# Magnetic fields in molecular clouds: Limitations of the analysis of   Zeeman observations

**Authors:** R. Brauer, S. Wolf, S. Reissl, F. Ober

arXiv: 1703.02745 · 2017-05-10

## TL;DR

This study assesses the uncertainties in deriving magnetic field strengths from Zeeman observations in molecular clouds, finding that typical conditions do not significantly affect the analysis accuracy.

## Contribution

We simulate Zeeman splitting using 3D radiative transfer to quantify analysis uncertainties and provide correction factors for different spectral lines and species.

## Key findings

- Uncertainties are minimal for typical molecular cloud conditions.
- Density variations above typical levels have little impact on analysis accuracy.
- Velocity and magnetic field variations along the line-of-sight slightly increase uncertainty.

## Abstract

Context. Observations of Zeeman split spectral lines represent an important approach to derive the structure and strength of magnetic fields in molecular clouds. In contrast to the uncertainty of the spectral line observation itself, the uncertainty of the analysis method to derive the magnetic field strength from these observations is not been well characterized so far.   Aims. We investigate the impact of several physical quantities on the uncertainty of the analysis method, which is used to derive the line-of-sight (LOS) magnetic field strength from Zeeman split spectral lines.   Methods. We simulate the Zeeman splitting of the 1665 MHz OH line with the 3D radiative transfer (RT) extension ZRAD. This extension is based on the line RT code Mol3D (Ober et al. 2015) and has been developed for the POLArized RadIation Simulator POLARIS (Reissl et al. 2016).   Results. Observations of the OH Zeeman effect in typical molecular clouds are not significantly affected by the uncertainty of the analysis method. We derived an approximation to quantify the range of parameters in which the analysis method works sufficiently accurate and provide factors to convert our results to other spectral lines and species as well. We applied these conversion factors to CN and found that observations of the CN Zeeman effect in typical molecular clouds are neither significantly affected by the uncertainty of the analysis method. In addition, we found that the density has almost no impact on the uncertainty of the analysis method, unless it reaches values higher than those typically found in molecular clouds. Furthermore, the uncertainty of the analysis method increases, if both the gas velocity and the magnetic field show significant variations along the line-of-sight. However, this increase should be small in Zeeman observations of most molecular clouds considering typical velocities of ~1 km/s.

## Full text

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## Figures

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## References

47 references — full list in the complete paper: https://tomesphere.com/paper/1703.02745/full.md

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Source: https://tomesphere.com/paper/1703.02745