The Solar Probe Plus Mission: Humanity’s First Visit to Our Star

Fox, N. J.; Velli, M.; Bale, S. D.; Decker, R. B.; Driesman, Andrew; Howard, R. A.; Kasper, J. C.; Kinnison, James D.; Kusterer, M. B.; Lario, D.; Lockwood, Mary Kae; McComas, D. J.; Raouafi, N. E.; Szabó, Á.

doi:10.1007/s11214-015-0211-6

Cited by 999 publications

(733 citation statements)

References 126 publications

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“…The method holds promise for improving the extraction of quantitative information from shocks in the corona using remote sensing observations. It can readily use observations from different vantage points, including from the imagers (Howard et al, 2013;Vourlidas et al, 2016) aboard the upcoming Solar Orbiter (Müeller et al, 2013) and Solar Probe Plus (Fox et al, 2016) missions to be compared with direct in situ measurements from these missions. The technique will also greatly improve the results from any future joint coronagraphic imaging and off-limb spectroscopy of shocks (Bemporad and Mancuso, 2011;Vourlidas and Bemporad, 2012).…”

Section: Discussionmentioning

confidence: 99%

The density compression ratio of shock fronts associated with coronal mass ejections

Kwon

Vourlidas

2018

J. Space Weather Space Clim.

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-We present a new method to extract the three-dimensional electron density profile and density compression ratio of shock fronts associated with coronal mass ejections (CMEs) observed in white light coronagraph images. We demonstrate the method with two examples of fast halo CMEs (∼2000 km s À1 ) observed on 2011 March 7 and 2014 February 25. Our method uses the ellipsoid model to derive the threedimensional geometry and kinematics of the fronts. The density profiles of the sheaths are modeled with double-Gaussian functions with four free parameters, and the electrons are distributed within thin shells behind the front. The modeled densities are integrated along the lines of sight to be compared with the observed brightness in COR2-A, and a x 2 approach is used to obtain the optimal parameters for the Gaussian profiles. The upstream densities are obtained from both the inversion of the brightness in a pre-event image and an empirical model. Then the density ratio and Alfvénic Mach number are derived. We find that the density compression peaks around the CME nose, and decreases at larger position angles. The behavior is consistent with a driven shock at the nose and a freely propagating shock wave at the CME flanks. Interestingly, we find that the supercritical region extends over a large area of the shock and lasts longer (several tens of minutes) than past reports. It follows that CME shocks are capable of accelerating energetic particles in the corona over extended spatial and temporal scales and are likely responsible for the wide longitudinal distribution of these particles in the inner heliosphere. Our results also demonstrate the power of multi-viewpoint coronagraphic observations and forward modeling in remotely deriving key shock properties in an otherwise inaccessible regime.

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Section: Discussionmentioning

confidence: 99%

The density compression ratio of shock fronts associated with coronal mass ejections

Kwon

Vourlidas

2018

J. Space Weather Space Clim.

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“…Alfvénic turbulence is thought to be captured by the incompressible magnetohydrodynamics (MHD) equations, which in fluctuating Elsasser (1950) form (omitting forcing and dissipation terms) are ∂δz ± ∂t ∓ v A ∇ δz ± + δz ∓ · ∇δz ± = −∇P, (2.1)…”

Section: Phenomenological Models Of Alfvénic Turbulencementioning

confidence: 99%

“…The following year (2018) is due to see the launch of Solar Probe Plus (Fox et al 2015) and Solar Orbiter (Müller et al 2013), which will both travel closer to the Sun than any previous spacecraft, and for which turbulence, along with the associated heating, is one of the main science goals. In particular, Solar Probe Plus will travel to within 9 Solar radii of the solar surface, and will have a comprehensive payload measuring the electromagnetic fields and particles to explore turbulence and heating within the corona for the first time.…”

Section: Future Missionsmentioning

confidence: 99%

Recent progress in astrophysical plasma turbulence from solar wind observations

2016

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This paper summarises some of the recent progress that has been made in understanding astrophysical plasma turbulence in the solar wind, from in situ spacecraft observations. At large scales, where the turbulence is predominantly Alfvénic, measurements of critical balance, residual energy and three-dimensional structure are discussed, along with comparison to recent models of strong Alfvénic turbulence. At these scales, a few per cent of the energy is also in compressive fluctuations, and their nature, anisotropy and relation to the Alfvénic component is described. In the small-scale kinetic range, below the ion gyroscale, the turbulence becomes predominantly kinetic Alfvén in nature, and measurements of the spectra, anisotropy and intermittency of this turbulence are discussed with respect to recent cascade models. One of the major remaining questions is how the turbulent energy is dissipated, and some recent work on this question, in addition to future space missions which will help to answer it, are briefly discussed.

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“…While many of the current spacecraft missions perform multi-point measurements -four-point tetrahedral formation flights on scales of 10 000 down to 100 km by the Cluster mission (Escoubet et al, 2001) and on a 10 km scale by the MMS mission (Burch et al, 2016), 1-D fivepoint measurements by the THEMIS mission (Angelopoulos, 2008), three-point measurements by the Swarm mission Olsen et al, 2013;Thebault et al, 2013), and two-point measurements by the Van Allen Probes (Mauk et al, 2013;Stratton et al, 2013) -the upcoming spacecraft missions are more specialized to unique observational approaches toward the understanding of turbulence processes (particularly in interplanetary space) at the cost of returning back to single spacecraft measurements. Examples are simultaneous remote sensing and in situ measurements by Solar Orbiter (Müller et al, 2013), the closest observations to the Sun by Solar Probe Plus (Fox et al, 2016), and highprecision sampling of particle velocity distribution functions, electric fields, and magnetic fields by THOR (Vaivads et al, 2016). Analysis of spatial structure or intermittency is not covered here, and will be presented in separate papers.…”

Section: Turbulent Space Plasmamentioning

confidence: 99%

Review article: Wave analysis methods for space plasma experiment

Narita

2017

Nonlin. Processes Geophys.

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Abstract. A review of analysis methods is given on quasimonochromatic waves, turbulent fluctuations, and wavewave and wave-particle interactions for single-spacecraft data in situ in near-Earth space and interplanetary space, in particular using magnetic field and electric field data. Energy spectra for different components of the fluctuating fields, minimum variance analysis, propagation and polarization properties of electromagnetic waves, wave distribution function, helicity quantities, higher-order statistics, and detection methods for wave-particle interactions are explained.

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The Solar Probe Plus Mission: Humanity’s First Visit to Our Star

Cited by 999 publications

References 126 publications

The density compression ratio of shock fronts associated with coronal mass ejections

The density compression ratio of shock fronts associated with coronal mass ejections

Recent progress in astrophysical plasma turbulence from solar wind observations

Review article: Wave analysis methods for space plasma experiment

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