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Main Authors: Shane, Brandon, Burkhart, Blakesley, Fissel, Laura, Clark, Susan E., Mocz, Philip, Foley, Michael M.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.10286
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author Shane, Brandon
Burkhart, Blakesley
Fissel, Laura
Clark, Susan E.
Mocz, Philip
Foley, Michael M.
author_facet Shane, Brandon
Burkhart, Blakesley
Fissel, Laura
Clark, Susan E.
Mocz, Philip
Foley, Michael M.
contents The characterization of magnetic fields within molecular clouds is fundamental to understanding star formation processes. Accurately gauging the three-dimensional structure of these fields presents a challenge, as observational techniques such as dust polarization and the Zeeman effect each provide only partial information on the orientation and line-of-sight strength, respectively. By analyzing a suite of AREPO simulations, this paper investigates how observables can relate to underlying physical properties to derive a more comprehensive picture of the magnetic field's inclination angle and strength, specifically in regions where both dust polarization and Zeeman data are available. To demonstrate the method, we produce synthetic observations of the polarization angle dispersion and line-of-sight Alfvén Mach Number and explore the behavior of the inclination angle, $γ$, and strength of the magnetic field in regions where both Zeeman and dust polarization data are available. We find that dust polarization data can be used to determine the inclination angle if the cloud is known to be trans-Alfvénic or sub-Alfvénic. The strength of the magnetic field relative to turbulence can be estimated by comparing polarization observations to Zeeman observations. Comparing the dispersion of the polarization angle to the estimated line-of-sight Alfvén Mach Number provides clues about the strength of the magnetic field and, consequently, the orientation of the magnetic field.
format Preprint
id arxiv_https___arxiv_org_abs_2411_10286
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Tracing 3-D Magnetic Field Structure Using Dust Polarization and the Zeeman Effect
Shane, Brandon
Burkhart, Blakesley
Fissel, Laura
Clark, Susan E.
Mocz, Philip
Foley, Michael M.
Astrophysics of Galaxies
Solar and Stellar Astrophysics
The characterization of magnetic fields within molecular clouds is fundamental to understanding star formation processes. Accurately gauging the three-dimensional structure of these fields presents a challenge, as observational techniques such as dust polarization and the Zeeman effect each provide only partial information on the orientation and line-of-sight strength, respectively. By analyzing a suite of AREPO simulations, this paper investigates how observables can relate to underlying physical properties to derive a more comprehensive picture of the magnetic field's inclination angle and strength, specifically in regions where both dust polarization and Zeeman data are available. To demonstrate the method, we produce synthetic observations of the polarization angle dispersion and line-of-sight Alfvén Mach Number and explore the behavior of the inclination angle, $γ$, and strength of the magnetic field in regions where both Zeeman and dust polarization data are available. We find that dust polarization data can be used to determine the inclination angle if the cloud is known to be trans-Alfvénic or sub-Alfvénic. The strength of the magnetic field relative to turbulence can be estimated by comparing polarization observations to Zeeman observations. Comparing the dispersion of the polarization angle to the estimated line-of-sight Alfvén Mach Number provides clues about the strength of the magnetic field and, consequently, the orientation of the magnetic field.
title Tracing 3-D Magnetic Field Structure Using Dust Polarization and the Zeeman Effect
topic Astrophysics of Galaxies
Solar and Stellar Astrophysics
url https://arxiv.org/abs/2411.10286