Solar Wind Turbulence from 1 to 45 au. II. Analysis of Inertial-range Fluctuations Using Voyager and ACE Observations

Zackary B. Pine; Charles W. Smith; Sophia J. Hollick; Matthew R. Argall; Bernard J. Vasquez; Philip A. Isenberg; Nathan A. Schwadron; Colin J. Joyce; Justyna M. Sokół; MacIej Bzowski; Marzena A. Kubiak; Kathleen E. Hamilton; Megan L. McLaurin; Robert J. Leamon

doi:10.3847/1538-4357/abab0f

Solar Wind Turbulence from 1 to 45 au. II. Analysis of Inertial-range Fluctuations Using Voyager and ACE Observations

Zackary B. Pine, Charles W. Smith, Sophia J. Hollick, Matthew R. Argall, Bernard J. Vasquez, Philip A. Isenberg, Nathan A. Schwadron, Colin J. Joyce, Justyna M. Sokół, MacIej Bzowski, Marzena A. Kubiak, Kathleen E. Hamilton, Megan L. McLaurin, Robert J. Leamon

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Abstract

We examine both Voyager and Advanced Composition Explorer magnetic field measurements at frequencies that characterize the inertial range using traditional polarization techniques that are designed to characterize plasma waves. Although we find good agreement with both the anticipated spectral index of the power spectrum and the scaling of magnetic power with heliocentric distance, we do not find that the polarization analyses yield results that can be readily described by plasma wave theory. The fluctuations are not circularly polarized and there is a markedly reduced coherence between the components of the fluctuation. The degree of polarization is also generally low, although not as low as the coherence, and the minimum variance direction is essentially random. We conclude that traditional plasma wave theory may not offer a good description for inertial-range fluctuations.

Original language	English
Article number	92
Journal	Astrophysical Journal
Volume	900
Issue number	2
DOIs	https://doi.org/10.3847/1538-4357/abab0f
State	Published - Sep 10 2020

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Pine, Z. B., Smith, C. W., Hollick, S. J., Argall, M. R., Vasquez, B. J., Isenberg, P. A., Schwadron, N. A., Joyce, C. J., Sokół, J. M., Bzowski, M., Kubiak, M. A., Hamilton, K. E., McLaurin, M. L., & Leamon, R. J. (2020). Solar Wind Turbulence from 1 to 45 au. II. Analysis of Inertial-range Fluctuations Using Voyager and ACE Observations. Astrophysical Journal, 900(2), Article 92. https://doi.org/10.3847/1538-4357/abab0f

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title = "Solar Wind Turbulence from 1 to 45 au. II. Analysis of Inertial-range Fluctuations Using Voyager and ACE Observations",

abstract = "We examine both Voyager and Advanced Composition Explorer magnetic field measurements at frequencies that characterize the inertial range using traditional polarization techniques that are designed to characterize plasma waves. Although we find good agreement with both the anticipated spectral index of the power spectrum and the scaling of magnetic power with heliocentric distance, we do not find that the polarization analyses yield results that can be readily described by plasma wave theory. The fluctuations are not circularly polarized and there is a markedly reduced coherence between the components of the fluctuation. The degree of polarization is also generally low, although not as low as the coherence, and the minimum variance direction is essentially random. We conclude that traditional plasma wave theory may not offer a good description for inertial-range fluctuations.",

author = "Pine, {Zackary B.} and Smith, {Charles W.} and Hollick, {Sophia J.} and Argall, {Matthew R.} and Vasquez, {Bernard J.} and Isenberg, {Philip A.} and Schwadron, {Nathan A.} and Joyce, {Colin J.} and Sok{\'o}{\l}, {Justyna M.} and MacIej Bzowski and Kubiak, {Marzena A.} and Hamilton, {Kathleen E.} and McLaurin, {Megan L.} and Leamon, {Robert J.}",

year = "2020",

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day = "10",

doi = "10.3847/1538-4357/abab0f",

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Pine, ZB, Smith, CW, Hollick, SJ, Argall, MR, Vasquez, BJ, Isenberg, PA, Schwadron, NA, Joyce, CJ, Sokół, JM, Bzowski, M, Kubiak, MA, Hamilton, KE, McLaurin, ML & Leamon, RJ 2020, 'Solar Wind Turbulence from 1 to 45 au. II. Analysis of Inertial-range Fluctuations Using Voyager and ACE Observations', Astrophysical Journal, vol. 900, no. 2, 92. https://doi.org/10.3847/1538-4357/abab0f

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T1 - Solar Wind Turbulence from 1 to 45 au. II. Analysis of Inertial-range Fluctuations Using Voyager and ACE Observations

AU - Pine, Zackary B.

AU - Smith, Charles W.

AU - Hollick, Sophia J.

AU - Argall, Matthew R.

AU - Vasquez, Bernard J.

AU - Isenberg, Philip A.

AU - Schwadron, Nathan A.

AU - Joyce, Colin J.

AU - Sokół, Justyna M.

AU - Bzowski, MacIej

AU - Kubiak, Marzena A.

AU - Hamilton, Kathleen E.

AU - McLaurin, Megan L.

AU - Leamon, Robert J.

PY - 2020/9/10

Y1 - 2020/9/10

N2 - We examine both Voyager and Advanced Composition Explorer magnetic field measurements at frequencies that characterize the inertial range using traditional polarization techniques that are designed to characterize plasma waves. Although we find good agreement with both the anticipated spectral index of the power spectrum and the scaling of magnetic power with heliocentric distance, we do not find that the polarization analyses yield results that can be readily described by plasma wave theory. The fluctuations are not circularly polarized and there is a markedly reduced coherence between the components of the fluctuation. The degree of polarization is also generally low, although not as low as the coherence, and the minimum variance direction is essentially random. We conclude that traditional plasma wave theory may not offer a good description for inertial-range fluctuations.

AB - We examine both Voyager and Advanced Composition Explorer magnetic field measurements at frequencies that characterize the inertial range using traditional polarization techniques that are designed to characterize plasma waves. Although we find good agreement with both the anticipated spectral index of the power spectrum and the scaling of magnetic power with heliocentric distance, we do not find that the polarization analyses yield results that can be readily described by plasma wave theory. The fluctuations are not circularly polarized and there is a markedly reduced coherence between the components of the fluctuation. The degree of polarization is also generally low, although not as low as the coherence, and the minimum variance direction is essentially random. We conclude that traditional plasma wave theory may not offer a good description for inertial-range fluctuations.

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ER -

Solar Wind Turbulence from 1 to 45 au. II. Analysis of Inertial-range Fluctuations Using Voyager and ACE Observations

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