A FAR-INFRARED OBSERVATIONAL TEST OF THE DIRECTIONAL DEPENDENCE IN RADIATIVE GRAIN ALIGNMENT

• Published in: Astrophysical journal. Letters Vol. 812; no. 1; pp. L7 - 6
• Main Authors: Vaillancourt, John E., Andersson, B.-G.
• Format: Journal Article
• Language: English
• Published: United States The American Astronomical Society 10.10.2015
• Subjects: Alignment; ANISOTROPY; ASTROPHYSICS, COSMOLOGY AND ASTRONOMY; CLOUDS; COMPARATIVE EVALUATIONS; dust, extinction; EFFICIENCY; FAR INFRARED RADIATION; Grains; INTERSTELLAR MAGNETIC FIELDS; INTERSTELLAR SPACE; ISM: individual objects (OMC-1); ISM: magnetic fields; Magnetic fields; MORPHOLOGY; ORIENTATION; POLARIZATION; PROBABILITY; Rotation; Spinning; STARS; submillimeter: ISM; TORQUE
• ISSN: 2041-8205; 2041-8213; 2041-8213
• DOI: 10.1088/2041-8205/812/1/L7

ABSTRACT The alignment of interstellar dust grains with magnetic fields provides a key method for measuring the strength and morphology of the fields. In turn, this provides a means to study the role of magnetic fields from diffuse gas to dense star-forming regions. The physical mechanism for aligning the grains has been a long-term subject of study and debate. The theory of radiative torques, in which an anisotropic radiation field imparts sufficient torques to align the grains while simultaneously spinning them to high rotational velocities, has passed a number of observational tests. Here we use archival polarization data in dense regions of the Orion molecular cloud (OMC-1) at 100, 350, and 850 m to test the prediction that the alignment efficiency is dependent upon the relative orientations of the magnetic field and radiation anisotropy. We find that the expected polarization signal, with a 180-degree period, exists at all wavelengths out to radii of 1.5 arcmin centered on the Becklin-Neugebauer Kleinmann-Low (BNKL) object in OMC-1. The probabilities that these signals would occur due to random noise are low ( 1%), and are lowest toward BNKL compared to the rest of the cloud. Additionally, the relative magnetic field to radiation anisotropy directions accord with theoretical predictions in that they agree to better than 15° at 100 m and 4° at 350 m.