The Ion Transition Range of Solar Wind Turbulence in the Inner Heliosphere: Parker Solar Probe Observations

Huang, Suming; Sahraoui, Fouad; Andrés, Nahuel; Hadid, Lina; Yuan, Zhiyong; He, Jiansen; Zhao, Jinsong; Galtier, Sébastien; Zhang, J.; Deng, Xiaohua; Jiang, K.; Yu, Lei; Xu, S. B.; Xiong, Qian; Wei, Yong; Wit, T. Dudok de; Bale, S. D.; Kasper, J. C.

doi:10.3847/2041-8213/abdaaf

Cited by 22 publications

(28 citation statements)

References 86 publications

(99 reference statements)

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“…Furthermore, other parameters of the plasma, such as plasma beta [48], ion-to-electron heating rate [49,50] and/or effects of outer scale separation [51] may influence the properties of sub-ion scale cascade. Recent PSP observations [24,26] of a young solar wind suggest that the level normalized cross-helicity (imbalance between the counter-propagating Alfvén wave packets) may play a role in the dynamics of the transitional range, which may lead to the observed steepening. Huang et al [26] reported a weak anticorrelation between the transition range spectral index and cross-helicity, in relative terms, such a trend is qualitatively consistent with Figure 8 because higher levels of inertial range fluctuations are characteristic for fast solar wind [52], which exhibits non-zero cross-helicity.…”

Section: Discussionmentioning

confidence: 99%

“…Recent PSP observations [24,26] of a young solar wind suggest that the level normalized cross-helicity (imbalance between the counter-propagating Alfvén wave packets) may play a role in the dynamics of the transitional range, which may lead to the observed steepening. Huang et al [26] reported a weak anticorrelation between the transition range spectral index and cross-helicity, in relative terms, such a trend is qualitatively consistent with Figure 8 because higher levels of inertial range fluctuations are characteristic for fast solar wind [52], which exhibits non-zero cross-helicity. We plan to address the role of cross-helicity in a future study that will employ hybrid-kinetic simulations and the technique introduced in the current manuscript.…”

Section: Discussionmentioning

confidence: 99%

“…By keeping the noise slope constant (b = b fit = −0.03), we can compute the asymptotic value (R obs → ∞) for each local slope, that is, the value of an 'intrinsic' local slope that would have been measured in the absence of the noise, s rec = a = (sR obs + b)/(R obs − 1). Furthermore, a few studies [26,42] showed a dependence of the slopes in the transition range on absolute or relative levels of magnetic field fluctuations, δB or δB/B 0 . Let us denote the average P B within the range of the spacecraft frame frequencies 0.05 Hz < f < 0.1 Hz as P in .…”

Section: Years Of Wind Mfi Datamentioning

confidence: 99%

“…In the power spectral density (PSD) of density, magnetic, velocity, and/or electric fields, the transition manifests itself as a break at the Taylor-shifted (We adopt a concise expression for the Taylor's frozen-in hypothesis that allows a conversion of a temporal measurement, t, to spatial measurement, l: l = V sw t, where V sw is the solar wind speed) spacecraft frame frequency ( f ) of the respective ion characteristic scales [22]. Moreover, a few authors [23][24][25][26] have reported the presence of a double break in the spectra of magnetic field fluctuations: from the inertial range, where the spectrum follows a power law ∝ f α , α ∈ [−1.4, −2] for example, [5,27], it sometimes steepens significantly to f α , α ∈ [−3, −6] [24,26], and then it becomes less steep, ∝ f α , α ∈ [−2.6, −3.2] [28][29][30]. The intermediate range of frequencies where the spectra are steepest is usually denoted as transition range [23].…”

Section: Introductionmentioning

confidence: 99%

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A Novel Method for Estimating the Intrinsic Magnetic Field Spectrum of Kinetic-Range Turbulence

et al. 2021

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Understanding plasma turbulence below the ion characteristic scales is one of the key open problems of solar wind physics. The bulk of our knowledge about the nature of the kinetic-scale fluctuations comes from the high-cadence measurements of the magnetic field. The spacecraft frame frequencies of the sub-ion scale fluctuations are frequently around the Nyquist frequencies of the magnetic field sampling rate. Thus, the resulting ‘measured’ time series may significantly differ from the ‘true’ ones. It follows that second-order moments (e.g., power spectral density, PSD) of the signal may also be highly affected in both their amplitude and their slope. In this paper, we focus on the estimation of the PSD slope for finitely sampled data and we unambiguously define a so-called local slope in the framework of Continuous Wavelet Transform. Employing Monte Carlo simulations, we derive an empirical formula that assesses the statistical error of the local slope estimation. We illustrate the theoretical results by analyzing measurements of the magnetic field instrument (MFI) on board the Wind spacecraft. Our analysis shows that the trace power spectra of magnetic field measurements of MFI can be modeled as the sum of PSD of an uncorrelated noise and an intrinsic signal. We show that the local slope strongly depends on the signal-to-noise (S/N) ratio, stressing that noise can significantly affect the slope even for S/N around 10. Furthermore, we show that the local slopes below the frequency corresponding to proton inertial length, 5≳kλpi>1, depend on the level of the magnetic field fluctuations in the inertial range (Pin), exhibiting a gradual flattening from about −11/3 for high Pin toward about −8/3 for low Pin.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Years Of Wind Mfi Datamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A Novel Method for Estimating the Intrinsic Magnetic Field Spectrum of Kinetic-Range Turbulence

et al. 2021

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“…Several studies have been devoted to the investigation of spectral breaks at both low and high frequencies (e.g., Markovskii et al 2008;Bruno et al 2014Bruno et al , 2017, as well as, to link the location of these breaks to spatial scales in the plasma frame (e.g., Bourouaine et al 2012), mostly related to both ion gyroradius and inertial length (Chen et al 2014). However, various physical processes operate near the observed spectral break (around 1 Hz) such that a direct connection with a peculiar dynamics (e.g., waves vs. instabilities, dispersion vs. damping mechanisms) is really difficult at 1 AU solar distance, thus still remaining an open question (e.g., Alexandrova et al 2013;Huang et al 2021). By searching for scaling-law behaviors and looking at high-order statistics several insights have been provided on turbulence and intermittency (Kolmogorov 1941(Kolmogorov , 1962 as well as on both the direct and inverse energy/enstrophy cascade mechanisms (Matthaeus & Goldstein 1982;Sorriso-Valvo et al 2007).…”

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confidence: 99%

Small-scale Induced Large-scale Transitions in Solar Wind Magnetic Field

Alberti

Faranda

Donner

et al. 2021

ApJL

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We investigate the role of small-scale dynamics in inducing large-scale transitions in the solar wind magnetic field by means of dynamical system metrics based on instantaneous fractal dimensions. By looking at the corresponding multiscale features, we observe a break in the average attractor dimension occurring at the crossover between the inertial and the kinetic/dissipative regime. Our analysis suggests that large-scale transitions are induced by small-scale dynamics through an inverse cascade mechanism driven by local correlations, while electron contributions (if any) are hidden by instrumental noise.

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Observations of cross scale energy transfer in the inner heliosphere by Parker Solar Probe

Parashar

Matthaeus

2022

Rev. Mod. Plasma Phys.

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The solar wind, a continuous flow of plasma from the sun, not only shapes the near Earth space environment but also serves as a natural laboratory to study plasma turbulence in conditions that are not achievable in the lab. Starting with the Mariners, for more than five decades, multiple space missions have enabled in-depth studies of solar wind turbulence. Parker Solar Probe (PSP) was launched to explore the origins and evolution of the solar wind. With its state-of-the-art instrumentation and unprecedented close approaches to the sun, PSP is starting a new era of inner heliospheric exploration. In this review we discuss observations of turbulent energy flow across scales in the inner heliosphere as observed by PSP. After providing a quick theoretical overview and a quick recap of turbulence before PSP, we discuss in detail the observations of energy at various scales on its journey from the largest scales to the internal degrees of freedom of the plasma. We conclude with some open ended questions, many of which we hope that PSP will help answer.

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The Ion Transition Range of Solar Wind Turbulence in the Inner Heliosphere: Parker Solar Probe Observations

Cited by 22 publications

References 86 publications

A Novel Method for Estimating the Intrinsic Magnetic Field Spectrum of Kinetic-Range Turbulence

A Novel Method for Estimating the Intrinsic Magnetic Field Spectrum of Kinetic-Range Turbulence

Small-scale Induced Large-scale Transitions in Solar Wind Magnetic Field

Observations of cross scale energy transfer in the inner heliosphere by Parker Solar Probe

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