Energy partitioning constraints at kinetic scales in low-beta turbulence

Daniel J. Gershman; Adolfo F-Vinas; John C. Dorelli; Melvyn L. Goldstein; Jason Shuster; Levon A. Avanov; Scott A. Boardsen; Julia E. Stawarz; Steven J. Schwartz; Conrad Schiff; Benoit Lavraud; Yoshifumi Saito; William R. Paterson; Barbara L. Giles; Craig J. Pollock; Robert J. Strangeway; Christopher T. Russell; Roy B. Torbert; Thomas E. Moore; James L. Burch

doi:10.1063/1.5009158

Energy partitioning constraints at kinetic scales in low-beta turbulence

Daniel J. Gershman^*, Adolfo F-Vinas, John C. Dorelli, Melvyn L. Goldstein, Jason Shuster, Levon A. Avanov, Scott A. Boardsen, Julia E. Stawarz, Steven J. Schwartz, Conrad Schiff, Benoit Lavraud, Yoshifumi Saito, William R. Paterson, Barbara L. Giles, Craig J. Pollock, Robert J. Strangeway, Christopher T. Russell, Roy B. Torbert, Thomas E. Moore, James L. Burch

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

29 Citations (Scopus)

Abstract

Turbulence is a fundamental physical process through which energy injected into a system at large scales cascades to smaller scales. In collisionless plasmas, turbulence provides a critical mechanism for dissipating electromagnetic energy. Here, we present observations of plasma fluctuations in low-β turbulence using data from NASA's Magnetospheric Multiscale mission in Earth's magnetosheath. We provide constraints on the partitioning of turbulent energy density in the fluid, ion-kinetic, and electron-kinetic ranges. Magnetic field fluctuations dominated the energy density spectrum throughout the fluid and ion-kinetic ranges, consistent with previous observations of turbulence in similar plasma regimes. However, at scales shorter than the electron inertial length, fluctuation power in electron kinetic energy significantly exceeded that of the magnetic field, resulting in an electron-motion-regulated cascade at small scales. This dominance is highly relevant for the study of turbulence in highly magnetized laboratory and astrophysical plasmas.

Original language	English
Article number	022303
Journal	Physics of Plasmas
Volume	25
Issue number	2
DOIs	https://doi.org/10.1063/1.5009158
Publication status	Published - 2018
Externally published	Yes

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10.1063/1.5009158

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Gershman, D. J., F-Vinas, A., Dorelli, J. C., Goldstein, M. L., Shuster, J., Avanov, L. A., Boardsen, S. A., Stawarz, J. E., Schwartz, S. J., Schiff, C., Lavraud, B., Saito, Y., Paterson, W. R., Giles, B. L., Pollock, C. J., Strangeway, R. J., Russell, C. T., Torbert, R. B., Moore, T. E., & Burch, J. L. (2018). Energy partitioning constraints at kinetic scales in low-beta turbulence. Physics of Plasmas, 25(2), Article 022303. https://doi.org/10.1063/1.5009158

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title = "Energy partitioning constraints at kinetic scales in low-beta turbulence",

abstract = "Turbulence is a fundamental physical process through which energy injected into a system at large scales cascades to smaller scales. In collisionless plasmas, turbulence provides a critical mechanism for dissipating electromagnetic energy. Here, we present observations of plasma fluctuations in low-β turbulence using data from NASA's Magnetospheric Multiscale mission in Earth's magnetosheath. We provide constraints on the partitioning of turbulent energy density in the fluid, ion-kinetic, and electron-kinetic ranges. Magnetic field fluctuations dominated the energy density spectrum throughout the fluid and ion-kinetic ranges, consistent with previous observations of turbulence in similar plasma regimes. However, at scales shorter than the electron inertial length, fluctuation power in electron kinetic energy significantly exceeded that of the magnetic field, resulting in an electron-motion-regulated cascade at small scales. This dominance is highly relevant for the study of turbulence in highly magnetized laboratory and astrophysical plasmas.",

author = "Gershman, \{Daniel J.\} and Adolfo F-Vinas and Dorelli, \{John C.\} and Goldstein, \{Melvyn L.\} and Jason Shuster and Avanov, \{Levon A.\} and Boardsen, \{Scott A.\} and Stawarz, \{Julia E.\} and Schwartz, \{Steven J.\} and Conrad Schiff and Benoit Lavraud and Yoshifumi Saito and Paterson, \{William R.\} and Giles, \{Barbara L.\} and Pollock, \{Craig J.\} and Strangeway, \{Robert J.\} and Russell, \{Christopher T.\} and Torbert, \{Roy B.\} and Moore, \{Thomas E.\} and Burch, \{James L.\}",

year = "2018",

doi = "10.1063/1.5009158",

language = "English",

volume = "25",

journal = "Physics of Plasmas",

issn = "1070-664X",

publisher = "American Institute of Physics",

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Gershman, DJ, F-Vinas, A, Dorelli, JC, Goldstein, ML, Shuster, J, Avanov, LA, Boardsen, SA, Stawarz, JE, Schwartz, SJ, Schiff, C, Lavraud, B, Saito, Y, Paterson, WR, Giles, BL, Pollock, CJ, Strangeway, RJ, Russell, CT, Torbert, RB, Moore, TE & Burch, JL 2018, 'Energy partitioning constraints at kinetic scales in low-beta turbulence', Physics of Plasmas, vol. 25, no. 2, 022303. https://doi.org/10.1063/1.5009158

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T1 - Energy partitioning constraints at kinetic scales in low-beta turbulence

AU - Gershman, Daniel J.

AU - F-Vinas, Adolfo

AU - Dorelli, John C.

AU - Goldstein, Melvyn L.

AU - Shuster, Jason

AU - Avanov, Levon A.

AU - Boardsen, Scott A.

AU - Stawarz, Julia E.

AU - Schwartz, Steven J.

AU - Schiff, Conrad

AU - Lavraud, Benoit

AU - Saito, Yoshifumi

AU - Paterson, William R.

AU - Giles, Barbara L.

AU - Pollock, Craig J.

AU - Strangeway, Robert J.

AU - Russell, Christopher T.

AU - Torbert, Roy B.

AU - Moore, Thomas E.

AU - Burch, James L.

PY - 2018

Y1 - 2018

N2 - Turbulence is a fundamental physical process through which energy injected into a system at large scales cascades to smaller scales. In collisionless plasmas, turbulence provides a critical mechanism for dissipating electromagnetic energy. Here, we present observations of plasma fluctuations in low-β turbulence using data from NASA's Magnetospheric Multiscale mission in Earth's magnetosheath. We provide constraints on the partitioning of turbulent energy density in the fluid, ion-kinetic, and electron-kinetic ranges. Magnetic field fluctuations dominated the energy density spectrum throughout the fluid and ion-kinetic ranges, consistent with previous observations of turbulence in similar plasma regimes. However, at scales shorter than the electron inertial length, fluctuation power in electron kinetic energy significantly exceeded that of the magnetic field, resulting in an electron-motion-regulated cascade at small scales. This dominance is highly relevant for the study of turbulence in highly magnetized laboratory and astrophysical plasmas.

AB - Turbulence is a fundamental physical process through which energy injected into a system at large scales cascades to smaller scales. In collisionless plasmas, turbulence provides a critical mechanism for dissipating electromagnetic energy. Here, we present observations of plasma fluctuations in low-β turbulence using data from NASA's Magnetospheric Multiscale mission in Earth's magnetosheath. We provide constraints on the partitioning of turbulent energy density in the fluid, ion-kinetic, and electron-kinetic ranges. Magnetic field fluctuations dominated the energy density spectrum throughout the fluid and ion-kinetic ranges, consistent with previous observations of turbulence in similar plasma regimes. However, at scales shorter than the electron inertial length, fluctuation power in electron kinetic energy significantly exceeded that of the magnetic field, resulting in an electron-motion-regulated cascade at small scales. This dominance is highly relevant for the study of turbulence in highly magnetized laboratory and astrophysical plasmas.

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VL - 25

JO - Physics of Plasmas

JF - Physics of Plasmas

IS - 2

M1 - 022303

ER -

Energy partitioning constraints at kinetic scales in low-beta turbulence

Abstract

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