Linear Polarization of Class I Methanol Masers in Massive Star-Forming Regions

Kang, Ji-hyun; Byun, Do-Young; Kim, Kee‐Tae; Kim, Jong-Soo; Lyo, A-Ran; Vlemmings, Wouter

doi:10.3847/0067-0049/227/2/17

Cited by 18 publications

(18 citation statements)

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“…Wiebe & Watson (1998) found that in masers with strong linear polarization, changes in the orientation of the magnetic field along the line of sight could cause rotation of the linear polarization vector to produce circular polarization. Observing with the Korean VLBI network telescopes in single dish mode, Kang et al (2016) measured (2.0±0.2) % linear polarization in the 44 GHz CH 3 OH masers toward DR21W. Given this low value, it is unlikely that linear polarization is causing the observed Stokes V in our observations.…”

Section: Discussionmentioning

confidence: 62%

The Zeeman Effect in the 44 GHz Class I Methanol (CH₃OH) Maser Line toward DR21W

Momjian¹,

Sarma

2019

ApJ

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We report the detection of the Zeeman effect in the 44 GHz Class I methanol maser line toward the high mass star forming region DR21W. There are two prominent maser spots in DR21W at the ends of a northwest-southeast linear arrangement. For the maser at the northwestern end (maser A), we fit three Gaussian components. In the strongest component, we obtain a significant Zeeman detection, with zB los = −23.4 ± 3.2 Hz. If we use z = −0.920 Hz mG −1 for the F = 5 → 4 hyperfine transition, this corresponds to a magnetic field |B los | = 25.4 mG; B los would be higher if a different hyperfine was responsible for the 44 GHz maser, but our results also rule out some hyperfines, since fields in these regions cannot be hundreds of mG. Class I methanol masers form in outflows where shocks compress magnetic fields in proportion to gas density. Designating our detected B los = 25 mG as the magnetic field in the post-shock gas, we find that B los in the pre-shock gas should be 0.1-0.8 mG. Although there are no thermal-line Zeeman detections toward DR21W, such values are in good agreement with Zeeman measurements in the CN thermal line of 0.36 and 0.71 mG about 3.5 away in DR21(OH) in gas of comparable density to the pre-shock gas density in DR21W. Comparison of our derived magnetic energy density to the kinetic energy density in DR21W indicates that magnetic fields likely play a significant role in shaping the dynamics of the post-shocked gas in DR21W.

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Section: Discussionmentioning

confidence: 62%

The Zeeman Effect in the 44 GHz Class I Methanol (CH₃OH) Maser Line toward DR21W

Momjian¹,

Sarma

2019

ApJ

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“…They argue that the masers are unsaturated and that the theory of Nedoluha and Watson (1992) applies; specifically that the linear polarization arises from anisotropic pumping and anisotropic radiation losses and the circular polarization from non-Zeeman effects (Watson, 2009). Kang et al (2016) present a survey of linear polarization in 44 GHz and 95 GHz Class I masers conducted with a single dish from the Korean VLBI Network (KVN). Their results yielded a lower fractional linear polarization and they argue accordingly for a diminished influence of anisotropic pumping and losses than Wiesemeyer et al (2004).…”

Section: Ghz and 44 Ghz Methanol Masersmentioning

confidence: 99%

“…There remain broad open questions in both the micophysics and macrophysics of star formation theory (McKee and Ostriker, 2007). Maser polarization observations in SFR probe the fine-scale magnetic field in dense regions n ∼ 10 5−11 cm −3 of obscured HMSFR (Kang et al, 2016) and therefore provide constraints on the theory of high-mass as opposed to low-mass star formation (Zinnecker and Yorke, 2007). In addition, masers are confined to certain evolutionary phases of HMSF, specifically between the formation of hot dense molecular cores (HDMC) (Zinnecker and Yorke, 2007), equivalently highmass protostellar objects (HMPO) (McKee and Ostriker, 2007), and their subsequent evolution into ultra-compact HII regions (UCHII) (Churchwell, 2002).…”

Section: Relationship Of Maser Polarization Observations To Star Formmentioning

confidence: 99%

Review of Zeeman Effect Observations of Regions of Star Formation

Crutcher

Kemball

2019

Front. Astron. Space Sci.

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The Zeeman effect is the only observational technique available to measure directly the strength of magnetic fields in regions of star formation. This chapter reviews the physics of the Zeeman effect and its practical use in both extended gas and in masers. We discuss observational results for the five species for which the Zeeman effect has been detected in the interstellar medium -H I, OH, and CN in extended gas and OH, CH 3 OH, and H 2 O in masers. These species cover a wide range in density, from ∼ 10 cm −3 to ∼ 10 10 cm −3 , which allows magnetic fields to be measured over the full range of cloud densities. However, there are significant limitations, including that only the line-of-sight component of the magnetic field strength can usually be measured and that there are often significant uncertainties about the physical conditions being sampled, particularly for masers. We discuss statistical methods to partially overcome these limitations. The results of Zeeman observations are that the mass to magnetic flux ratio, which measures the relative importance of gravity to magnetic support, is subcritical (gravity dominates magnetic support) at lower densities but supercritical for N H 10 22 cm −2 . Above n H ∼ 300 cm −3 , which is roughly the density at which clouds typically become self-gravitating, the strength of magnetic fields increases approximately as B ∝ n 2/3 , which suggest that magnetic fields do not provide significant support at high densities. This is consistent with high-density clouds being supercritical. However, magnetic fields have a large range in strengths at any given density, so the role of magnetic fields should differ significantly from one cloud to another. And for maser regions the dependence of field strength on density may have a slightly lower slope. Turbulent reconnection theory seems to best match the Zeeman observational results.

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“…In this paper, we report on single-dish measurements of linear polarisation toward 44 and 95 GHz methanol maser sources. The full results are published in Kang et al (2016). We also report on the preliminary results of follow-up VLBI observations, especially on the G10.34-0.14.…”

Section: Introductionmentioning

confidence: 97%

Linear polarisation of Class I methanol masers in massive star formation regions

Kang¹,

Byun²,

Kim³

et al. 2017

Proc. IAU

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We present the results of the linear polarisation observations of methanol masers at 44 and 95 GHz towards 39 massive star forming regions (Kanget al.2016). These two lines are observed simultaneously with the 21-m Korean VLBI Network (KVN) telescope in single dish mode. About 60% of the observed showed fractional polarisation of a few percents at least at one of the two transition lines. We note that the linear polarisation of the 44 GHz methanol maser is first detected in this study including single dish and interferometer observations. We find the polarisation properties of these two lines are similar as expected, since they trace similar regions. As a follow-up study, we have carried out the VLBI polarisation observations toward some 44 GHz maser targets using the KVN telescope. We present preliminary VLBI polarisation results of G10.34-0.14, which show consistent polarisation properties in multiple epoch observations.

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Linear Polarization of Class I Methanol Masers in Massive Star-Forming Regions

Cited by 18 publications

References 50 publications

The Zeeman Effect in the 44 GHz Class I Methanol (CH₃OH) Maser Line toward DR21W

The Zeeman Effect in the 44 GHz Class I Methanol (CH₃OH) Maser Line toward DR21W

Review of Zeeman Effect Observations of Regions of Star Formation

Linear polarisation of Class I methanol masers in massive star formation regions

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Linear Polarization of Class I Methanol Masers in Massive Star-Forming Regions

Cited by 18 publications

References 50 publications

The Zeeman Effect in the 44 GHz Class I Methanol (CH3OH) Maser Line toward DR21W

The Zeeman Effect in the 44 GHz Class I Methanol (CH3OH) Maser Line toward DR21W

Review of Zeeman Effect Observations of Regions of Star Formation

Linear polarisation of Class I methanol masers in massive star formation regions

Contact Info

Product

Resources

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The Zeeman Effect in the 44 GHz Class I Methanol (CH₃OH) Maser Line toward DR21W

The Zeeman Effect in the 44 GHz Class I Methanol (CH₃OH) Maser Line toward DR21W