Resolved magnetic structures in the disk-halo interface of NGC 628

Mulcahy, D. D.; Beck, Rainer; Heald, G.

doi:10.1051/0004-6361/201629907

Cited by 41 publications

(62 citation statements)

References 92 publications

(200 reference statements)

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“…The largest difference is found in M 31. For individual magnetic arms, p o was found to be larger than p s by about 20 • in M 83 [173], about 8 • in M 101 [174], and 12 • − 23 • for the three main arms in M 74 [171]. This could indicate that anisotropic turbulent fields, responsible for a significant fraction of the polarized emission, have a systematically larger pitch angle than the regular field.…”

Section: Galaxymentioning

confidence: 90%

Synthesizing Observations and Theory to Understand Galactic Magnetic Fields: Progress and Challenges

et al. 2019

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Constraining dynamo theories of magnetic field origin by observation is indispensable but challenging, in part because the basic quantities measured by observers and predicted by modelers are different. We clarify these differences and sketch out ways to bridge the divide. Based on archival and previously unpublished data, we then compile various important properties of galactic magnetic fields for nearby spiral galaxies. We consistently compute strengths of total, ordered, and regular fields, pitch angles of ordered and regular fields, and we summarize the present knowledge on azimuthal modes, field parities, and the properties of non-axisymmetric spiral features called magnetic arms. We review related aspects of dynamo theory, with a focus on mean-field models and their predictions for large-scale magnetic fields in galactic discs and halos. Further, we measure the velocity dispersion of H I gas in arm and inter-arm regions in three galaxies, M 51, M 74, and NGC 6946, since spiral modulation of the root-mean-square turbulent speed has been proposed as a driver of non-axisymmetry in large-scale dynamos. We find no evidence for such a modulation and place upper limits on its strength, helping to narrow down the list of mechanisms to explain magnetic arms. Successes and remaining challenges of dynamo models with respect to explaining observations are briefly summarized, and possible strategies are suggested. With new instruments like the Square Kilometre Array (SKA), large data sets of magnetic and non-magnetic properties from thousands of galaxies will become available, to be compared with theory.

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Section: Galaxymentioning

confidence: 90%

Synthesizing Observations and Theory to Understand Galactic Magnetic Fields: Progress and Challenges

et al. 2019

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“…Similar results have been seen in the disk of the face-on galaxy, NGC 628, as shown in Figs. 18 and 26 of Mulcahy et al (2017) and also more recently in the disk of the edge-on galaxy, NGC 4666 (Stein et al 2019). For the latter galaxy, the field direction also flips across the major axis of the galaxy.…”

Section: Introductionmentioning

confidence: 94%

“…However it is becoming common place to give the Faraday depth by RM synthesis for nearly face-on galaxies (e.g. Beck 2015b; Mulcahy et al 2017). Thus in this section we give a preliminary RM screen analysis of essentially the same model used in the previous section.…”

Section: Rm Screen For Face-on Galaxiesmentioning

confidence: 99%

Evolving galactic dynamos and fits to the reversing rotation measures in the halo of NGC 4631

Woodfinden

Henriksen

Irwin

et al. 2019

Monthly Notices of the Royal Astronomical Society

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Rotation measure (RM) synthesis maps of NGC 4631 show remarkable sign reversals with distance from the minor axis in the northern halo of the galaxy on kpc scales. To explain this new phenomenon, we solve the dynamo equations under the assumption of scale invariance and search for rotating logarithmic spiral solutions. Solutions for velocity fields representing accretion onto the disk, outflow from the disk, and rotationonly in the disk are found that produce RM with reversing signs viewed edge-on. Model RM maps are created for a variety of input parameters using a Faraday screen and are scaled to the same amplitude as the observational maps. Residual images are then made and compared to find a best fit. Solutions for rotation-only, i.e. relative to a pattern uniform rotation, did in general, not fit the observations of NGC 4631 well. However, outflow models did provide a reasonable fit to the magnetic field. The best results for the specific region that was modelled in the northern halo are found with accretion. Since there is abundant evidence for both winds and accretion in NGC 4631, this modelling technique has the potential to distinguish between the dominant flows in galaxies.

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“…On the other hand, we take B coh as a free parameter, varying its value to see the effects on the Faraday spectrum. Recent RM studies of face-on external galaxies such as IC 342 (Beck 2009) and NGC 628 (Mulcahy et al 2017) indicated absolute values of the RM up to ∼100 rad m −2 , which corresponds to up to ∼6 μG if we assume that the average thermal electron density along the LOS is 0.02 cm −3 and the path length through the thermal gas is 1 kpc. So, we set B coh = 0-5 μG.…”

mentioning

confidence: 96%

Study of the Vertical Magnetic Field in Face-on Galaxies Using Faraday Tomography

Ideguchi

Tashiro

Akahori

et al. 2017

ApJ

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Faraday tomography allows astronomers to probe the distribution of the magnetic field along the line of sight (LOS), but that can be achieved only after the Faraday spectrum is interpreted. However, the interpretation is not straightforward, mainly because the Faraday spectrum is complicated due to a turbulent magnetic field; it ruins the one-to-one relation between the Faraday depth and the physical depth, and appears as many small-scale features in the Faraday spectrum. In this paper, by employing "simple toy models" for the magnetic field, we describe numerically as well as analytically the characteristic properties of the Faraday spectrum. We show that the Faraday spectrum along "multiple LOSs" can be used to extract the global properties of the magnetic field. Specifically, considering face-on spiral galaxies and modeling turbulent magnetic field as a random field with a single coherence length, we numerically calculate the Faraday spectrum along a number of LOSs and its shape-characterizing parameters, that is, the moments. When multiple LOSs cover a region of (10 coherence length) 2 , the shape of the Faraday spectrum becomes smooth and the shape-characterizing parameters are well specified. With the Faraday spectrum constructed as a sum of Gaussian functions with different means and variances, we analytically show that the parameters are expressed in terms of the regular and turbulent components of the LOS magnetic field and the coherence length. We also consider the turbulent magnetic field modeled with a power-law spectrum, and study how the magnetic field is revealed in the Faraday spectrum. Our work suggests a way to obtain information on the magnetic field from a Faraday tomography study.

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Resolved magnetic structures in the disk-halo interface of NGC 628

Cited by 41 publications

References 92 publications

Synthesizing Observations and Theory to Understand Galactic Magnetic Fields: Progress and Challenges

Synthesizing Observations and Theory to Understand Galactic Magnetic Fields: Progress and Challenges

Evolving galactic dynamos and fits to the reversing rotation measures in the halo of NGC 4631

Study of the Vertical Magnetic Field in Face-on Galaxies Using Faraday Tomography

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