Kinetic Slow Mode in the Solar Wind and Its Possible Role in Turbulence Dissipation and Ion Heating

Narita, Yasuhito; Marsch, E.

doi:10.1088/0004-637x/805/1/24

Cited by 44 publications

(50 citation statements)

References 59 publications

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“…Moreover, even though some points in Fig. 1c and d, may agree better with the curves for IBWs as there is no significant signature in the cross-correlation, this is most likely due to wave-wave interactions between individual KAW packets or KAWs and KSWs (Narita and Motschmann, 2017;Roberts et al, 2017). It is also interesting to note that while the KAW dominates both other wave modes, the majority of the fluctuations do not fall into the thresholds in Table 1.…”

Section: Resultsmentioning

confidence: 70%

“…Several multi-spacecraft observations of the solar wind have revealed that the fluctuations at proton kinetic scales typically have low intrinsic propagation speeds in the plasma frame. This result has been interpreted as evidence of kinetic Alfvén waves (KAWs) (Sahraoui et al, 2010), as coherent structures which are predominantly advected with the bulk velocity (Perrone et al, 2017), as a combination of KAW turbulence and coherent structures (Roberts et al, 2013(Roberts et al, , 2015, or as nonlinear modes where wave-wave interactions have broadened the dispersion relation diagram (Narita and Motschmann, 2017;Roberts et al, 2017). Kinetic slow waves (KSWs) are the kinetic counterpart of the magnetohydrodynamic (MHD) slow mode when it develops a large perpendicular wave number, and it shares many properties with the KAW, such as a similar dispersion relation and anticorrelated fluctuations in magnetic field and density Narita and Marsch, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Multi-scale analysis of compressible fluctuations in the solar wind

Roberts¹,

Narita²,

Escoubet³

2018

Ann. Geophys.

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Abstract. Compressible plasma turbulence is investigated in the fast solar wind at proton kinetic scales by the combined use of electron density and magnetic field measurements. Both the scale-dependent cross-correlation (CC) and the reduced magnetic helicity (σ m ) are used in tandem to determine the properties of the compressible fluctuations at proton kinetic scales. At inertial scales the turbulence is hypothesised to contain a mixture of Alfvénic and slow waves, characterised by weak magnetic helicity and anti-correlation between magnetic field strength B and electron density n e . At proton kinetic scales the observations suggest that the fluctuations have stronger positive magnetic helicities as well as strong anti-correlations within the frequency range studied. These results are interpreted as being characteristic of either counter-propagating kinetic Alfvén wave packets or a mixture of anti-sunward kinetic Alfvén waves along with a component of kinetic slow waves.

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Section: Resultsmentioning

confidence: 70%

Section: Introductionmentioning

confidence: 99%

Multi-scale analysis of compressible fluctuations in the solar wind

Roberts¹,

Narita²,

Escoubet³

2018

Ann. Geophys.

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“…The observation of pressure-balanced structures (PBSs) in the solar wind (Burlaga & Ogilvie 1970;Vellante & Lazarus 1987;Burlaga et al 1990;Zank et al 1990;Marsch & Tu 1993;Tu & Marsch 1994;Ghosh et al 1998;Bavassano et al 2004;Yao et al 2011Yao et al , 2013aYao et al , 2013bNarita & Marsch 2015) suggests that IA modes indeed account for only a minority of the total compressive energy, because IA waves perturb the total pressure, whereas NP modes are associated with approximate total-pressure balance in the limit   k 0. Future observational studies to constrain the IA fraction in the solar wind will be important for further testing of the importance of the fluctuating-anisotropy effect in the solar wind.…”

Section: Discussionmentioning

confidence: 99%

Collisionless Isotropization of the Solar-Wind Protons by Compressive Fluctuations and Plasma Instabilities

Verscharen

Chandran

Klein

et al. 2016

ApJ

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p , whereT p and  T p are the perpendicular and parallel temperatures of the protons, B is the magnetic field strength, and n p is the proton density. If the amplitude of the compressive fluctuations is large enough, R p crosses one or more instability thresholds for anisotropy-driven microinstabilities. The enhanced field fluctuations from these microinstabilities scatter the protons so as to reduce the anisotropy of the pressure tensor. We propose that this scattering drives the average value of R p away from the marginal stability boundary until the fluctuating value of R p stops crossing the boundary. We model this "fluctuating-anisotropy effect" using linear VlasovMaxwell theory to describe the large-scale compressive fluctuations. We argue that this effect can explain why, in the nearly collisionless solar wind, the average value of R p is close to unity.

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“…-Kinetic slow mode is a kinetic extension of the MHD slow mode (Zhao et al, 2014;Narita and Marsch, 2015) and its existence is suggested by a pressure-balance structure in the solar wind (Yao et al, 2013). Kinetic slow mode is obtained as a quasi-perpendicular limit of the ion acoustic waves and becomes less damped at highly oblique angles at around 85 • and larger.…”

Section: Introductionmentioning

confidence: 98%

“…There are only few observation cases in space plasmas within a frequency range between the fundamental and several harmonics of the ion gyro-frequency such as fluctuations in the solar wind (Perschke et al, 2013(Perschke et al, , 2014 and in the magnetic reconnection outflow region (Narita et al, 2016a). The ion Bernstein modes are clearly visible in direct numerical simulations, and offer various kinds of wave-wave interactions for the parametric instability (Jenkins et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

On the role of ion-scale whistler waves in space and astrophysical plasma turbulence

et al. 2016

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Abstract. Competition of linear mode waves is studied numerically to understand the energy cascade mechanism in plasma turbulence on ion-kinetic scales. Hybrid plasma simulations are performed in a 3-D simulation box by pumping large-scale Alfvén waves on the fluid scale. The result is compared with that from our earlier 2-D simulations. We find that the whistler mode is persistently present both in the 2-D and 3-D simulations irrespective of the initial setup, e.g., the amplitude of the initial pumping waves, while all the other modes are excited and damped such that the energy is efficiently transported to thermal energy over non-whistler mode. The simulation results suggest that the whistler mode could transfer the fluctuation energy smoothly from the fluid scale down to the electron-kinetic scale, and justifies the notion of whistler turbulence.

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Kinetic Slow Mode in the Solar Wind and Its Possible Role in Turbulence Dissipation and Ion Heating

Cited by 44 publications

References 59 publications

Multi-scale analysis of compressible fluctuations in the solar wind

Multi-scale analysis of compressible fluctuations in the solar wind

Collisionless Isotropization of the Solar-Wind Protons by Compressive Fluctuations and Plasma Instabilities

On the role of ion-scale whistler waves in space and astrophysical plasma turbulence

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