The Amplitude of Magnetohydrodynamic Turbulence in the Inner Solar Wind

Spangler, S. R.

doi:10.1086/341889

Cited by 52 publications

(56 citation statements)

References 28 publications

(76 reference statements)

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“…deviation of the density turbulence in the fast solar wind at wavenumber k = 1.4 × 10 6 km −1 . The results for the slow solar wind density turbulence (Marsch & Tu, 1990;Woo et al, 1995) showed a constant level around 10 % which was also found in the later study from Spangler (2002). More recently Chen et al (2012Chen et al ( , 2013b have examined the slope of the density fluctuations power spectral density for 17 intervals of solar wind.…”

Section: Solar Wind Conditionssupporting

confidence: 64%

A review of solar type III radio bursts

Reid

Ratcliffe

2014

Res. Astron. Astrophys.

334

217

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Solar type III radio bursts are an important diagnostic tool in the understanding of solar accelerated electron beams. They are a signature of propagating beams of nonthermal electrons in the solar atmosphere and the solar system. Consequently, they provide information on electron acceleration and transport, and the conditions of the background ambient plasma they travel through. We review the observational properties of type III bursts with an emphasis on recent results and how each property can help identify attributes of electron beams and the ambient background plasma. We also review some of the theoretical aspects of type III radio bursts and cover a number of numerical efforts that simulate electron beam transport through the solar corona and the heliosphere.

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Section: Solar Wind Conditionssupporting

confidence: 64%

A review of solar type III radio bursts

Reid

Ratcliffe

2014

Res. Astron. Astrophys.

334

217

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“…F o rt h es o l a rw i n d ,α ∼ 11/3 agrees with that of Kolmogorov derived for fluid turbulence (Spangler & Sakurai, 1995;Spangler et al , 2002;Spangler , 2002;Tu & Marsch , 1994;Wohlmuth et al , 2001;Woo et al , 1995). The inner scale l i (which is also known as the dissipative scale) increases linearly with heliocentric distance as l i =(…”

Section: Electron Density Fluctuationssupporting

confidence: 82%

“…For a Kolmogorov spectrum with α = 11/3, this expression takes the form Spangler (2002). For the flat spectrum with α = 3, this becomes…”

Section: Electron Density Fluctuationsmentioning

confidence: 99%

Monte Carlo Simulations in Solar Radio Astronomy

Thejappa¹,

MacDowall²

2011

Applications of Monte Carlo Method in Science and Engineering

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“…Lee and Jokipii, 1975;Rickett, 1977;Coles and Harmon, 1989;Bastian, 1994;Cairns, 1998;Spangler, 2002] …”

Section: Density Turbulencementioning

confidence: 99%

“…[9] The empirical model we use for C N 2 (R) was originally mooted by Armstrong and Woo [1980] and later refined, based on VLBI observations between 10 and 50 R , by, for example, Spangler and Sakurai [1995] and Spangler [2002]:…”

Section: Density Turbulencementioning

confidence: 99%

Constraints on coronal turbulence models from source sizes of noise storms at 327 MHz

Subramanian

Cairns

2011

J. Geophys. Res.

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[1] We seek to reconcile observations of small source sizes in the solar corona at 327 MHz with predictions of scattering models that incorporate refractive index effects, inner scale effects, and a spherically diverging wavefront. We use an empirical prescription for the turbulence amplitude C N 2 (R) based on very long baseline interferometry observations by Spangler et al. of compact radio sources against the solar wind for heliocentric distances R ≈ 10-50 R . We use the Coles and Harmon model for the inner scale l i (R), which is presumed to arise from cyclotron damping. In view of the prevalent uncertainty in the power law index that characterizes solar wind turbulence at various heliocentric distances, we retain this index as a free parameter. We find that the inclusion of spherical divergence effects suppresses the predicted source size substantially. We also find that inner scale effects significantly reduce the predicted source size. An important general finding for solar sources is that the calculations substantially underpredict the observed source size. Three possible, nonexclusive, interpretations of this general result are proposed. First and simplest, future observations with better angular resolution will detect much smaller sources. Consistent with this, previous observations of small sources in the corona at metric wavelengths are limited by the instrument resolution. Second, the spatially varying level of turbulence C N 2 (R) is much larger in the inner corona than predicted by straightforward extrapolation sunward of the empirical prescription, which was based on observations between 10 and 50 R . Either the functional form or the constant of proportionality could be different. Third, perhaps the inner scale is smaller than the model, leading to increased scattering. These results and interpretations are discussed and compared with earlier work.

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The Amplitude of Magnetohydrodynamic Turbulence in the Inner Solar Wind

Cited by 52 publications

References 28 publications

A review of solar type III radio bursts

A review of solar type III radio bursts

Monte Carlo Simulations in Solar Radio Astronomy

Constraints on coronal turbulence models from source sizes of noise storms at 327 MHz

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