmentioning

confidence: 99%

Soft X‐ray Imaging of the Magnetosheath and Cusps Under Different Solar Wind Conditions: MHD Simulations

et al. 2019

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The soft X-ray emissions from the Earth's magnetosheath and cusp regions are simulated under different solar wind conditions, based on the PPMLR-MHD code. The X-ray images observed by a hypothetical telescope are presented, and the basic responses of the magnetopause and cusp regions are discernable in these images. From certain viewing geometries, the magnetopause position in the equatorial plane, as well as the latitudinal scales and azimuthal extent of cusp can be directly extracted from the X-ray images. With these reconstructed positions, the issues we are able to analyze include but are not limited to the compression of magnetopause and widening of the cusp after an enhancement of solar wind flux, as well as the erosion of the magnetopause and equatorward motion of cusp after the southward turning of the interplanetary magnetic field. Hence, the X-ray imaging is an appropriate technique to study the large-scale motion of magnetopause and cusps in response to solar wind variations.Recently, a novel approach was proposed to remotely detect the large-scale magnetopause: soft X-ray imaging (Branduardi-Raymont et al., 2012Collier et al., 2012;Sibeck et al., 2018;Walsh et al., 2016). The basic mechanism for soft X-ray emissions in the magnetosheath and cusp regions is the solar wind charge exchange (SWCX) process. On the one hand, heavy ions in high charge states, such as O 7+ , exist in the ambient solar wind. On the other hand, neutral atoms and molecules, such as the hydrogen, are ubiquitous in the geospace environment due to the Earth's exosphere. When they encounter and interact with each other, an electron can be transferred from the neutral to the ion. As a result of capturing the electron, the solar wind ion is in an electronically excited state, and then emits one or more photons in the extreme ultraviolet or soft X-ray bands while decaying to the lower-energy state. In the magnetosheath, the density of the highly charged ions is enhanced as the solar wind slows down after the bow shock. The solar wind cannot directly penetrate the magnetopause, and thus, the plasma with solar wind origin is quite tenuous inside the magnetosphere. This leads to a sharp boundary at the magnetopause in terms of the soft X-ray emissivity. The cusps are special regions on the magnetopause. The solar wind plasma can enter directly, and thus, the X-ray emissivity is expected to be higher inside of the cusps. With different solar wind fluxes and/or interplanetary magnetic fields (IMF), the X-ray emissivity in the magnetosheath and cusps can be

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“…X‐ray imaging of the solar wind charge exchange (SWCX) processes in Earth's magnetosheath and nearby solar wind can provide a wealth of information about the dynamic processes which take place in those regions. Sibeck et al () provide a very thorough and extensive review of developments in the field of X‐ray imaging and related fields. SWCX was originally proposed by Cravens () as an explanation for X‐ray emissions from comet Hyakutake reported by Lisse et al ().…”

Section: Introductionmentioning

confidence: 99%

Boundary Detection in Three Dimensions With Application to the SMILE Mission: The Effect of Model‐Fitting Noise

et al. 2019

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The magnetosheath and near-Earth solar wind emit X-rays due to charge-exchange between the extended atmosphere and highly ionized particles in the solar wind. These emissions can be used to remotely sense the dynamic processes in this region. The Solar Wind Magnetosphere Ionosphere Link Explorer mission will carry out these measurements. In a previous paper, we looked at the effect of photon counting statistics on determining the location of the magnetopause and bow shock. In this paper we explore, through simulations, the more challenging question of orbital viewing geometry bias when the model and the emissions do not match each other exactly. Our simulations conclude that while care must be taken to avoid false minima in the fitting, there is very little to no orbital bias in extracting the position and large-scale shape of the magnetopause and bow shocks from 2-D X-ray images from the future Solar Wind Magnetosphere Ionosphere Link Explorer mission.

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Imaging Plasma Density Structures in the Soft X-Rays Generated by Solar Wind Charge Exchange with Neutrals

Cited by 83 publications

References 553 publications

Deriving the Magnetopause Position from the Soft X‐Ray Image by Using the Tangent Fitting Approach

Deriving the Magnetopause Position from the Soft X‐Ray Image by Using the Tangent Fitting Approach

Soft X‐ray Imaging of the Magnetosheath and Cusps Under Different Solar Wind Conditions: MHD Simulations

Boundary Detection in Three Dimensions With Application to the SMILE Mission: The Effect of Model‐Fitting Noise

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