Magnetic field traces gas and dust swirling around supermassive black hole

Astronomers reveal a new high resolution map of the magnetic field lines in gas and dust swirling around the supermassive black hole at the centre of our Galaxy, published in a new paper in Monthly Notices of the Royal Astronomical Society. The team, led by Professor Pat Roche of the University of Oxford, created the map, which is the first of its kind, using the CanariCam infrared camera attached to the Gran Telescopio Canarias sited on the island of La Palma.

Black holes are objects with gravitational fields so strong that not even light can escape their grasp. The centre of almost every galaxy appears to host a black hole, and the one we live in, the Milky Way, is no exception. Stars move around the black hole at speeds of up to 30 million kilometres an hour, indicating that it has a mass of more than a million times our Sun.

Visible light from sources in the centre of the Milky Way is blocked by clouds of gas and dust. Infrared light, as well as X-rays and radio waves, passes through this obscuring material, so astronomers use this to see the region more clearly. CanariCam combines infrared imaging with a polarising device, which preferentially filters light with the particular characteristics associated with magnetic fields.

The new infrared map covers a region about 1 light year on each side of the supermassive black hole. The map shows the intensity of infrared light, and traces magnetic field lines within filaments of warm dust grains and hot gas, which appear as thin lines reminiscent of brush strokes in a painting.

The filaments, several light years long, appear to meet close to the black hole (at a point below centre in the map), and may indicate where orbits of streams of gas and dust converge. One prominent feature links some of the brightest stars in the centre of the Galaxy. Despite the strong winds flowing from these stars, the filaments remain in place, bound by the magnetic field within them. Elsewhere the magnetic field is less clearly aligned with the filaments. Depending on how the material flows, some of it may eventually be captured and engulfed by the black hole.

The new observations give astronomers more detailed information on the relationship between the bright stars and the dusty filaments. The origin of the magnetic field in this region is not understood, but it is likely that a smaller magnetic field is stretched out as the filaments are elongated by the gravitational influence of the black hole and stars in the galactic centre.

Roche praises the new technique and the result: “Big telescopes like GTC, and instruments like CanariCam, deliver real results. We’re now able to watch material race around a black hole 25,000 light years away, and for the first time see magnetic fields there in detail.”

The team are using CanariCam to probe magnetic fields in dusty regions in our galaxy. They hope to obtain further observations of the Galactic Centre to investigate the larger scale magnetic field and how it links to the clouds of gas and dust orbiting the black hole further out at distances of several light years.
 


Media contacts

Dr Robert Massey
Royal Astronomical Society
Tel: +44 (0)20 7292 3979
Mob: +44 (0)7802 877699
press@ras.ac.uk
 

Dr Helen Klus
Royal Astronomical Society
Tel: +44 (0)20 7292 3976
press@ras.ac.uk
 


Science contact

Professor Pat Roche
University of Oxford
pat.roche@physics.ox.ac.uk
 


Image and caption

 

The colour scale in the image shows the amount of infrared (heat) radiation coming from warm dust particles in the filaments and luminous stars within a light year of the Galactic centre. The position of the black hole is indicated by an asterisk. The lines trace the magnetic field directions and reveal the complex interactions between the stars and the dusty filaments, and the impact that they and the gravitational force has on them. The observations were made with the largest telescope in Europe, which allowed details of the fine structure in the magnetic fields to be revealed for the first time. 

Credit: E. Lopez-Rodriguez / NASA Ames / University of Texas at San Antonio
 


Further information

The new work appears in: "The Magnetic Field in the central parsec of the Galaxy", P.F. Roche, E. Lopez-Rodriguez, C.M. Telesco, R. Schödel, C. Packham, Monthly Notices of the Royal Astronomical Society (2018), in press (DOI: 10.1093/mnras/sty129).

A copy of the paper is available from: https://doi.org/10.1093/mnras/sty129
 

The magnetic field directions are indicated by the polarisation produced in infrared light emitted from billions of tiny spinning elongated dust particles. These become aligned to the weak magnetic field that threads through the gas in which they are embedded.

Polarised light in this instance is produced because the emitting grains are elongated and aligned so that the emission along the long axis of the grains is greater than along the short axis, and when the spin is aligned to a magnetic field, the direction of the field threading through the emitting material can be traced.

Here polarisation is measured with the CanariCam instrument mounted on the Gran Telescopio Canarias (GTC). With a main mirror 10.4 metres in diameter, the GTC provides greater resolution than was possible with previous instruments, and reveals the fine details of the polarised structures for the first time. CanariCam was developed at the University of Florida by a team led by Prof Charles Telesco. It has unique capabilities for measuring polarisation at infrared wavelengths.
 


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