Observations of magnetic fields in the Milky Way and in nearby galaxies with a Square Kilometre Array

AbstractOne of the five key science projects for the Square Kilometre Array (SKA) is “The Origin and Evolution of Cosmic Magnetism”, in which radio polarimetry will be used to reveal what cosmic magnets look like and what role they have played in the evolving Universe. Many of the SKA prototypes now being built are also targeting magnetic fields and polarimetry as key science areas. Here I review the prospects for innovative new polarimetry and Faraday rotation experiments with forthcoming facilities such as ASKAP, LOFAR, the ATA, the EVLA, and ultimately the SKA. Sensitive wide-field polarisation surveys with these telescopes will provide a dramatic new view of magnetic fields in the Milky Way, in nearby galaxies and clusters, and in the high-redshift Universe.

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Magnetic fields in our Milky Way Galaxy and nearby galaxies

Proceedings of the International Astronomical Union ◽

10.1017/s1743921313002561 ◽

2012 ◽

Vol 8 (S294) ◽

pp. 213-224 ◽

Cited By ~ 4

Author(s):

JinLin Han

Keyword(s):

Star Formation ◽

Magnetic Fields ◽

Large Scale ◽

Milky Way ◽

Spiral Galaxies ◽

Large Scale Structure ◽

Scale Structure ◽

Measure Data ◽

Submillimeter Wavelength ◽

Nearby Galaxies

AbstractMagnetic fields in our Galaxy and nearby galaxies have been revealed by starlight polarization, polarized emission from dust grains and clouds at millimeter and submillimeter wavelength, the Zeeman effect of spectral lines or maser lines from clouds or clumps, diffuse radio synchrotron emission from relativistic electrons in interstellar magnetic fields, and the Faraday rotation of background radio sources as well as pulsars for our Milky Way. It is easy to get a global structure for magnetic fields in nearby galaxies, while we have observed many details of magnetic fields in our Milky Way, especially by using pulsar rotation measure data. In general, magnetic fields in spiral galaxies probably have a large-scale structure. The fields follow the spiral arms with or without the field direction reversals. In the halo of spiral galaxies magnetic fields exist and probably also have a large-scale structure as toroidal and poloidal fields, but seem to be slightly weaker than those in the disk. In the central region of some galaxies, poloidal fields have been detected as vertical components. Magnetic field directions in galaxies seem to have been preserved during cloud formation and star formation, from large-scale diffuse interstellar medium to molecular clouds and then to the cloud cores in star formation regions or clumps for the maser spots. Magnetic fields in galaxies are passive to dynamics.

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Measurements of Cosmic Magnetism with LOFAR and SKA

Advances in Radio Science ◽

10.5194/ars-5-399-2007 ◽

2007 ◽

Vol 5 ◽

pp. 399-405 ◽

Cited By ~ 9

Author(s):

R. Beck

Keyword(s):

Magnetic Fields ◽

Interstellar Medium ◽

Milky Way ◽

Intergalactic Medium ◽

Low Frequency ◽

Radio Telescopes ◽

New Era ◽

Origin And Evolution ◽

Central Regions ◽

Nearby Galaxies

Abstract. The origin of magnetic fields in stars, galaxies and clusters is an open problem in astrophysics. The next-generation radio telescopes Low Frequency Array (LOFAR) and Square Kilometre Array (SKA) will revolutionize the study of cosmic magnetism. "The origin and evolution of cosmic magnetism" is a key science project for SKA. The planned all-sky survey of Faraday rotation measures (RM) at 1.4 GHz will be used to model the structure and strength of the magnetic fields in the intergalactic medium, the interstellar medium of intervening galaxies, and in the Milky Way. A complementary survey of selected regions at around 200 MHz is planned as a key project for LOFAR. Spectro-polarimetry applied to the large number of spectral channels available for LOFAR and SKA will allow to separate RM components from distinct foreground and background regions and to perform 3-D Faraday tomography of the interstellar medium of the Milky Way and nearby galaxies. – Deep polarization mapping with LOFAR and SKA will open a new era also in the observation of synchrotron emission from magnetic fields. LOFAR's sensitivity will allow to map the structure of weak, extended magnetic fields in the halos of galaxies, in galaxy clusters, and possibly in the intergalactic medium. Polarization observations with SKA at higher frequencies (1–10 GHz) will show the detailed magnetic field structure within the disks and central regions of galaxies, with much higher angular resolution than present-day radio telescopes.

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Shaping Disk Galaxy Stellar Populations via Internal and External Processes

Proceedings of the International Astronomical Union ◽

10.1017/s1743921314011442 ◽

2012 ◽

Vol 10 (H16) ◽

pp. 372-372

Author(s):

Rok Roškar

Keyword(s):

Galaxy Formation ◽

Stellar Population ◽

Milky Way ◽

Stellar Populations ◽

Radial Migration ◽

Disk Formation ◽

Process Understanding ◽

History Of ◽

Nearby Galaxies ◽

Gas Accretion

AbstractIn recent years, effects such as the radial migration of stars in disks have been recognized as important drivers of the properties of stellar populations. Radial migration arises due to perturbative effects of disk structures such as bars and spiral arms, and can deposit stars formed in disks to regions far from their birthplaces. Migrant stars can significantly affect the demographics of their new locales, especially in low-density regions such as in the outer disks. However, in the cosmological environment, other effects such as mergers and filamentary gas accretion also influence the disk formation process. Understanding the relative importance of these processes on the detailed evolution of stellar population signatures is crucial for reconstructing the history of the Milky Way and other nearby galaxies. In the Milky Way disk in particular, the formation of the thickened component has recently attracted much attention due to its potential to serve as a diagnostic of the galaxy's early history. Some recent work suggests, however, that the vertical structure of Milky Way stellar populations is consistent with models that build up the thickened component through migration. I discuss these developments in the context of cosmological galaxy formation.

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Double X/Peanut Structures in Barred Galaxies – Insights from an N–body Simulation

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/staa3814 ◽

2020 ◽

Author(s):

Bogdan C Ciambur ◽

Francesca Fragkoudi ◽

Sergey Khoperskov ◽

Paola Di Matteo ◽

Françoise Combes

Keyword(s):

Dark Matter ◽

Milky Way ◽

Large Fraction ◽

Formation Time ◽

Dark Matter Halo ◽

Barred Galaxies ◽

Pattern Speed ◽

Nearby Galaxies ◽

Dynamical Instabilities ◽

Bow Tie

Abstract Boxy, peanut– or X–shaped “bulges” are observed in a large fraction of barred galaxies viewed in, or close to, edge-on projection, as well as in the Milky Way. They are the product of dynamical instabilities occurring in stellar bars, which cause the latter to buckle and thicken vertically. Recent studies have found nearby galaxies that harbour two such features arising at different radial scales, in a nested configuration. In this paper we explore the formation of such double peanuts, using a collisionless N–body simulation of a pure disc evolving in isolation within a live dark matter halo, which we analyse in a completely analogous way to observations of real galaxies. In the simulation we find a stable double configuration consisting of two X/peanut structures associated to the same galactic bar – rotating with the same pattern speed – but with different morphology, formation time, and evolution. The inner, conventional peanut-shaped structure forms early via the buckling of the bar, and experiences little evolution once it stabilises. This feature is consistent in terms of size, strength and morphology, with peanut structures observed in nearby galaxies. The outer structure, however, displays a strong X, or “bow-tie”, morphology. It forms just after the inner peanut, and gradually extends in time (within 1 to 1.5 Gyr) to almost the end of the bar, a radial scale where ansae occur. We conclude that, although both structures form, and are dynamically coupled to, the same bar, they are supported by inherently different mechanisms.

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Pulsar Science with the SKA

Proceedings of the International Astronomical Union ◽

10.1017/s1743921317009188 ◽

2017 ◽

Vol 13 (S337) ◽

pp. 158-164 ◽

Cited By ~ 1

Author(s):

Evan F. Keane

Keyword(s):

Milky Way ◽

Phase 1 ◽

Square Kilometre Array

AbstractThe Square Kilometre Array (SKA) will be sensitive enough to discover all of the pulsars in the Milky Way that are beamed towards Earth. Already in the initial deployment, SKA Phase 1, it will make significant advances in pulsar science. In these proceedings I briefly overview what the SKA is, and describe its pulsar search and timing capabilities.

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The dark matter interpretation of the 3.5-keV line is inconsistent with blank-sky observations

Science ◽

10.1126/science.aaw3772 ◽

2020 ◽

Vol 367 (6485) ◽

pp. 1465-1467 ◽

Cited By ~ 6

Author(s):

Christopher Dessert ◽

Nicholas L. Rodd ◽

Benjamin R. Safdi

Keyword(s):

Dark Matter ◽

Emission Line ◽

Decay Rate ◽

Milky Way ◽

Line Emission ◽

Mass Range ◽

Sterile Neutrinos ◽

X Ray ◽

Upper Limit ◽

Nearby Galaxies

Observations of nearby galaxies and galaxy clusters have reported an unexpected x-ray emission line around 3.5 kilo–electron volts (keV). Proposals to explain this line include decaying dark matter—in particular, that the decay of sterile neutrinos with a mass around 7 keV could match the available data. If this interpretation is correct, the 3.5-keV line should also be emitted by dark matter in the halo of the Milky Way. We used more than 30 megaseconds of XMM-Newton (X-ray Multi-Mirror Mission) blank-sky observations to test this hypothesis, finding no evidence of the 3.5-keV line emission from the Milky Way halo. We set an upper limit on the decay rate of dark matter in this mass range, which is inconsistent with the possibility that the 3.5-keV line originates from dark matter decay.

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Magnetism Science with the Square Kilometre Array

Galaxies ◽

10.3390/galaxies8030053 ◽

2020 ◽

Vol 8 (3) ◽

pp. 53

Author(s):

George Heald ◽

Sui Mao ◽

Valentina Vacca ◽

Takuya Akahori ◽

Ancor Damas-Segovia ◽

...

Keyword(s):

Magnetic Fields ◽

Large Scale ◽

Galactic Nuclei ◽

Dark Matter Annihilation ◽

New Techniques ◽

Square Kilometre Array ◽

New Radio ◽

Recent Developments ◽

Using Data ◽

The Impact

The Square Kilometre Array (SKA) will answer fundamental questions about the origin, evolution, properties, and influence of magnetic fields throughout the Universe. Magnetic fields can illuminate and influence phenomena as diverse as star formation, galactic dynamics, fast radio bursts, active galactic nuclei, large-scale structure, and dark matter annihilation. Preparations for the SKA are swiftly continuing worldwide, and the community is making tremendous observational progress in the field of cosmic magnetism using data from a powerful international suite of SKA pathfinder and precursor telescopes. In this contribution, we revisit community plans for magnetism research using the SKA, in light of these recent rapid developments. We focus in particular on the impact that new radio telescope instrumentation is generating, thus advancing our understanding of key SKA magnetism science areas, as well as the new techniques that are required for processing and interpreting the data. We discuss these recent developments in the context of the ultimate scientific goals for the SKA era.

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Probing the cold magnetised Universe with SPICA-POL (B-BOP)

Publications of the Astronomical Society of Australia ◽

10.1017/pasa.2019.20 ◽

2019 ◽

Vol 36 ◽

Cited By ~ 6

Author(s):

Ph. André ◽

A. Hughes ◽

V. Guillet ◽

F. Boulanger ◽

A. Bracco ◽

...

Keyword(s):

Magnetic Fields ◽

Dynamic Range ◽

Signal To Noise Ratio ◽

European Space Agency ◽

Dust Emission ◽

Far Infrared ◽

High Dynamic Range ◽

Wide Field ◽

Infrared Telescope ◽

Nearby Galaxies

Abstract Space Infrared Telescope for Cosmology and Astrophysics (SPICA), the cryogenic infrared space telescope recently pre-selected for a ‘Phase A’ concept study as one of the three remaining candidates for European Space Agency (ESA's) fifth medium class (M5) mission, is foreseen to include a far-infrared polarimetric imager [SPICA-POL, now called B-fields with BOlometers and Polarizers (B-BOP)], which would offer a unique opportunity to resolve major issues in our understanding of the nearby, cold magnetised Universe. This paper presents an overview of the main science drivers for B-BOP, including high dynamic range polarimetric imaging of the cold interstellar medium (ISM) in both our Milky Way and nearby galaxies. Thanks to a cooled telescope, B-BOP will deliver wide-field 100–350 $\mu$ m images of linearly polarised dust emission in Stokes Q and U with a resolution, signal-to-noise ratio, and both intensity and spatial dynamic ranges comparable to those achieved by Herschel images of the cold ISM in total intensity (Stokes I). The B-BOP 200 $\mu$ m images will also have a factor $\sim $ 30 higher resolution than Planck polarisation data. This will make B-BOP a unique tool for characterising the statistical properties of the magnetised ISM and probing the role of magnetic fields in the formation and evolution of the interstellar web of dusty molecular filaments giving birth to most stars in our Galaxy. B-BOP will also be a powerful instrument for studying the magnetism of nearby galaxies and testing Galactic dynamo models, constraining the physics of dust grain alignment, informing the problem of the interaction of cosmic rays with molecular clouds, tracing magnetic fields in the inner layers of protoplanetary disks, and monitoring accretion bursts in embedded protostars.

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Supershells

International Astronomical Union Colloquium ◽

10.1017/s0252921100102829 ◽

1988 ◽

Vol 101 ◽

pp. 447-459

Author(s):

Richard McCray

Keyword(s):

Star Formation ◽

Radio Emission ◽

Interstellar Medium ◽

Milky Way ◽

Disk Galaxy ◽

Interstellar Gas ◽

Irregular Galaxies ◽

Nearby Galaxies ◽

Gas Layer

AbstractRepeated supernovae from an OB association will, in a few ×107 yr, create a cavity of coronal gas in the interstellar medium, with radius > 100 pc, surrounded by a dense expanding shell of cool interstellar gas. Such a cavity will likely burst through the gas layer of a disk galaxy. Such holes and “supershells” have been observed in optical and H I radio emission maps of the Milky Way and other nearby galaxies. The gas swept up in the supershell is likely to become gravitationally unstable, providing a mechanism for propagating star formation that may be particularly effective in irregular galaxies.

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