OMC-1 dust polarization in ALMA Band 7: Diagnosing grain alignment mechanisms in the vicinity of Orion Source I

Kate Pattle; Shih Ping Lai; Melvyn Wright; Simon Coudé; Richard Plambeck; Thiem Hoang; Ya Wen Tang; Pierre Bastien; Chakali Eswaraiah; Ray S. Furuya; Jihye Hwang; Shu Ichiro Inutsuka; Kee Tae Kim; Florian Kirchschlager; Woojin Kwon; Chang Won Lee; Sheng Yuan Liu; Aran Lyo; Nagayoshi Ohashi; Mark G. Rawlings; Mehrnoosh Tahani; Motohide Tamura; Archana Soam; Jia Wei Wang; Derek Ward-Thompson

doi:10.1093/mnras/stab608

OMC-1 dust polarization in ALMA Band 7: Diagnosing grain alignment mechanisms in the vicinity of Orion Source I

Kate Pattle, Shih Ping Lai, Melvyn Wright, Simon Coudé, Richard Plambeck, Thiem Hoang, Ya Wen Tang, Pierre Bastien, Chakali Eswaraiah, Ray S. Furuya, Jihye Hwang, Shu Ichiro Inutsuka, Kee Tae Kim, Florian Kirchschlager, Woojin Kwon, Chang Won Lee, Sheng Yuan Liu, Aran Lyo, Nagayoshi Ohashi, Mark G. RawlingsMehrnoosh Tahani, Motohide Tamura, Archana Soam, Jia Wei Wang, Derek Ward-Thompson

Physics

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Abstract

We present ALMA Band 7 polarization observations of the OMC-1 region of the Orion molecular cloud. We find that the polarization pattern observed in the region is likely to have been significantly altered by the radiation field of the >10⁴ L。 high-mass protostar Orion Source I. In the protostar’s optically thick disc, polarization is likely to arise from dust self-scattering. In material to the south of Source I – previously identified as a region of ‘anomalous’ polarization emission – we observe a polarization geometry concentric around Source I. We demonstrate that Source I’s extreme luminosity may be sufficient to make the radiative precession time-scale shorter than the Larmor time-scale for moderately large grains (> 0.005–0.1 μm), causing them to precess around the radiation anisotropy vector (k-RATs) rather than the magnetic field direction (B-RATs). This requires relatively unobscured emission from Source I, supporting the hypothesis that emission in this region arises from the cavity wall of the Source I outflow. This is one of the first times that evidence for k-RAT alignment has been found outside of a protostellar disc or AGB star envelope. Alternatively, the grains may remain aligned by B-RATs and trace gas infall on to the Main Ridge. Elsewhere, we largely find the magnetic field geometry to be radial around the BN/KL explosion centre, consistent with previous observations. However, in the Main Ridge, the magnetic field geometry appears to remain consistent with the larger-scale magnetic field, perhaps indicative of the ability of the dense Ridge to resist disruption by the BN/KL explosion.

Original language	English
Pages (from-to)	3414-3433
Number of pages	20
Journal	Monthly Notices of the Royal Astronomical Society
Volume	503
Issue number	3
DOIs	https://doi.org/10.1093/mnras/stab608
Publication status	Published - 1 May 2021

Keywords

ISM: dust, extinction
ISM: magnetic fields
Stars: formation
Submillimetre: ISM
Techniques: polarimetric

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10.1093/mnras/stab608

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Pattle, K., Lai, S. P., Wright, M., Coudé, S., Plambeck, R., Hoang, T., Tang, Y. W., Bastien, P., Eswaraiah, C., Furuya, R. S., Hwang, J., Inutsuka, S. I., Kim, K. T., Kirchschlager, F., Kwon, W., Lee, C. W., Liu, S. Y., Lyo, A., Ohashi, N., ... Ward-Thompson, D. (2021). OMC-1 dust polarization in ALMA Band 7: Diagnosing grain alignment mechanisms in the vicinity of Orion Source I. Monthly Notices of the Royal Astronomical Society, 503(3), 3414-3433. https://doi.org/10.1093/mnras/stab608

@article{dc5f5d7c015b4d64bad77d82d9bb2956,

title = "OMC-1 dust polarization in ALMA Band 7: Diagnosing grain alignment mechanisms in the vicinity of Orion Source I",

abstract = "We present ALMA Band 7 polarization observations of the OMC-1 region of the Orion molecular cloud. We find that the polarization pattern observed in the region is likely to have been significantly altered by the radiation field of the >104 L。 high-mass protostar Orion Source I. In the protostar{\textquoteright}s optically thick disc, polarization is likely to arise from dust self-scattering. In material to the south of Source I – previously identified as a region of {\textquoteleft}anomalous{\textquoteright} polarization emission – we observe a polarization geometry concentric around Source I. We demonstrate that Source I{\textquoteright}s extreme luminosity may be sufficient to make the radiative precession time-scale shorter than the Larmor time-scale for moderately large grains (> 0.005–0.1 μm), causing them to precess around the radiation anisotropy vector (k-RATs) rather than the magnetic field direction (B-RATs). This requires relatively unobscured emission from Source I, supporting the hypothesis that emission in this region arises from the cavity wall of the Source I outflow. This is one of the first times that evidence for k-RAT alignment has been found outside of a protostellar disc or AGB star envelope. Alternatively, the grains may remain aligned by B-RATs and trace gas infall on to the Main Ridge. Elsewhere, we largely find the magnetic field geometry to be radial around the BN/KL explosion centre, consistent with previous observations. However, in the Main Ridge, the magnetic field geometry appears to remain consistent with the larger-scale magnetic field, perhaps indicative of the ability of the dense Ridge to resist disruption by the BN/KL explosion.",

keywords = "ISM: dust, extinction, ISM: magnetic fields, Stars: formation, Submillimetre: ISM, Techniques: polarimetric",

author = "Kate Pattle and Lai, {Shih Ping} and Melvyn Wright and Simon Coud{\'e} and Richard Plambeck and Thiem Hoang and Tang, {Ya Wen} and Pierre Bastien and Chakali Eswaraiah and Furuya, {Ray S.} and Jihye Hwang and Inutsuka, {Shu Ichiro} and Kim, {Kee Tae} and Florian Kirchschlager and Woojin Kwon and Lee, {Chang Won} and Liu, {Sheng Yuan} and Aran Lyo and Nagayoshi Ohashi and Rawlings, {Mark G.} and Mehrnoosh Tahani and Motohide Tamura and Archana Soam and Wang, {Jia Wei} and Derek Ward-Thompson",

note = "Publisher Copyright: {\textcopyright} 2021 The Author(s). Published by Oxford University Press on behalf of Royal Astronomical SocietyPublished by Oxford University Press on behalf of Royal Astronomical Society.",

year = "2021",

month = may,

day = "1",

doi = "10.1093/mnras/stab608",

language = "English",

volume = "503",

pages = "3414--3433",

journal = "Monthly Notices of the Royal Astronomical Society",

issn = "0035-8711",

number = "3",

}

Pattle, K, Lai, SP, Wright, M, Coudé, S, Plambeck, R, Hoang, T, Tang, YW, Bastien, P, Eswaraiah, C, Furuya, RS, Hwang, J, Inutsuka, SI, Kim, KT, Kirchschlager, F, Kwon, W, Lee, CW, Liu, SY, Lyo, A, Ohashi, N, Rawlings, MG, Tahani, M, Tamura, M, Soam, A, Wang, JW & Ward-Thompson, D 2021, 'OMC-1 dust polarization in ALMA Band 7: Diagnosing grain alignment mechanisms in the vicinity of Orion Source I', Monthly Notices of the Royal Astronomical Society, vol. 503, no. 3, pp. 3414-3433. https://doi.org/10.1093/mnras/stab608

TY - JOUR

T1 - OMC-1 dust polarization in ALMA Band 7

T2 - Diagnosing grain alignment mechanisms in the vicinity of Orion Source I

AU - Pattle, Kate

AU - Lai, Shih Ping

AU - Wright, Melvyn

AU - Coudé, Simon

AU - Plambeck, Richard

AU - Hoang, Thiem

AU - Tang, Ya Wen

AU - Bastien, Pierre

AU - Eswaraiah, Chakali

AU - Furuya, Ray S.

AU - Hwang, Jihye

AU - Inutsuka, Shu Ichiro

AU - Kim, Kee Tae

AU - Kirchschlager, Florian

AU - Kwon, Woojin

AU - Lee, Chang Won

AU - Liu, Sheng Yuan

AU - Lyo, Aran

AU - Ohashi, Nagayoshi

AU - Rawlings, Mark G.

AU - Tahani, Mehrnoosh

AU - Tamura, Motohide

AU - Soam, Archana

AU - Wang, Jia Wei

AU - Ward-Thompson, Derek

N1 - Publisher Copyright: © 2021 The Author(s). Published by Oxford University Press on behalf of Royal Astronomical SocietyPublished by Oxford University Press on behalf of Royal Astronomical Society.

PY - 2021/5/1

Y1 - 2021/5/1

N2 - We present ALMA Band 7 polarization observations of the OMC-1 region of the Orion molecular cloud. We find that the polarization pattern observed in the region is likely to have been significantly altered by the radiation field of the >104 L。 high-mass protostar Orion Source I. In the protostar’s optically thick disc, polarization is likely to arise from dust self-scattering. In material to the south of Source I – previously identified as a region of ‘anomalous’ polarization emission – we observe a polarization geometry concentric around Source I. We demonstrate that Source I’s extreme luminosity may be sufficient to make the radiative precession time-scale shorter than the Larmor time-scale for moderately large grains (> 0.005–0.1 μm), causing them to precess around the radiation anisotropy vector (k-RATs) rather than the magnetic field direction (B-RATs). This requires relatively unobscured emission from Source I, supporting the hypothesis that emission in this region arises from the cavity wall of the Source I outflow. This is one of the first times that evidence for k-RAT alignment has been found outside of a protostellar disc or AGB star envelope. Alternatively, the grains may remain aligned by B-RATs and trace gas infall on to the Main Ridge. Elsewhere, we largely find the magnetic field geometry to be radial around the BN/KL explosion centre, consistent with previous observations. However, in the Main Ridge, the magnetic field geometry appears to remain consistent with the larger-scale magnetic field, perhaps indicative of the ability of the dense Ridge to resist disruption by the BN/KL explosion.

AB - We present ALMA Band 7 polarization observations of the OMC-1 region of the Orion molecular cloud. We find that the polarization pattern observed in the region is likely to have been significantly altered by the radiation field of the >104 L。 high-mass protostar Orion Source I. In the protostar’s optically thick disc, polarization is likely to arise from dust self-scattering. In material to the south of Source I – previously identified as a region of ‘anomalous’ polarization emission – we observe a polarization geometry concentric around Source I. We demonstrate that Source I’s extreme luminosity may be sufficient to make the radiative precession time-scale shorter than the Larmor time-scale for moderately large grains (> 0.005–0.1 μm), causing them to precess around the radiation anisotropy vector (k-RATs) rather than the magnetic field direction (B-RATs). This requires relatively unobscured emission from Source I, supporting the hypothesis that emission in this region arises from the cavity wall of the Source I outflow. This is one of the first times that evidence for k-RAT alignment has been found outside of a protostellar disc or AGB star envelope. Alternatively, the grains may remain aligned by B-RATs and trace gas infall on to the Main Ridge. Elsewhere, we largely find the magnetic field geometry to be radial around the BN/KL explosion centre, consistent with previous observations. However, in the Main Ridge, the magnetic field geometry appears to remain consistent with the larger-scale magnetic field, perhaps indicative of the ability of the dense Ridge to resist disruption by the BN/KL explosion.

KW - ISM: dust, extinction

KW - ISM: magnetic fields

KW - Stars: formation

KW - Submillimetre: ISM

KW - Techniques: polarimetric

UR - http://www.scopus.com/inward/record.url?scp=85107314341&partnerID=8YFLogxK

U2 - 10.1093/mnras/stab608

DO - 10.1093/mnras/stab608

M3 - Article

AN - SCOPUS:85107314341

SN - 0035-8711

VL - 503

SP - 3414

EP - 3433

JO - Monthly Notices of the Royal Astronomical Society

JF - Monthly Notices of the Royal Astronomical Society

IS - 3

ER -

OMC-1 dust polarization in ALMA Band 7: Diagnosing grain alignment mechanisms in the vicinity of Orion Source I

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Keywords

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