HAWC+ Far-infrared Observations of the Magnetic Field Geometry in M51 and NGC 891

Terry Jay Jones; Jin Ah Kim; C. Darren Dowell; Mark R. Morris; Jorge L. Pineda; Dominic J. Benford; Marc Berthoud; David T. Chuss; Daniel A. Dale; L. M. Fissel; Paul F. Goldsmith; Ryan T. Hamilton; Shaul Hanany; Doyal A. Harper; Thomas K. Henning; Alex Lazarian; Leslie W. Looney; Joseph M. Michail; Giles Novak; Fabio P. Santos; Kartik Sheth; Javad Siah; Gordon J. Stacey; Johannes Staguhn; Ian W. Stephens; Konstantinos Tassis; Christopher Q. Trinh; John E. Vaillancourt; Derek Ward-Thompson; Michael Werner; Edward J. Wollack; Ellen G. Zweibel

doi:10.3847/1538-3881/abada8

HAWC+ Far-infrared Observations of the Magnetic Field Geometry in M51 and NGC 891

Terry Jay Jones, Jin Ah Kim, C. Darren Dowell, Mark R. Morris, Jorge L. Pineda, Dominic J. Benford, Marc Berthoud, David T. Chuss, Daniel A. Dale, L. M. Fissel, Paul F. Goldsmith, Ryan T. Hamilton, Shaul Hanany, Doyal A. Harper, Thomas K. Henning, Alex Lazarian, Leslie W. Looney, Joseph M. Michail, Giles Novak, Fabio P. SantosKartik Sheth, Javad Siah, Gordon J. Stacey, Johannes Staguhn, Ian W. Stephens, Konstantinos Tassis, Christopher Q. Trinh, John E. Vaillancourt, Derek Ward-Thompson, Michael Werner, Edward J. Wollack, Ellen G. Zweibel

Physics and Astronomy (Twin Cities)

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Abstract

Stratospheric Observatory for Infrared Astronomy High-resolution Airborne Wideband Camera Plus polarimetry at 154 μm is reported for the face-on galaxy M51 and the edge-on galaxy NGC 891. For M51, the polarization vectors generally follow the spiral pattern defined by the molecular gas distribution, the far-infrared (FIR) intensity contours, and other tracers of star formation. The fractional polarization is much lower in the FIR-bright central regions than in the outer regions, and we rule out loss of grain alignment and variations in magnetic field strength as causes. When compared with existing synchrotron observations, which sample different regions with different weighting, we find the net position angles are strongly correlated, the fractional polarizations are moderately correlated, but the polarized intensities are uncorrelated. We argue that the low fractional polarization in the central regions must be due to significant numbers of highly turbulent segments across the beam and along lines of sight in the beam in the central 3 kpc of M51. For NGC 891, the FIR polarization vectors within an intensity contour of 1500 are oriented very close to the plane of the galaxy. The FIR polarimetry is probably sampling the magnetic field geometry in NGC 891 much deeper into the disk than is possible with NIR polarimetry and radio synchrotron measurements. In some locations in NGC 891, the FIR polarization is very low, suggesting we are preferentially viewing the magnetic field mostly along the line of sight, down the length of embedded spiral arms. There is tentative evidence for a vertical field in the polarized emission off the plane of the disk.

Original language	English (US)
Article number	167
Journal	Astronomical Journal
Volume	160
Issue number	4
DOIs	https://doi.org/10.3847/1538-3881/abada8
State	Published - Oct 2020

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© 2020. The Author(s). Published by the American Astronomical Society..

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Jones, T. J., Kim, J. A., Dowell, C. D., Morris, M. R., Pineda, J. L., Benford, D. J., Berthoud, M., Chuss, D. T., Dale, D. A., Fissel, L. M., Goldsmith, P. F., Hamilton, R. T., Hanany, S., Harper, D. A., Henning, T. K., Lazarian, A., Looney, L. W., Michail, J. M., Novak, G., ... Zweibel, E. G. (2020). HAWC+ Far-infrared Observations of the Magnetic Field Geometry in M51 and NGC 891. Astronomical Journal, 160(4), Article 167. https://doi.org/10.3847/1538-3881/abada8

Jones, TJ, Kim, JA, Dowell, CD, Morris, MR, Pineda, JL, Benford, DJ, Berthoud, M, Chuss, DT, Dale, DA, Fissel, LM, Goldsmith, PF, Hamilton, RT, Hanany, S, Harper, DA, Henning, TK, Lazarian, A, Looney, LW, Michail, JM, Novak, G, Santos, FP, Sheth, K, Siah, J, Stacey, GJ, Staguhn, J, Stephens, IW, Tassis, K, Trinh, CQ, Vaillancourt, JE, Ward-Thompson, D, Werner, M, Wollack, EJ & Zweibel, EG 2020, 'HAWC+ Far-infrared Observations of the Magnetic Field Geometry in M51 and NGC 891', Astronomical Journal, vol. 160, no. 4, 167. https://doi.org/10.3847/1538-3881/abada8

@article{290deef22c0247e789fa3d8e8212a99c,

title = "HAWC+ Far-infrared Observations of the Magnetic Field Geometry in M51 and NGC 891",

abstract = "Stratospheric Observatory for Infrared Astronomy High-resolution Airborne Wideband Camera Plus polarimetry at 154 μm is reported for the face-on galaxy M51 and the edge-on galaxy NGC 891. For M51, the polarization vectors generally follow the spiral pattern defined by the molecular gas distribution, the far-infrared (FIR) intensity contours, and other tracers of star formation. The fractional polarization is much lower in the FIR-bright central regions than in the outer regions, and we rule out loss of grain alignment and variations in magnetic field strength as causes. When compared with existing synchrotron observations, which sample different regions with different weighting, we find the net position angles are strongly correlated, the fractional polarizations are moderately correlated, but the polarized intensities are uncorrelated. We argue that the low fractional polarization in the central regions must be due to significant numbers of highly turbulent segments across the beam and along lines of sight in the beam in the central 3 kpc of M51. For NGC 891, the FIR polarization vectors within an intensity contour of 1500 are oriented very close to the plane of the galaxy. The FIR polarimetry is probably sampling the magnetic field geometry in NGC 891 much deeper into the disk than is possible with NIR polarimetry and radio synchrotron measurements. In some locations in NGC 891, the FIR polarization is very low, suggesting we are preferentially viewing the magnetic field mostly along the line of sight, down the length of embedded spiral arms. There is tentative evidence for a vertical field in the polarized emission off the plane of the disk.",

author = "Jones, {Terry Jay} and Kim, {Jin Ah} and Dowell, {C. Darren} and Morris, {Mark R.} and Pineda, {Jorge L.} and Benford, {Dominic J.} and Marc Berthoud and Chuss, {David T.} and Dale, {Daniel A.} and Fissel, {L. M.} and Goldsmith, {Paul F.} and Hamilton, {Ryan T.} and Shaul Hanany and Harper, {Doyal A.} and Henning, {Thomas K.} and Alex Lazarian and Looney, {Leslie W.} and Michail, {Joseph M.} and Giles Novak and Santos, {Fabio P.} and Kartik Sheth and Javad Siah and Stacey, {Gordon J.} and Johannes Staguhn and Stephens, {Ian W.} and Konstantinos Tassis and Trinh, {Christopher Q.} and Vaillancourt, {John E.} and Derek Ward-Thompson and Michael Werner and Wollack, {Edward J.} and Zweibel, {Ellen G.}",

note = "Publisher Copyright: {\textcopyright} 2020. The Author(s). Published by the American Astronomical Society..",

year = "2020",

month = oct,

doi = "10.3847/1538-3881/abada8",

language = "English (US)",

volume = "160",

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T1 - HAWC+ Far-infrared Observations of the Magnetic Field Geometry in M51 and NGC 891

AU - Jones, Terry Jay

AU - Kim, Jin Ah

AU - Dowell, C. Darren

AU - Morris, Mark R.

AU - Pineda, Jorge L.

AU - Benford, Dominic J.

AU - Berthoud, Marc

AU - Chuss, David T.

AU - Dale, Daniel A.

AU - Fissel, L. M.

AU - Goldsmith, Paul F.

AU - Hamilton, Ryan T.

AU - Hanany, Shaul

AU - Harper, Doyal A.

AU - Henning, Thomas K.

AU - Lazarian, Alex

AU - Looney, Leslie W.

AU - Michail, Joseph M.

AU - Novak, Giles

AU - Santos, Fabio P.

AU - Sheth, Kartik

AU - Siah, Javad

AU - Stacey, Gordon J.

AU - Staguhn, Johannes

AU - Stephens, Ian W.

AU - Tassis, Konstantinos

AU - Trinh, Christopher Q.

AU - Vaillancourt, John E.

AU - Ward-Thompson, Derek

AU - Werner, Michael

AU - Wollack, Edward J.

AU - Zweibel, Ellen G.

PY - 2020/10

Y1 - 2020/10

N2 - Stratospheric Observatory for Infrared Astronomy High-resolution Airborne Wideband Camera Plus polarimetry at 154 μm is reported for the face-on galaxy M51 and the edge-on galaxy NGC 891. For M51, the polarization vectors generally follow the spiral pattern defined by the molecular gas distribution, the far-infrared (FIR) intensity contours, and other tracers of star formation. The fractional polarization is much lower in the FIR-bright central regions than in the outer regions, and we rule out loss of grain alignment and variations in magnetic field strength as causes. When compared with existing synchrotron observations, which sample different regions with different weighting, we find the net position angles are strongly correlated, the fractional polarizations are moderately correlated, but the polarized intensities are uncorrelated. We argue that the low fractional polarization in the central regions must be due to significant numbers of highly turbulent segments across the beam and along lines of sight in the beam in the central 3 kpc of M51. For NGC 891, the FIR polarization vectors within an intensity contour of 1500 are oriented very close to the plane of the galaxy. The FIR polarimetry is probably sampling the magnetic field geometry in NGC 891 much deeper into the disk than is possible with NIR polarimetry and radio synchrotron measurements. In some locations in NGC 891, the FIR polarization is very low, suggesting we are preferentially viewing the magnetic field mostly along the line of sight, down the length of embedded spiral arms. There is tentative evidence for a vertical field in the polarized emission off the plane of the disk.

AB - Stratospheric Observatory for Infrared Astronomy High-resolution Airborne Wideband Camera Plus polarimetry at 154 μm is reported for the face-on galaxy M51 and the edge-on galaxy NGC 891. For M51, the polarization vectors generally follow the spiral pattern defined by the molecular gas distribution, the far-infrared (FIR) intensity contours, and other tracers of star formation. The fractional polarization is much lower in the FIR-bright central regions than in the outer regions, and we rule out loss of grain alignment and variations in magnetic field strength as causes. When compared with existing synchrotron observations, which sample different regions with different weighting, we find the net position angles are strongly correlated, the fractional polarizations are moderately correlated, but the polarized intensities are uncorrelated. We argue that the low fractional polarization in the central regions must be due to significant numbers of highly turbulent segments across the beam and along lines of sight in the beam in the central 3 kpc of M51. For NGC 891, the FIR polarization vectors within an intensity contour of 1500 are oriented very close to the plane of the galaxy. The FIR polarimetry is probably sampling the magnetic field geometry in NGC 891 much deeper into the disk than is possible with NIR polarimetry and radio synchrotron measurements. In some locations in NGC 891, the FIR polarization is very low, suggesting we are preferentially viewing the magnetic field mostly along the line of sight, down the length of embedded spiral arms. There is tentative evidence for a vertical field in the polarized emission off the plane of the disk.

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DO - 10.3847/1538-3881/abada8

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VL - 160

JO - Astronomical Journal

JF - Astronomical Journal

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ER -

HAWC+ Far-infrared Observations of the Magnetic Field Geometry in M51 and NGC 891

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