Magnetic field generation in a jet-sheath plasma via the kinetic Kelvin-Helmholtz instability

K.-I. Nishikawa; P. Hardee; B. Zhang; I. Dutan; M. Medvedev; E.J. Choi; K.W. Min; J. Niemiec; Y. Mizuno; Åke Nordlund; Jacob Trier Frederiksen; H. Sol; M. Pohl; D.H. Hartmann

doi:10.5194/angeo-31-1535-2013

Magnetic field generation in a jet-sheath plasma via the kinetic Kelvin-Helmholtz instability

K.-I. Nishikawa, P. Hardee, B. Zhang, I. Dutan, M. Medvedev, E.J. Choi, K.W. Min, J. Niemiec, Y. Mizuno, Åke Nordlund, Jacob Trier Frederiksen, H. Sol, M. Pohl, D.H. Hartmann

Astrophysics and Planetary Science

14 Citations (Scopus)

Abstract

We have investigated the generation of magnetic fields associated with velocity shear between an unmagnetized relativistic jet and an unmagnetized sheath plasma. We have examined the strong magnetic fields generated by kinetic shear (Kelvin-Helmholtz) instabilities. Compared to the previous studies using counter-streaming performed by Alves et al. (2012), the structure of the kinetic Kelvin-Helmholtz instability (KKHI) of our jet-sheath configuration is slightly different, even for the global evolution of the strong transverse magnetic field. In our simulations the major components of growing modes are the electric field/z, perpendicular to the flow boundary, and the magnetic field B/y, transverse to the flow direction. After the B/y component is excited, an induced electric field/x, parallel to the flow direction, becomes significant. However, other field components remain small. We find that the structure and growth rate of KKHI with mass ratios mi/me Combining double low line 1836 and mi/me Combining double low line 20 are similar. In our simulations saturation in the nonlinear stage is not as clear as in counter-streaming cases. The growth rate for a mildly-relativistic jet case (γj Combining double low line 1.5) is larger than for a relativistic jet case (γj Combining double low line 15).

Original language	English
Journal	Annales Geophysicae
Volume	31
Issue number	9
Pages (from-to)	1535-1541
ISSN	0992-7689
DOIs	https://doi.org/10.5194/angeo-31-1535-2013
Publication status	Published - 1 Jul 2013

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Nishikawa, K-I., Hardee, P., Zhang, B., Dutan, I., Medvedev, M., Choi, E. J., Min, K. W., Niemiec, J., Mizuno, Y., Nordlund, Å., Frederiksen, J. T., Sol, H., Pohl, M., & Hartmann, D. H. (2013). Magnetic field generation in a jet-sheath plasma via the kinetic Kelvin-Helmholtz instability. Annales Geophysicae, 31(9), 1535-1541. https://doi.org/10.5194/angeo-31-1535-2013

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title = "Magnetic field generation in a jet-sheath plasma via the kinetic Kelvin-Helmholtz instability",

abstract = "We have investigated the generation of magnetic fields associated with velocity shear between an unmagnetized relativistic jet and an unmagnetized sheath plasma. We have examined the strong magnetic fields generated by kinetic shear (Kelvin-Helmholtz) instabilities. Compared to the previous studies using counter-streaming performed by Alves et al. (2012), the structure of the kinetic Kelvin-Helmholtz instability (KKHI) of our jet-sheath configuration is slightly different, even for the global evolution of the strong transverse magnetic field. In our simulations the major components of growing modes are the electric field/z, perpendicular to the flow boundary, and the magnetic field B/y, transverse to the flow direction. After the B/y component is excited, an induced electric field/x, parallel to the flow direction, becomes significant. However, other field components remain small. We find that the structure and growth rate of KKHI with mass ratios mi/me Combining double low line 1836 and mi/me Combining double low line 20 are similar. In our simulations saturation in the nonlinear stage is not as clear as in counter-streaming cases. The growth rate for a mildly-relativistic jet case (γj Combining double low line 1.5) is larger than for a relativistic jet case (γj Combining double low line 15).",

author = "K.-I. Nishikawa and P. Hardee and B. Zhang and I. Dutan and M. Medvedev and E.J. Choi and K.W. Min and J. Niemiec and Y. Mizuno and {\AA}ke Nordlund and Frederiksen, {Jacob Trier} and H. Sol and M. Pohl and D.H. Hartmann",

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doi = "10.5194/angeo-31-1535-2013",

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TY - JOUR

T1 - Magnetic field generation in a jet-sheath plasma via the kinetic Kelvin-Helmholtz instability

AU - Nishikawa, K.-I.

AU - Hardee, P.

AU - Zhang, B.

AU - Dutan, I.

AU - Medvedev, M.

AU - Choi, E.J.

AU - Min, K.W.

AU - Niemiec, J.

AU - Mizuno, Y.

AU - Nordlund, Åke

AU - Frederiksen, Jacob Trier

AU - Sol, H.

AU - Pohl, M.

AU - Hartmann, D.H.

PY - 2013/7/1

Y1 - 2013/7/1

N2 - We have investigated the generation of magnetic fields associated with velocity shear between an unmagnetized relativistic jet and an unmagnetized sheath plasma. We have examined the strong magnetic fields generated by kinetic shear (Kelvin-Helmholtz) instabilities. Compared to the previous studies using counter-streaming performed by Alves et al. (2012), the structure of the kinetic Kelvin-Helmholtz instability (KKHI) of our jet-sheath configuration is slightly different, even for the global evolution of the strong transverse magnetic field. In our simulations the major components of growing modes are the electric field/z, perpendicular to the flow boundary, and the magnetic field B/y, transverse to the flow direction. After the B/y component is excited, an induced electric field/x, parallel to the flow direction, becomes significant. However, other field components remain small. We find that the structure and growth rate of KKHI with mass ratios mi/me Combining double low line 1836 and mi/me Combining double low line 20 are similar. In our simulations saturation in the nonlinear stage is not as clear as in counter-streaming cases. The growth rate for a mildly-relativistic jet case (γj Combining double low line 1.5) is larger than for a relativistic jet case (γj Combining double low line 15).

AB - We have investigated the generation of magnetic fields associated with velocity shear between an unmagnetized relativistic jet and an unmagnetized sheath plasma. We have examined the strong magnetic fields generated by kinetic shear (Kelvin-Helmholtz) instabilities. Compared to the previous studies using counter-streaming performed by Alves et al. (2012), the structure of the kinetic Kelvin-Helmholtz instability (KKHI) of our jet-sheath configuration is slightly different, even for the global evolution of the strong transverse magnetic field. In our simulations the major components of growing modes are the electric field/z, perpendicular to the flow boundary, and the magnetic field B/y, transverse to the flow direction. After the B/y component is excited, an induced electric field/x, parallel to the flow direction, becomes significant. However, other field components remain small. We find that the structure and growth rate of KKHI with mass ratios mi/me Combining double low line 1836 and mi/me Combining double low line 20 are similar. In our simulations saturation in the nonlinear stage is not as clear as in counter-streaming cases. The growth rate for a mildly-relativistic jet case (γj Combining double low line 1.5) is larger than for a relativistic jet case (γj Combining double low line 15).

U2 - 10.5194/angeo-31-1535-2013

DO - 10.5194/angeo-31-1535-2013

M3 - Journal article

SN - 0992-7689

VL - 31

SP - 1535

EP - 1541

JO - Annales Geophysicae

JF - Annales Geophysicae

IS - 9

ER -

Magnetic field generation in a jet-sheath plasma via the kinetic Kelvin-Helmholtz instability

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