Highly Alfvénic slow solar wind at 0.3 au during a solar minimum: Helios insights for Parker Solar Probe and Solar Orbiter

Perrone, D.; D’Amicis, R.; Marco, R. De; Matteini, Lorenzo; Stansby, David; Bruno, R.; Horbury, T. S.

doi:10.1051/0004-6361/201937064

Cited by 37 publications

(30 citation statements)

References 52 publications

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“…The low magnetic compressibility found by Perrone, Bruno, et al. (2020) are in agreement with both results in the inner heliosphere (Bavassano, Dobrowolny, Fanfoni, et al., 1982) and at 1 AU (Perrone et al., 2017) in fast solar wind. The presence of small‐scale coherent structures during PSP’s first encounter has also been highlighted by employing the partial variance of increments (PVI) technique (Greco et al., 2008).…”

Section: In Situ Observationssupporting

confidence: 89%

“…Moreover, Perrone, Bruno, et al. (2020) have studied magnetic properties at ion scales in three selected periods characterized by different switchbacks activity. They found that this range of scales appears to be characterized by a high level of intermittency, with the presence of non‐compressive coherent events, such as current sheets, vortex‐like structures, and wave packets identified as ion cyclotron modes.…”

Section: In Situ Observationsmentioning

confidence: 99%

“…Please refer to D’Amicis, Matteini, and Bruno (2019) for Wind data; Perrone, D’Amicis, et al. (2020) for Helios data; and Bale et al. (2019) for PSP data.…”

Section: Data Availability Statementmentioning

confidence: 99%

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On Alfvénic Slow Wind: A Journey From the Earth Back to the Sun

et al. 2021

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Introduction"Asking for the average solar wind might appear as silly as asking for the taste of an average drink. What is the average between wine and beer? Obviously mere mixing-and averaging means mixing-does not lead to a meaningful result. Better taste and judge separately and then compare, if you wish." (Reiner Schwenn, Solar Wind 5, 1982) Following this basic idea, the quasi-stationary solar wind observed in the heliosphere has been traditionally categorized into two types based on particle bulk speed (Borovsky, 2012a;Stakhiv et al., 2015;Zurbuchen, 2007), namely fast (V sw > 600 km/s) and slow (V sw < 500 km/s) wind, also characterized by different features ranging from large to small scales. Indeed, slow wind has lower proton temperature and higher density, and in general much more variable properties, with respect to fast wind (Bruno et al., 1986;Lopez & Freeman, 1986;Schwenn, 2006). Moreover, the variability in the observed relative abundance of different charge-states of solar wind ions implies an anti-correlation of the freezing-in temperature with wind speed (Geiss et al., 1995;Kasper et al., 2012), and the thermodynamics of electrons, protons and heavy ions has also been observed to vary with speed (

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Section: In Situ Observationssupporting

confidence: 89%

Section: In Situ Observationsmentioning

confidence: 99%

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On Alfvénic Slow Wind: A Journey From the Earth Back to the Sun

et al. 2021

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“…[106]. These results were further supported by another study by the same authors [107] who presented the first statistical evidence of the presence of a slow Alfvénic solar wind during maximum of solar activity and found to be very similar to the fast wind on many respects and not only for the Alfvénic content of the fluctuations [44,[108][109][110][111][112]. [107] demonstrated that the nature of these kind of fluctuations plays a major role in the geomagnetic activity rather than the type of wind selected on the basis of the flow speed.…”

Section: Connecting Solar Wind Turbulence and Geomagnetic Responsesupporting

confidence: 59%

The Effect of Solar-Wind Turbulence on Magnetospheric Activity

D’Amicis

Telloni²,

Bruno

2020

Front. Phys.

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The solar wind is a highly turbulent medium exhibiting scalings of the fluctuations ranging over several decades of scales from the correlation length down to proton and electron gyroradii, thus suggesting a self-similar nature for these fluctuations. During its journey, the solar wind encounters the region of space surrounding Earth dominated by the geomagnetic field which is called magnetosphere. The latter is exposed to the continuous buffeting of the solar wind which determines its characteristic comet-like shape. The solar wind and the magnetosphere interact continously, thus constituting a coupled system, since perturbations in the interplanetary medium cause geomagnetic disturbances. However, strong variations in the geomagnetic field occur even in absence of large solar perturbations. In this case, a major role is attributed to solar wind turbulence as a driver of geomagnetic activity especially at high latitudes. In this review, we report about the state-of-art related to this topic. Since the solar wind and the magnetosphere are both high Reynolds number plasmas, both follow a scale-invariant dynamics and are in a state far from equilibrium. Moreover, the geomagnetic response, although closely related to the changes of the interplanetary magnetic field condition, is also strongly affected by the intrinsic dynamics of the magnetosphere generated by geomagnetic field variations caused by the internal conditions.

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“…Matteini et al (2018) found that the presence of the −1 frequency range could be a result of the saturation of the amplitude of the magnetic fluctuations in the fast wind. D' Amicis et al (2019) reported that the slow solar wind with high Alfvénicity share common characteristics with the fast wind, and Perrone et al (2020) further observed that Alfvénic slow wind shows a break between the inertial range and large scales where the magnetic fluctuations saturate. It seems plausible that this −1 frequency range is related to the observations of Alfvénic switchbacks (de Wit et al 2020;Horbury et al 2020;Mozer et al 2020;McManus et al 2020), close the Sun, that provide most of the energy-containing range in the slow wind.…”

Section: Discussionmentioning

confidence: 98%

Energy Supply for Heating the Slow Solar Wind Observed by Parker Solar Probe between 0.17 and 0.7 au

Wang

et al. 2020

ApJL

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Energy supply sources for the heating process in the slow solar wind remain unknown. The Parker Solar Probe (PSP) mission provides a good opportunity to study this issue. Recently, PSP observations have found that the slow solar wind experiences stronger heating inside 0.24 au. Here for the first time we measure in the slow solar wind the radial gradient of the low-frequency breaks on the magnetic trace power spectra and evaluate the associated energy supply rate. We find that the energy supply rate is consistent with the observed perpendicular heating rate calculated based on the gradient of the magnetic moment. Based on this finding, one could explain why the slow solar wind is strongly heated inside 0.25 au but expands nearly adiabatically outside 0.25 au. This finding supports the concept that the energy added from the energy-containing range is transferred by an energy cascade process to the dissipation range, and then dissipates to heat the slow solar wind. The related issues for further study are discussed.

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Highly Alfvénic slow solar wind at 0.3 au during a solar minimum: Helios insights for Parker Solar Probe and Solar Orbiter

Cited by 37 publications

References 52 publications

On Alfvénic Slow Wind: A Journey From the Earth Back to the Sun

On Alfvénic Slow Wind: A Journey From the Earth Back to the Sun

The Effect of Solar-Wind Turbulence on Magnetospheric Activity

Energy Supply for Heating the Slow Solar Wind Observed by Parker Solar Probe between 0.17 and 0.7 au

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