The JCMT BISTRO Survey: Multi-wavelength polarimetry of bright regions   in NGC 2071 in the far-infrared/submillimetre range, with POL-2 and HAWC+

L. Fanciullo (1); F. Kemper (1; 2); K. Pattle (3); P. M. Koch (1),; S. Sadavoy (4); S. Coud\'e (5); A. Soam (5; 6); T. Hoang (7); T. Onaka (8; and 9); V. J. M. Le Gouellec (5; 10); D. Arzoumanian (11; 12); D. Berry; (13); C. Eswaraiah (14; 15); E. J. Chung (16); R. Furuya (17); C. L. H.; Hull (18; 19); J. Hwang (7; 20); D. Johnstone (21; 22); J.-h. Kang; (7); K. H. Kim (7); F. Kirchschlager (23); V. K\"onyves (24); J. Kwon (9); W.; Kwon (25; 26); S.-P. Lai (27); C. W. Lee (7; 20); T. Liu (28); A.-R.; Lyo (7); I. Stephens (29; 30); M. Tamura (9; 12; 31); X. Tang (32),; D. Ward-Thompson (24); A. Whitworth (33); H. Shinnaga (34) ((1) Academia; Sinica Institute of Astronomy; Astrophysics; (2) European Southern; Observatory; (3) Centre for Astronomy; School of Physics; National University; of Ireland Galway; (4) Department for Physics; Engineering Physics and; Astrophysics; Queen's University; (5) SOFIA Science Center; Universities; Space Research Association; NASA Ames Research Center; (6) Indian Institute; of Astrophysics; (7) Korea Astronomy; Space Science Institute; (8); Department of Physics; Faculty of Science; Engineering; Meisei University,; (9) Department of Astronomy; Graduate School of Science; The University of; Tokyo; (10) Universit\'e Paris-Saclay; CNRS; CEA; Astrophysique,; Instrumentation et Mod\'elisation de Paris-Saclay; (11) Aix Marseille Univ,; CNRS; CNES; LAM; (12) National Astronomical Observatory of Japan; Mitaka,; Tokyo; (13) East Asian Observatory; (14) CAS Key Laboratory of FAST; National; Astronomical Observatories; Chinese Academy of Sciences; (15) Indian; Institute of Science Education; Research; (16) Department of Astronomy and; Space Science; Chungnam National University; (17) Tokushima University; (18); National Astronomical Observatory of Japan; Santiago; Chile; (19) Joint ALMA; Observatory; (20) University of Science; Technology; Korea (UST); (21) NRC; Herzberg Astronomy; Astrophysics; (22) Department of Physics and; Astronomy; University of Victoria; (23) Department of Physics; Astronomy,; University College London; (24) Jeremiah Horrocks Institute; University of; Central Lancashire; (25) Department of Earth Science Education; Seoul; National University; (26) SNU Astronomy Research Center; Seoul National; University; (27) Institute of Astronomy; Department of Physics; National; Tsing Hua University; (28) Key Laboratory for Research in Galaxies and; Cosmology; Shanghai Astronomical Observatory; Chinese Academy of Sciences,; (29) Department of Earth; Environment; and Physics; Worcester State; University; (30) Center for Astrophysics | Harvard & Smithsonian; (31); Astrobiology Center; National Institutes of Natural Sciences (32) Xinjiang; Astronomical Observatory; Chinese Academy of Sciences; (33) School of Physics; and Astronomy; Cardiff University; (34) Department of Physics; Astronomy,; Graduate School of Science; Engineering; Kagoshima University)

arXiv:2209.09604·astro-ph.GA·September 21, 2022

The JCMT BISTRO Survey: Multi-wavelength polarimetry of bright regions in NGC 2071 in the far-infrared/submillimetre range, with POL-2 and HAWC+

L. Fanciullo (1), F. Kemper (1, 2), K. Pattle (3), P. M. Koch (1),, S. Sadavoy (4), S. Coud\'e (5), A. Soam (5, 6), T. Hoang (7), T. Onaka (8, and 9), V. J. M. Le Gouellec (5, 10), D. Arzoumanian (11, 12), D. Berry, (13), C. Eswaraiah (14, 15), E. J. Chung (16), R. Furuya (17)

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TL;DR

This study demonstrates that multi-wavelength polarimetry using HAWC+ and POL-2 reveals complex magnetic field structures and dust properties in NGC 2071, highlighting the importance of combining data across wavelengths for star formation studies.

Contribution

The paper provides new insights into magnetic field morphology and dust grain behavior by analyzing multi-wavelength polarimetry data, revealing limitations of current dust models and the need for combined wavelength approaches.

Findings

01

Polarization angle varies significantly with wavelength, indicating complex magnetic field structures.

02

Standard methods using monochromatic intensity can produce misleading results.

03

Multi-wavelength polarimetry is essential for understanding dust and magnetic fields in molecular clouds.

Abstract

Polarized dust emission is a key tracer in the study of interstellar medium and of star formation. The observed polarization, however, is a product of magnetic field structure, dust grain properties and grain alignment efficiency, as well as their variations in the line of sight, making it difficult to interpret polarization unambiguously. The comparison of polarimetry at multiple wavelengths is a possible way of mitigating this problem. We use data from HAWC+/SOFIA and from SCUBA-2/POL-2 (from the BISTRO survey) to analyse the NGC 2071 molecular cloud at 154, 214 and 850 $μ$ m. The polarization angle changes significantly with wavelength over part of NGC 2071, suggesting a change in magnetic field morphology on the line of sight as each wavelength best traces different dust populations. Other possible explanations are the existence of more than one polarization mechanism in the cloud…

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