Cosmic brick factory

The reconstructed image of the dusty disk (left) around the young star HD 163296, derived from the MATISSE observations. The false-colour image shows the thermal radiation from the disk at infrared wavelengths. The observations revealed a strong asymmetry which presents itself as a bright clump located at the upper right part in the image. A vortex concentrating material in a horseshoe-shaped region in the inner disk (to the right) could be causing this asymmetry. It orbits the central star at a distance similar to that of Mercury revolving around the Sun.  Credit: Jozsef Varga (Leiden Observatory), Heloise Meheut (CNRS/Lagrange) 

A new instrument reveals the site for planet birth aroud a young star

Studying the formation of planets close to their host stars by observations has been extremely challenging so far. As part of an international collaboration, scientists - among others from the Max Planck Institutes for Astronomy and for Radioastronomy - have employed a new instrument called MATISSE which has now uncovered evidence for a vortex at the inner rim of a planet-forming disk around a young star. It appears to move on an orbit around its star similar to Mercury’s orbit around the Sun. Astronomers think such vortices are sites where small particles converge and grow to form planets’ building blocks. Max Planck researchers contributed considerably to building MATISSE, an infrared imager for ESO’s Very Large Telescope Interferometer.

Astronomers have discovered more than 4000 planets orbiting stars other than the Sun. However, scientists still have to figure out the details of how those planets form from the disks made of dust and gas that surround their parent stars. During recent years, sophisticated instrumentation has provided close-up views on such planet-forming disks. However, they generally lack the angular resolution and sensitivity to probe the disks’ inner regions where terrestrial planets are supposed to emerge from rocky building blocks that eventually grow from tiny dust grains.

An extensive collaboration of scientists led by Jozsef Varga from Leiden Observatory (The Netherlands) have now managed to overcome those limits by utilising a new instrument called MATISSE (Multi AperTure mid-Infrared SpectroScopic Experiment). The observations were made with essential contributions by astronomers of the Max Planck Institutes for Astronomy (MPIA) and for Radioastronomy (MPIfR). At infrared wavelengths these observations provide evidence for a vortex embedded inside a ring of hot dust at the inner edge of the protoplanetary disk of the young star HD 163296. The potential vortex revealed itself as a hot spot that produces an asymmetry at the disk’s inner edge. The scientists inferred that it revolves around the star roughly within a month by including published data. Its trajectory resides at a distance from the central star comparable to Mercury’s orbit around the Sun.

Theoretical calculations have predicted the occurrence of vortices in disks, where material swirls around like a tornado and accumulates dust. “The higher dust density induces faster grain growth than anywhere else in the disk, which may render those whirls to be efficient factories to produce the building blocks of future planets,” Roy van Boekel explains. He leads the Protoplanetary Disk Science Group and manages the MATISSE project at MPIA. Some of the newly formed rocky bricks collide under high speeds which causes grinding of the material to tiny grains. They can attain higher temperatures than larger pebbles which is the likely origin of the hot spot found in the data.

Group photo of the MATISSE team next to a MATISSE instrument cryostat.

Credit: Michael Lehmitz (MPIA) 

This spectacular result will appear in the scientific journal Astronomy & Astrophysics as the MATISSE team’s first scientific publication. “MATISSE is a new infrared instrument for the VLTI (Very Large Telescope Interferometer) which the European Southern Observatory (ESO) operates at its Paranal site in Chile,” Michael Lehmitz, an engineer at MPIA says. “MPIA contributed to an international consortium that designed and built MATISSE by integrating the delicate optics into a cryostat that cools them down to -235° C.” Subsequent low-temperature performance tests were also carried out at MPIA. MATISSE combines the light collected from up to four individual VLT units, performing spectroscopic and imaging observations. With such a design, the facility simulates the imaging power of a telescope of up to 200 metres in diameter, capable of producing the most detailed images ever at mid-infrared wavelengths.

“We explicitly designed MATISSE to probe the inner zones of exoplanet-forming disks that have not been accessible before by available astronomical instrumentation,” Thomas Henning, director at MPIA and Co-PI of MATISSE points out. “I am proud and excited that the discovery of a potential vortex in the disk of HD 163296 demonstrates that we can investigate the processes that produce Earth-like planets at small distances from the host star.”

The study presented here belongs to an extensive Guaranteed Time Observation (GTO) program, which investigates the planet-forming mechanisms in the inner zones of protoplanetary disks. Over the next few years, the GTO program will study many more systems like HD 163296. This way, it will improve our understanding of how the formation of Earth-like planets proceeds around a wide variety of young stars.

"This first scientific result marks the starting point for further research. One of the goals is to study stars with dust disks and specifically those in which Earth-like planets can form," says Gerd Weigelt, director at MPIfR, who led a long involvement in the development of MATISSE as head of the Infrared Interferometry Research Group at the institute.

 

Source: Max Planck Institute for Radio Astronomy

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Contact

Dr. Markus Nielbock
Press and public relations officer
Phone:+49 6221 528-134
Max Planck Institute for Astronomy, Heidelberg

Dr. Norbert Junkes
Press and public relations
Phone:+49 2 28525-399
Max Planck Institute for Radio Astronomy, Bonn

Dr. Roy van Boekel
Head of Protoplanetary Disk Science Group
Phone:+49 6221 528-405
Max Planck Institute for Astronomy, Heidelberg

Prof. Dr. Thomas K. Henning
Director
Phone:+49 6221 528-200
Max Planck Institute for Astronomy, Heidelberg

Prof. Dr. Gerd Weigelt
Director
Phone:+49 228 525-243
Max Planck Institute for Radio Astronomy, Bonn

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Original publication

1. J. Varga, M. Hogerheijde, R. van Boekel et al.

The asymmetric inner disk of the Herbig Ae star HD 163296 in the eyes of VLTI/MATISSE: evidence for a vortex?
Astronomy & Astrophysics (2021)
DOI

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MATISSE sees first light at ESO´s Paranal Observatory in Chile
MPIA Institute announcement from 5 March 2018

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Links

MATISSE

Description of the MATISSE-Instrument

MATISSE

Online manual of the MATISSE instrument

Very Large Telescope Interferometer (VLTI)
 

Description of the VLT(I)

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A three-dimensional view of the Milky Way

Colourful variety: The section shows interstellar clouds in a small area of about 5% of the total SEDIGISM mapping; each of these clouds is coloured differently. The small picture in the upper left diagrams the course of the spiral arms in the Milky Way. The grey region marks the complete area of the SEDIGISM mapping. In this illustration, the direction of the sector is light blue. Ana Duarte-Cabral, Alex Pettitt, and James Urquhart

The Apex telescope makes it possible to observe molecular clouds and star births in the galactic plane

December 03, 2020 In our Milky Way, there are about 200 billion suns as well as large quantities of gas, some of which serves as raw material for star births. The gas collects in compact lumps but also appears as extended molecular clouds. Astronomers have used the Apex sub-millimetre telescope in Chile to look deep into the galactic plane and measure the interstellar medium. They studied the distribution of the cold molecular gas in the inner region of the Milky Way with unprecedented accuracy. The researchers catalogued more than 10,000 interstellar clouds. They found out that currently only about 10% of them contain stars. The project is called SEDIGISM (Structure, Excitation and Dynamics of the Inner Galactic Interstellar Medium) and covers an area of 84 square degrees in the southern sky.

The mapping contains data from 2013 to 2017, which was collected by the 12-metre Apex telescope in the Chilean Andes. “With the publication of this most detailed map of cold molecular clouds in the Milky Way to date, a long-term observation project is now coming to fruition”, says Frederic Schuller from the Max Planck Institute for Radio Astronomy, the project leader of SEDIGISM.

Scientists have been able to observe the southern part of the inner Milky Way with an angular resolution of 30 arcseconds; this corresponds to ¹⁄₆₀ of the apparent diameter of the full moon in the Earth’s sky. They have also gained valuable information on structure, distance, and velocity for all galactic molecular clouds in about two thirds of the inner disc of the Milky Way.

The researchers observed the spectral lines of the carbon monoxide molecule – including the rare isotopes ¹³CO and C¹⁸O – and deduced the mass and three-dimensional distribution of cold and dense molecular gas in the interstellar medium. Various structures such as filaments and recesses were found; these are the result of different physical effects.

Molecular clouds contain the raw material from which new stars are formed. The mapping of these clouds is therefore necessary to determine important parameters such as the efficiency of star formation in the Milky Way. Structures and physical conditions within the clouds provide the fundamental basis for the theories of star formation. It is therefore important to spatially resolve the individual clouds and distinguish them from each other.

One key to the success was the 12-metre Apex telescope with its highly accurate surface and one of the world’s best locations for sub-millimetre astronomy. The instrument is located at an altitude of 5100 meters on the Chajnantor Plain in the Chilean Atacama Desert. Here, there is extremely low water vapour content and thus excellent transparency of the atmosphere.

The new data complement a series of mappings of the galactic plane produced in the mid to far infra-red wavelength range over the past decade. This was done with space telescopes such as the Spitzer, Herschel, and – for longer wavelengths – the Apex itself. However, these projects lacked the speed information that SEDIGISM has now provided. The re-analysis of the data allows a more detailed study of star formation – and thus of the structure and dynamics of the Milky Way itself.

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Contact

 

Dr. Norbert Junkes

Press and public relations

Phone:+49 2 28525-399

Max Planck Institute for Radio Astronomy, Bonn

Dr. Friedrich Wyrowski

Phone:+49 228 525381

Max Planck Institute for Radio Astronomy, Bonn

Dr. Dario Colombo

Phone:+49 228 525-196

Max Planck Institute for Radio Astronomy, Bonn

 

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Original Publication

 

1. F. Schuller et al.

The SEDIGISM survey: first data release and overview of the Galactic structure

Monthly Notices of the Royal Astronomical Society, 26. November 2020

DOI

 

2. A. Duarte-Cabral et al.

The SEDIGISM survey: Molecular clouds in the inner Galaxy

Monthly Notices of the Royal Astronomical Society, 26. November 2020

DOI

 

3. J. S. Urquhart et al.

SEDIGISM-ATLASGAL: Dense Gas Fraction and Star Formation Efficiency across the Galactic Disk

Monthly Notices of the Royal Astronomical Society, 26. November 2020

DOI 

 Source:  Max Planck Institute for Radio Astronomy

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A Spiral Galaxy with a Huge Magnetic Field

The spiral galaxy NGC 4217 has a huge magnetic field, that is shown here as green lines. The radio data for this visualisation were recorded with the Karl G. Jansky Very Large Array (VLA). The image of the galaxy shown from the side is taken from data from the Sloan Digital Sky Survey and Kitt Peak National Observatory. © Composite image: Y. Stein, with the support of J. English. VLA radio data: Y. Stein & R.-J. Dettmar as part of CHANG-ES led by J. Irwin. Optical data: SDSS. Ionised hydrogen (in red): R. Rand (0.9m KPNO telescope). Software code: A. Miskolczi & Y. Stein (adapted from Linear Integral Convolution code).

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New cosmic magnetic field structures discovered in the galaxy NGC 4217

Superbubbles, giant loops and X-shaped magnetic field structures – this galaxy boasts a veritable wealth of shapes. How such structures are formed is a mystery. Some clues are provided by a new study led by Yelena Stein within the framework of the CHANG-ES project (“Continuum HAlos in Nearby Galaxies -- an EVLA Survey”). Rainer Beck, a scientist from the Max Planck Institute for Radio Astronomy (MPIfR) in Bonn, Germany, participated in the study. For a comprehensive image of the magnetic field structures, the researchers combined different methods that enabled them to visualise the ordered and chaotic magnetic fields of the galaxy both along the line of sight and perpendicular to it.

The results are published online in the journal  "Astronomy & Astrophysics" on July 21, 2020.

Spiral galaxies such as our Milky Way can have sprawling magnetic fields. There are various theories about their formation, but so far the process is not well understood. An international research team has now analysed the magnetic field of the Milky Way-like galaxy NGC 4217 in detail on the basis of radio astronomical observations and has discovered as yet unknown magnetic field structures. The data suggest that star formation and star explosions, so-called supernovae, are responsible for the visible structures.

The analysed data had been compiled in the project “Continuum Halos in Nearby Galaxies”, where radio waves were utilised to measure 35 galaxies. “Galaxy NGC 4217 is of particular interest to us,” explains Yelena Stein, who began the study at the Chair of Astronomy at Ruhr-Universität Bochum under Professor Ralf-Jürgen Dettmar and who currently works at the Centre de Données astronomiques de Strasbourg. NGC 4217 is similar to the Milky Way and is only about 67 million light years away, which means relatively close to it, in the Ursa Major constellation. The researchers therefore hope to successfully transfer some of their findings to our home galaxy.

Magnetic fields and origins of star formation

When evaluating the data from NGC 4217, the researchers found several remarkable structures. The galaxy has an X-shaped magnetic field structure, which has also been observed in other galaxies, extending far outwards from the galaxy disk, namely over 20,000 light years.

In addition to the X-shape, the team found a helix structure and two large bubble structures, also called superbubbles. The latter originate from places where many massive stars explode as supernovae, but also where stars are formed that emit stellar winds in the process. Researchers therefore suspect a connection between these phenomena.

“It is fascinating that we discover unexpected phenomena in every galaxy whenever we use radio polarisation measurements,” points out Rainer Beck from MPIfR in Bonn, one of the authors of the study. “Here in NGC 4217, it is huge magnetic gas bubbles and a helix magnetic field that spirals upwards into the galaxy’s halo.”

The analysis moreover revealed large loop structures in the magnetic fields along the entire galaxy. “This has never been observed before,” explains Yelena Stein. “We suspect that the structures are caused by star formation, because at these points matter is thrown outward.”

Image shows magnetic field structures

For their analysis, the researchers combined different methods that enabled them to visualise the ordered and chaotic magnetic fields of the galaxy both along the line of sight and perpendicular to it. The result was a comprehensive image of the structures.

To optimise the results, Yelena Stein combined the data evaluated by means of radio astronomy with an image of NGC 4217 that was taken in the visible light range. “Visualising the data was important to me,” stresses Stein. “Because when you think about galaxies, magnetic fields is not the first thing that comes to mind, although they can be gigantic and display unique structures. The image is supposed to shift the magnetic fields more into focus.”

Source: Max Planck Institute for  Radio Astronomy/News

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Background Information

CHANG-ES: the “Continuum Halos in Nearby Galaxies, an EVLA Survey” project brings together scientists from all over the globe in order to investigate the occurrence and origin of galaxy halos by means of radio observations.

Image Composition: Composite image by Yelena Stein of the Centre de Données astronomiques de Strasbourg (CDS) with the support of Jayanne English (University of Manitoba). VLA radio data from Yelena Stein and Ralf-Jürgen Dettmar (Ruhr University Bochum). The observations are part of the project Continuum Halos in Nearby Galaxies – an EVLA Survey (CHANG-ES) led by Judith Irwin (Queen’s University, Canada). The optical data are from the Sloan Digital Sky Survey. The ionised hydrogen data (red) are from the 0.9m telescope of the Kitt Peak National Observatory, collected by Richard J. Rand of the University of New Mexico. The software code for tracing the magnetic field lines was adapted from the Linear Integral Convolution code provided by Arpad Miskolczi of Ruhr University.

Funding: The research was funded by the Hans Böckler Foundation and the German Research Foundation (DFG Research Unit 1254). Data were received from the Sloan Digital Sky Survey III – financed by the Alfred P. Sloan Foundation and participating institutions, the National Science Foundation (NSF) and the Office of Science of the U.S. Department of Energy (DOE) – and from the Wide-field Infrared Survey Explorer (WISE) – financed by the National Aeronautics and Space Administration (NASA). The National Radio Astronomy Observatory (NRAO) is a facility of the NSF, operated under cooperative agreement by Associated Universities, Inc.

The team from the Ruhr-Universität Bochum, the Centre de Données astronomiques de Strasbourg and the Max Planck Institute for Radio Astronomy in Bonn, together with US-American and Canadian colleagues, published their report in the journal Astronomy and Astrophysics, released online on 21 July 2020. The research team consists of Yelena Stein, Ralf-Jürgen Dettmar, Rainer Beck, Judith Irwin, Theresa Wiegert, Arpad Miskolczi, Q. Daniel Wang, Jayanne English, Richard Henriksen, Michael Radica and Jiangtao Li. Rainer Beck is affiliated with the MPIfR.

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Contact

Dr. Rainer Beck
Phone:+49 228 525-313
Max-Planck-Institut für Radioastronomie, Bonn

Dr. Yelena Stein
Centre de Données astronomiques de Strasbourg, Université de Strasbourg, France.

Prof. Dr. Ralf-Jürgen Dettmar
Phone:+49 234 3223-454
Fakultät für Physik und Astronomie, Ruhr-Universität Bochum

Dr. Norbert Junkes
Press and Public Outreach
Phone:+49 228 525-399
Max-Planck-Institut für Radioastronomie, Bonn

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Original Paper

CHANG-ES XXI. Transport processes and the X-shaped magnetic field of NGC 4217: off-center superbubble structure

Y. Stein et al., Astronomy & Astrophysics (July 21, 2020). DOI: 10.1051/0004-6361/202037675

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Links

Fundamental Physics in Radio Astronomy

Research Department "Fundamental Physics in Radio Astronomy" at MPIfR, Bonn, Germany

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CHANG-ES
Continuum Halos in Nearby Galaxies, an EVLA Survey (CHANG-ES)

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NRAO
National Radio Astronomy Observatory (NRAO)

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VLA
Karl G. Jansky Very Large Array (VLA)

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SDSS
Sloan Digital Sky Survey (SDSS)

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RUB, Chair of Astronomy
Chair of Astronomy, Ruhr-Universität Bochum (RUB)

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CDS
Centre de Données astronomiques de Strasbourg (CDS)

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Galactic Magnetic Fields
Scholarpedia article "Galactic Magnetic Fields" by Rainer Beck/MPIfR

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Parallel Press Releases and Image Releases

Magnetic field of a spiral Galaxy
NRAO Image Release, 21 July 2020

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New cosmic magnetic field structures discovered in galaxy NGC 4217

RUB Press Release, 21 July 2020

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Magnetic Field of a Spiral Galaxy

Observatoire astronomique de Strasbourg Press Release, 21 July 2020

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Globular cluster billowing in the Galactic wind

Globular cluster 47 Tuc (upper right) and the Small Magellanic Cloud in the same field-of-view. The inset is a close-up of the cluster showing the detected magnetic field in a colour scale. The lines indicate the effect of the Galactic wind on the magnetic field. © ESO/VISTA VMC (background image); F. Abbate et al., Nature Astronomy (inset)

Investigation of pulsars in 47 Tuc provides constraints on the magnetic field in the halo of the Milky Way

March 02, 2020. The Galactic magnetic field plays an important role in the evolution of our Galaxy, but its small-scale behaviour is still poorly known. It is also unknown whether it permeates the halo of the Galaxy or not. By using observations of pulsars in the halo globular cluster 47 Tuc, an international research team led by Federico Abbate from the Max Planck Institute for Radio Astronomy in Bonn, Germany who started this work at University of Milano Bicocca and INAF-Astronomical Observatory of Cagliari, could probe the Galactic magnetic field at scales of a few light years for the first time. They discovered an unexpected strong magnetic field in the direction of the cluster. This magnetic field points perpendicularly to the Galactic disk and could be explained by an interaction with the Galactic wind. This is a magnetized outflow that extends from the Galactic disk into the surrounding halo and its existence has never been proven before.

47 Tucanae, or 47 Tuc as it is usually called, is a spectacular globular cluster visible with the naked eye in the constellation “Tucana” in the southern sky close to the Small Magellanic Cloud. The first pulsar in this cluster was discovered in 1990 with the Parkes 64-m radio telescope in Australia, and soon more were found with the same telescope. Currently there are 25 pulsars known in 47 Tuc. For this reason, this very well-studied globular cluster became one of the most important for pulsar astronomers as well.

Pulsars are periodic sources that allow astronomers to measure the so-called dispersion measure which is a delay of the arrival time of the single pulses at different frequencies. This delay is proportional to the density of free electrons along the path from the pulsar to the Earth. “In 2001, we noticed that the pulsars in the far side of the cluster had a higher dispersion measure than those in the near side, which implied the presence of gas in the cluster”, says Paulo Freire from the Max Planck Institute for Radio Astronomy (MPIfR) who led a number of research projects on 47 Tuc.

What makes 47 Tuc even more interesting is that the cluster is at a distance of about 15,000 light years, located in a relatively undisturbed area in the Galactic halo. The halo surrounds the Galactic disk and hosts very few stars and very small quantities of gas. “The pulsars in this cluster can give us a unique and unprecedented insight into the large-scale geometry of the magnetic field in the Galactic halo.” says Federico Abbate, lead author of the paper and now working at MPIfR, who performed the analysis during his PhD at the University of Milano-Bicocca and at INAF - Cagliari Astronomical Observatory.

Understanding the geometry and strength of Galactic magnetic fields is essential to draw a complete picture of our Galaxy. The magnetic fields can affect star formation, regulate the propagation of high-energy particles and help establish the presence of a Galactic scale outflow of gas from the disk to the surrounding halo. Despite their importance, the large-scale geometry of the magnetic fields in the Galactic halo is not fully known.

Magnetic fields are not observable directly, but scientists make use of the effects they have on the low-density plasma that permeates the Galactic disk. In this plasma, the electrons are separated from the atomic nuclei and they behave like small magnets. The electrons are attracted by the magnetic field and are forced to orbit the magnetic field lines, emitting radiation known as synchrotron radiation. Other than emitting their own radiation, the free electrons also leave a peculiar signature on the polarized radiation that travels through the plasma. The electromagnetic field of the polarized radiation oscillates always in the same direction and the electrons in a magnetized medium will rotate this direction by different amounts at different frequencies. This effect is called Faraday rotation and is measurable only at radio frequencies.

Observations of polarized radio emission work well to constrain the magnetic field in the Galactic disk where the plasma is dense enough. In the Galactic halo, however, the plasma density is too low to directly observe the effects. For this reason, the geometry and strength of the magnetic field in the halo is unknown and models predict that it could either be parallel or perpendicular to the disk. The presence of a magnetized outflow from the disk to the halo has been suggested following observations in other galaxies. It can also explain the diffuse X-ray emission in the Galaxy.

Recent observations of the pulsars in 47 Tuc, also performed with the Parkes radio telescope in Australia, were able to measure their polarized radio emission and their Faraday rotation. These reveal the presence of a magnetic field in the globular cluster that is surprisingly strong - so strong, in fact, that it cannot be maintained by the globular cluster itself but requires an external source located in the Galactic halo. The direction of the magnetic field is compatible with that of the Galactic wind, perpendicular to the Galactic disk. The interaction of the Galactic wind and the cluster forms a shock that amplifies the magnetic field to the values observed.

This work reveals a new technique to study the magnetic field in the Galactic halo. This cluster is a perfect target for observations with the innovative MeerKAT radio telescope in South Africa. “In the near future, the MeerKAT telescope will greatly improve the polarization measurements and possibly not only confirm the presence of the Galactic wind but also constrain its properties,” says Andrea Possenti from the INAF – Cagliari Astronomical Observatory who is involved in the globular cluster pulsars efforts with MeerKAT together with the MPIfR. Moreover, this powerful telescope in particular with its further development towards the Square Kilometre Array (SKA) has the capabilities to observe other globular clusters in the halo and corroborate the results.

The results are published in this week’s issue of „Nature Astronomy“.

Source: Max Planck Institute for Radio Astronomy/News

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The research team consists of Federico Abbate, Andrea Possenti, Caterina Tiburzi, Ewan Barr, Willem van Straten, Alessandro Ridolfi and Paulo Freire. The first author, Federico Abbate, is now at the MPIfR. Co-authors Ewan Barr and Paulo Freire are both affiliated with the MPIfR.

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Original Paper

Constraints on the magnetic field in the Galactic halo from globular cluster pulsars 

F. Abbate et al., Nature Astronomy, 02 March 2020. DOI: 10.1038/s41550-020-1030-6.

The URL will become valid after the embargo expires on Monday, March 02, 19:00 CET (13:00 US EST).

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Links

Fundamental Physics in Radio Astronomy
Research Department "Fundamental Physics in Radio Astronomy" at MPIfR, Bonn, Germany

Parkes
CSIRO Parkes Observatory

Millisecond Pulsars in 47 Tuc 
Information on millisecond pulsars in globular cluster 47 Tuc (Website Paulo Freire)

MeerKAT
South African MeerKAT radio telescope

SKA Observatory 
Square Kilometre Array Observatory

Pulsar Dispersion Measure 
Website "Pulsar Dispersion Measure" at Swinburne University, Australia

Cosmic Magnetism
Website "Cosmic Magnetism" at Square Kilometre Array (SKA)

Galactic Magnetic Fields
Scholarpedia article "Galactic Magnetic Fields" by Rainer Beck/MPIfR

Pulsars in 47 Tuc (Movie)

Ensemble of pulsars in 47 Tuc: movie simulation with pulsar sounds (Jodrell Bank; Andrew Lyne & Michael Kramer; 40 MB)

Pulsars in 47 Tuc (Audio file)

Sounds of an ensemble of millisecond pulsars in 47 Tuc. Audio file (Jodrell Bank; Andrew Lyne & Michael Kramer)

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A Repeating Fast Radio Burst from a Spiral Galaxy

Image of the host galaxy of the Fast Radio Burst (FRB) 180916.J0158+65 as seen with the Gemini-North telescope. The position of the FRB is marked. The inset is a higher-contrast zoom-in of the star-forming region containing the FRB (marked by the red circle). © B. Marcote et al, Nature 2020

Localisation of a new, recurring source of radio flashes deepens the mystery of their origins

The Effelsberg 100-m radio telescope participated in the European VLBI Network (EVN) to observe a repeating Fast Radio Burst (FRB) and helped to pinpoint the FRB to a spiral galaxy similar to our own. Crucial to this work was the sensitivity of the Effelsberg telescope and its flexible pulsar instrument that aided the quick radio localisation. This FRB is the closest to Earth ever localised and was found in a radically different environment to previous studies. The discovery, once again, changes researchers’ assumptions on the origins of these mysterious extragalactic events.

The results are reported in the current issue of the journal Nature by an international team of scientists including Ramesh Karuppusamy from the Max Planck Institute for Radio Astronomy in Bonn, Germany.

One of the greatest mysteries in astronomy right now is the origin of short, dramatic bursts of radio light seen across the universe, known as Fast Radio Bursts or FRBs. Although they last for only a thousandth of a second, there are now hundreds of records of these enigmatic sources. However, from these records, the precise location is known for just four FRBs - they are said to be ‘localised’.

In 2016, one of these four sources was observed to repeat, with bursts originating from the same region in the sky in a non-predictable way. This resulted in researchers drawing distinctions between FRBs where only a single burst of light was observed (‘non-repeating’) and those where multiple bursts of light were observed (‘repeating’).

“The multiple flashes that we witnessed in the first repeating FRB arose from very particular and extreme conditions inside a very tiny (dwarf) galaxy”, says Benito Marcote, from the Joint Institute for VLBI ERIC, the lead author of the current study. “This discovery represented the first piece of the puzzle but it also raised more questions than it solved, such as whether there was a fundamental difference between repeating and non-repeating FRBs. Now, we have localised a second repeating FRB, which challenges our previous ideas on what the source of these bursts could be.”

On 19th June 2019, eight telescopes from the European VLBI Network (EVN) simultaneously observed a radio source known as FRB 180916.J0158+65. This source was originally discovered in 2018 by the CHIME telescope in Canada, which enabled the team to conduct a very high resolution observation with the EVN in the direction of FRB 180916.J0158+65. During five hours of observations the researchers detected four bursts, each lasting for less than two thousandths of a second. The resolution reached through the combination of the telescopes across the globe, using a technique known as Very Long Baseline Interferometry (VLBI), meant that the bursts could be precisely localised to a region of approximately only seven light years across. This localisation is comparable to an individual on Earth being able to distinguish a person on the Moon.

The Effelsberg 100-m radio telescope of the Max Planck institute for Radio Astronomy (MPIfR) played a crucial role in these observations in two ways. With the flexible instruments at this telescope one could record data amenable to rapid identification of radio bursts and a form of data suitable for high resolution radio imaging. Secondly the large collecting area of the telescope makes it an indispensable element in the coordinated interferometric observations of weak sources like this FRB.

With the precise position of the radio source the team was able to conduct observations with one of the world’s largest optical telescopes, the 8-m Gemini North on Mauna Kea in Hawaii. Examining the environment around the source revealed that the bursts originated from a spiral galaxy named SDSS J015800.28+654253.0, located half a billion light years from Earth. The bursts come from a region of that galaxy where star formation is prominent.

“The found location is radically different from the previously located repeating FRB, but also different from all previously studied FRBs”, explains Kenzie Nimmo, PhD student at the University of Amsterdam. “The differences between repeating and non-repeating fast radio bursts are thus less clear and we think that these events may not be linked to a particular type of galaxy or environment. It may be that FRBs are produced in a large zoo of locations across the Universe and just require some specific conditions to be visible.”

“With the characterisation of this source, the argument against against pulsar-like emission as origin for repeating FRBs is gaining strength”, says Ramesh Karuppusamy of the MPIfR, a co-author of the study. “We are at the verge of more such localisations brought about by the upcoming newer telescopes. These will finally allow us to establish the true nature of these sources”, he adds.

While the current study casts doubt on previous assumptions, this FRB is the closest to Earth ever localised, allowing astronomers to study these events in unparalleled detail.

“We hope that continued studies will unveil the conditions that result in the production of these mysterious flashes. Our aim is to precisely localize more FRBs and, ultimately, understand their origin”, concludes Jason Hessels, corresponding author on the study, from the Netherlands Institute for Radio Astronomy (ASTRON) and the University of Amsterdam.

Map of the European VLBI Network (EVN) telescopes used in the observation, showing the positions of the eight participating radio telescopes and also JIVE in The Netherlands. (visibleearth.nasa.gov).

Source: Max Planck Institute for Radio Astronomy

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Why Fast Radio Burst localisation is important

While Fast Radio Bursts (FRBs) are a mystery of their own, their study could bring astronomers closer to understanding the Universe itself. In modern cosmology a major question is how structures on all scales were formed. There are computationally expensive simulations to address these questions, but their results strongly depend on the assumed conditions in the early Universe. Results from such simulations need to be compared with actual observations to determine if the simulations provide accurate answers. This is problematic as the majority of matter distributed within galaxies is invisible.

FRBs, however, may offer an elegant solution to this problem in the future. The short pulses from FRBs are “dispersed”, so at longer wavelengths the pulse arrives to Earth slightly later than at shorter wavelengths. This time delay can be measured very accurately, and it is an indirect estimate of the amount of material between the source and the Earth. If thousands of FRBs are found, in all directions, it will be possible to map the distribution of matter across the universe. However, in order to get the true three-dimensional distribution of matter in space, astronomers need to know the distance of each FRB from Earth as well.

How to localise a Fast Radio Burst

In the majority of searches for FRBs a single radio telescope is used to identify the approximate region that the FRB is originating from. However, the use of very high resolution radio observations through Very Long Baseline Interferometry (VLBI) adopts a novel approach.

Currently, the European VLBI Network (EVN) is the only VLBI array that is sensitive enough to study FRBs. In doing so, astronomers are able to determine both the host galaxy and the immediate local environment of the FRB. By determining the host galaxy, astronomers can then use optical observations to analyze the light coming from the galaxy and this can be used to determine its distance from Earth. Studying the environments in which FRBs occur is the key to understanding how these bursts can be produced and which extragalactic objects are associated with them.

“As we continue to unravel the mystery of FRBs, astronomers need to be able to study these sources in incredible detail. The combined sensitivity of the telescopes in the EVN currently provides a unique opportunity to observe these events and we hope that continued observations will contribute to our understanding of these enigmatic sources.” says Francisco Colomer, Director of the Joint Institute for VLBI ERIC.

Institutes and telescopes involved

Institutes involved Observations were conducted with the European Very Long Baseline Interferometry Network (EVN). The EVN is the most sensitive Very Long Baseline Interferometry (VLBI) array in the world, which allows researchers to conduct unique, high-resolution, radio astronomical observations of cosmic radio sources. Data from the EVN is processed at the Joint Institute for VLBI ERIC (JIVE) - an international research infrastructure based in the Netherlands, which also provides support, conducts leading research and forwards technical development in the field of radio astronomy.

A total of eight antennas from the EVN were involved in this observation: 25x38-m Jodrell Bank Mark2, University of Manchester (UK), 25-m Westerbork single-dish, ASTRON (The Netherlands), 100-m Effelsberg, Max Planck Institute for Radio Astronomy (Germany), 32-m Medicina, National Institute for Astrophysics (Italy), 25-m Onsala, Onsala Space Observatory (Sweden), 32-m Toruń, Nicolaus Copernicus University (Poland), 32-m Irbene, Ventspils International Radio Astronomy Centre (Latvia), and 65-m Tianma, Chinese Academy of Sciences (China).

Follow up optical observations were conducted using 8.1-m Gemini North, National Science Foundation’s National Optical-Infrared Astronomy Research Laboratory and Association of Universities for Research in Astronomy (USA).

The authors of the current study comprise B. Marcote, K. Nimmo, J. W. T. Hessels, S. P. Tendulkar, C. G. Bassa, Z. Paragi, A. Keimpema, M. Bhardwaj, R. Karuppusamy, V. M. Kaspi, C. J. Law, D. Michilli, K. Aggarwal, B. Andersen, A. M. Archibald, K. Bandura, G. C. Bower, P. J. Boyle, C. Brar, S. Burke-Spolaor, B. J. Butler, T. Cassanelli, P. Chawla, P. Demorest, M. Dobbs, E. Fonseca, U. Giri, D. C. Good, K. Gourdji, A. Josephy, A. Yu. Kirichenko, F. Kirsten, T. L. Landecker, D. Lang, T. J. W. Lazio, D. Z. Li, H.-H. Lin, J. D. Linford, K. Masui, J. Mena-Parra, A. Naidu, C. Ng, C. Patel, U.-L. Pen, Z. Pleunis, M. Rafiei-Ravandi, M. Rahman, A. Renard, P. Scholz, S. R. Siegel, K. M. Smith, I. H. Stairs, K. Vanderlinde and A. V. Zwaniga with Ramesh Karuppusamy as co-author from MPIfR.

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Contact

Dr. Ramesh Karuppusamy
Phone:+49 228 525-108
Email: ramesh@mpifr-bonn.mpg.de
Max-Planck-Institut für Radioastronomie, Bonn

Dr. Jason Hessels
Phone:+31 521 596-769
Email: hessels@astron.nl
ASTRON & The University of Amsterdam, The Netherlands

Dr. Norbert Junkes
Presse- und Öffentlichkeitsarbeit
Phone:+49 228 525-399
Email: njunkes@mpifr-bonn.mpg.de
Max-Planck-Institut für Radioastronomie, Bonn

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Original Paper

A repeating fast radio burst source localized to a nearby spiral galaxy

B. Marcote et al., Nature, Online Publication January 06, 2020

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Links

JIVE
Joint Institute for VLBI ERIC (JIVE)

Radio Telescope Effelsberg
Effelsberg Radio Telescope

EVN
European VLBI Network (EVN)

A repeating Fast Radio Burst from a Spiral Galaxy
Youtube Movie on FRB 180916.J0158+65.

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Hundreds of Thousands of New Galaxies

Galaxy cluster Abell 1314 in the constellation „Ursa Major“ in a distance of approximately 460 million light years. The LOFAR observations reveal radio emission from high-speed cosmic electrons (marked in red) resulting from collisions with other galaxy clusters. The overlay onto an optical image also shows hot X-ray gas (marked in grey) from observations with the Chandra satellite. © Amanda Wilber/LOFAR Surveys Team

Astronomers publish new sky map detecting a vast number of previously unknown galaxies

An international team of more than 200 astronomers from 18 countries including scientists from the Max Planck Institute for Radio Astronomy in Bonn, Germany, has published the first phase of a major new radio sky survey at unprecedented sensitivity using the Low Frequency Array (LOFAR) telescope. The survey reveals hundreds of thousands of previously undetected galaxies, shedding new light on many research areas including the physics of black holes and how clusters of galaxies evolve.

A special issue of the scientific journal Astronomy & Astrophysics is dedicated to the first twenty-six research papers describing the survey and its first results.

Radio astronomy reveals processes in the Universe that we cannot see with optical instruments. In this first part of the sky survey, LOFAR observed a quarter of the northern hemisphere at low radio frequencies. At this point, approximately ten percent of that data is now made public. It maps three hundred thousand sources, almost all of which are galaxies in the distant Universe; their radio signals have travelled billions of light years before reaching Earth.

Black holes

Huub Röttgering, Leiden University (The Netherlands): “If we take a radio telescope and we look up at the sky, we see mainly emission from the immediate environment of massive black holes. With LOFAR we hope to answer the fascinating question: where do those black holes come from?” What we do know is that black holes are pretty messy eaters. When gas falls onto them they emit jets of material that can be seen at radio wavelengths.

Philip Best, University of Edinburgh (UK), adds: “LOFAR has a remarkable sensitivity and that allows us to see that these jets are present in all of the most massive galaxies, which means that their black holes never stop eating.”

Clusters of galaxies

Clusters of galaxies are ensembles of hundreds to thousands of galaxies and it has been known for decades that when two clusters of galaxies merge, they can produce radio emission spanning millions of light years. This emission is thought to come from particles that are accelerated during the merger process. Amanda Wilber, University of Hamburg (Germany), elaborates: “With radio observations we can detect radiation from the tenuous medium that exists between galaxies. This radiation is generated by energetic shocks and turbulence. LOFAR allows us to detect many more of these sources and understand what is powering them."

Annalisa Bonafede, University of Bologna and INAF (Italy), adds: “What we are beginning to see with LOFAR is that, in some cases, clusters of galaxies that are not merging can also show this emission, albeit at a very low level that was previously undetectable. This discovery tells us that, besides merger events, there are other phenomena that can trigger particle acceleration over huge scales.”

Magnetic fields

The unprecedented accuracy of the LOFAR measurements allows to measure the effect of cosmic magnetic fields on radio waves. Researchers from Germany investigated magnetic fields in the halos of galaxies. They could show the existence of enormous magnetic structures also between galaxies. „The LOFAR data are providing hints that the space between galaxies could be completely magnetic“, says Rainer Beck from MPIfR Bonn, Germany.

High-quality images

Creating low-frequency radio sky maps takes both significant telescope and computational time and requires large teams to analyse the data. “LOFAR produces enormous amounts of data - we have to process the equivalent of ten million DVDs of data. The LOFAR surveys were recently made possible by a mathematical breakthrough in the way we understand interferometry”, says Cyril Tasse, Observatoire de Paris - Station de radioastronomie à Nançay (France).

“We have been working together with SURF in the Netherlands to efficiently transform the massive amounts of data into high-quality images. These images are now public and will allow astronomers to study the evolution of galaxies in unprecedented detail”, says Timothy Shimwell, Netherlands Institute for Radio Astronomy (ASTRON) and Leiden University.

SURF's compute and data centre located at SURFsara in Amsterdam runs on 100 percent renewable energy and hosts over 20 petabytes of LOFAR data. “This is more than half of all data collected by the LOFAR telescope to date. It is the largest astronomical data collection in the world. Processing the enormous data sets is a huge challenge for scientists. What normally would have taken centuries on a regular computer was processed in less than one year using the high throughput compute cluster (Grid) and expertise”, says Raymond Oonk (SURFsara).

LOFAR

The LOFAR telescope, the Low Frequency Array, is unique in its capabilities to map the sky in fine detail at metre wavelengths. LOFAR is operated by ASTRON in The Netherlands and is considered to be the world’s leading telescope of its type. “This sky map will be a wonderful scientific legacy for the future. It is a testimony to the designers of LOFAR that this telescope performs so well”, says Carole Jackson, Director General of ASTRON.

The next step

The 26 research papers in the special issue of Astronomy & Astrophysics were done with only the first two percent of the sky survey. The team aims to make sensitive high-resolution images of the whole northern sky, which will reveal 15 million radio sources in total. “Just imagine some of the discoveries we may make along the way. I certainly look forward to it”, says Jackson. “And among these there will be the first massive black holes that formed when the Universe was only a ‘baby’, with an age a few percent of its present age”, adds Röttgering.

LOFAR station Effelsberg, shown from 50 m above ground. In front: LOFAR lowband antennas (LBA) for 10-80 MHz, in the back: LOFAR highband antennas (HBA) for 110-240 MHz. © W. Reich/MPIfR

Source: Max Planck Institute for Radio Astronomy

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Local Contact:

Dr. Rainer Beck
Phone:+49 228 525-323
Email: rbeck@mpifr-bonn.mpg.de
Max-Planck-Institut für Radioastronomie, Bonn

Prof. Dr. Michael Kramer
Director and Head of "Fundamental Physics in Radio Astronomy" Research Dept.
Phone:+49 228 525-278
Email: mkramer@mpifr-bonn.mpg.de
Max-Planck-Institut für Radioastronomie, Bonn

Dr. Norbert Junkes
Press and Public Outreach
Phone:+49 228 525-399
Email: njunkes@mpifr-bonn.mpg.de
Max-Planck-Institut für Radioastronomie, Bonn

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Original Papers:

LOFAR Surveys - 26 papers in special issue of „Astronomy and Astrophysics“ 2019.

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Links:

Radioastro­nomische Fundamental­physik
Research Department "Fundamental Physics in Radio Astronomy" at MPIfR, Bonn, Germany

Images and Videos - Additional images and video clips

Image Gallery LOFAR Surveys - Images from LOFAR surveys

LOFAR - International LOFAR Telescope (ILT)

LOFAR MPIfR - LOFAR website at Max Planck Institute for Radio Astronomy (MPIfR)

GLOW - German Long Wavelength Consortium (GLOW)

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LOFAR: The international LOFAR telescope (ILT) consists of a European network of radio antennas, connected by a high-speed fibre optic network spanning seven countries. LOFAR was designed, built and is now operated by ASTRON (Netherlands Institute for Radio Astronomy), with its core located in Exloo in the Netherlands. LOFAR works by combining the signals from more than 100,000 individual antenna dipoles, using powerful computers to process the radio signals as if it formed a ‘dish’ of 1900 kilometres diameter. LOFAR is unparalleled given its sensitivity and ability to image at high resolution (i.e. its ability to make highly detailed images), such that the LOFAR data archive is the largest astronomical data collection in the world and is hosted at SURFsara (The Netherlands), Forschungszentrum Juelich (Germany) and the Poznan Super Computing Center (Poland). LOFAR is a pathfinder of the Square Kilometre Array (SKA), which will be the largest and most sensitive radio telescope in the world.

Institutes publishing the results:

Australia: CSIRO

Canada: University of Montreal, University of Calgary, Queen’s University

Denmark: University of Copenhagen

France: Observatoire de Paris PSL, Station de radioastronomie de Nançay, Université Côte d'Azur, Université de Strasbourg

Germany: Hamburg University, Ruhr-University Bochum, Karl Schwarzschild Observatory Tautenburg, European Southern Observatory, University of Bonn, Max Planck Institut für Extraterrestrische Physik, Garching, Bielefeld University, Max Planck Institute for Radio Astronomy, Bonn

Iceland: University of Iceland

India: Savitribai Phule Pune University

Ireland: University College Dublin

Italy: National Institute for Astrophysics (INAF), University of Bologna

Mexico: Universidad de Guanajuato

The Netherlands: ASTRON, the NOVA (Netherlands Research School for Astronomy) institutes at Leiden University, Groningen University, University of Amsterdam and Radboud University Nijmegen, SURFsara, SRON, Ampyx Power B.V, JIVE

Poland: Jagiellonian University, Nicolaus Copernicus University Toruń

South Africa: University of Western Cape, Rhodes University, SKA South Africa

Spain: Universidad de La Laguna

Sweden: Chalmers University

Uganda: Mbarara University of Science & Technology

United Kingdom: University of Hertfordshire, University of Edinburgh, Open University, University of Oxford, Univerity of Southampton, University of Bristol, University of Manchester, The Rutherford Appleton Laboratory, University of Portsmouth, University of Nottingham

USA: Harvard University, Naval Research Laboratory, University of Massachusetts

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Lifting the veil on the black hole at the heart of our Galaxy

Top left: Simulation of Sgr A* at 86 GHz. Top right: Simulation with added effects of scattering. Bottom right: Scattered image from the observations, this is how we see Sgr A* on the sky. Bottom left: The unscattered image, after removing the effects of scattering along our line of sight, this is how Sgr A* really looks like. © S. Issaoun, M. Mościbrodzka, Radboud University/ M. D. Johnson, CfA 

ALMA and the Global mm-VLBI Array team up and provide first scientific results

Including the powerful ALMA into an array of telescopes for the first time, astronomers have found that the emission from the supermassive black hole Sagittarius A* (Sgr A*) at the center of our Galaxy comes from a smaller region than previously thought. This may indicate that a radio jet from Sgr A* is pointed almost directly towards the Earth.

The work, performed by an international team with participation of the Max Planck Institute for Radio Astronomy, is published in the Astrophysical Journal.

So far, a foggy cloud of hot gas has prevented astronomers from making sharp images of the supermassive black hole Sgr A* and causing doubt on its true nature. They have now included for the first time the powerful ALMA telescope in northern Chile into a global network of radio telescopes to peer through this fog, but the source keeps surprising them: its emission region is so small that the source may actually have to point directly at the direction of the Earth.

Observing at a frequency of 86 GHz with the technique of Very Long Baseline Interferometry (VLBI), which combines many telescopes to form a virtual telescope the size of the Earth, the team succeeded in mapping out the exact properties of the light scattering blocking our view of Sgr A*. The removal of most of the scattering effects has produced a first image of the surroundings of the black hole.

The high quality of the unscattered image has allowed the team to constrain theoretical models for the gas around Sgr A*. The bulk of the radio emission is coming from a mere 300 milllionth of a degree, and the source has a symmetrical morphology. “This may indicate that the radio emission is produced in a disk of infalling gas rather than by a radio jet,” explains Sara Issaoun, graduate student at the Radboud University Nijmegen in the Netherlands, who leads the work and has tested several computer models against the data. “However, that would make Sgr A* an exception compared to other radio emitting black holes. The alternative could be that the radio jet is pointing almost at us”.

The German astronomer Heino Falcke, Professor of Radio Astronomy at Radboud University and PhD supervisor of Issaoun, calls this statement very unusual, but he also no longer rules it out. Last year, Falcke would have considered this a contrived model, but recently the GRAVITY team came to a similar conclusion using ESO’s Very Large Telescope Interferometer of optical telescopes and an independent technique. “Maybe this is true after all”, concludes Falcke, “and we are looking at this beast from a very special vantage point.”

Supermassive black holes are common in the centers of galaxies and may generate the most energetic phenomena in the known universe. It is believed that, around these black holes, matter falls in a rotating disk and part of this matter is expelled in opposite directions along two narrow beams, called jets, at speeds close to the speed of light, which typically produces a lot of radio light. “Whether the radio emission seen from SgrA* originates from a symmetrical underlying structure, or is intrinsically asymmetric is a matter of intense discussion”, explains Thomas Krichbaum, member of the team.

Sgr A* is the nearest supermassive black hole and 'weighs' about 4 million solar masses. Its apparent size on the sky is less than a 100 millionth degree, which corresponds to the size of a tennis ball on the moon as seen from the Earth. To measure this, the technique of VLBI is required. The resolution achieved with VLBI is further increased by the observation frequency. The highest frequency to date for VLBI is 230 GHz. “The first observations of Sgr A* at 86 GHz date from 26 years ago, led by Thomas Krichbaum at our Institute, with only a handful of telescopes. Over the years, the quality of the data and imaging capabilities has improved steadily as more telescopes join.”, says J. Anton Zensus, director at the Max Planck Institute for Radio Astronomy and head of its Radio Astronomy/VLBI division.

The findings of Issaoun and her international team including scientists from two research departments (Kramer & Zensus) at MPIfR describe the first observations at 86 GHz in which ALMA also participated, by far the most sensitive telescope at this frequency. ALMA became part of the Global Millimeter VLBI Array (GMVA), which is operated by the Max Planck Institute for Radio Astronomy, in April 2017. The participation of ALMA, made possible by the ALMA Phasing Project effort, has been decisive for the success of this project.

The participation of ALMA in mm-VLBI is important because of its sensitivity and its location in the southern hemisphere. In addition to ALMA, twelve radio telescopes in North America and Europe also participated in the network. The resolution achieved was twice as large as in previous observations at this frequency and produced the first image of Sgr A* that is considerably reduced in interstellar scattering (an effect caused by density irregularities in the ionized material along the line of sight between Sgr A* and the Earth)

To remove the scattering and obtain the image, the team used a technique developed by Michael Johnson of the Harvard-Smithsonian Center for Astrophysics (CfA). "Even though scattering blurs and distorts the image of Sgr A*, the incredible resolution of these observations allowed us to pin down the exact properties of the scattering,” says Johnson. “We could then remove most of the effects from scattering and begin to see what things look like near the black hole. The great news is that these observations show that scattering will not prevent the Event Horizon Telescope from seeing a black hole shadow at 230 GHz, if there's one to be seen."

Future studies at different wavelengths will provide complementary information and further observational constraints for this source, which holds the key to a better understanding of black holes, the most exotic objects in the known universe.

The Global Millimeter VLBI Array (GMVA), with ALMA added

© S. Issaoun, Radboud University/ D. Pesce, CfA

Source: Max Planck Institute for Radio Astronomy

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The data were correlated at the Max Planck Institute for Radio Astronomy (MPIfR), which also operates the Global Millimeter-VLBI Array (GMVA). Data analysis software was developed at the MIT Haystack Observatory and the Smithsonian Astrophysical Observatory.

Several members of the team worked in this project as part of the European Research Council funded BlackHoleCam (BHC) team.

The research team is also part of the Event Horizon Telescope (EHT) consortium, an international partnership of thirteen institutes from ten countries: Germany, the Netherlands, France & Spain (via IRAM), USA, Mexico, Japan, Taiwan, Canada and China (via EAO).

The participation of the Atacama Large Millimeter/submillimeter Array (ALMA) through the ALMA Phasing Project has been decisive for the success of this project.

The GMVA is partially supported by the European Union’s Horizon 2020 research and innovation programme under grant agreement No. 730562.

The research team comprises S. Issaoun, M. D. Johnson, L. Blackburn, C. D. Brinkerink, M. Mościbrodzka, A. Chael, C. Goddi, I. Martí-Vidal, J. Wagner, S. S. Doeleman, H. Falcke, T. P. Krichbaum, K. Akiyama, U. Bach, K. L. Bouman, G. C. Bower, A. Broderick, I. Cho, G. Crew, J. Dexter, V. Fish, R. Gold, J. L. Gómez, K. Hada, A. Hernández-Gómez, M. Janßen, M. Kino, M. Kramer, L. Loinard, R.-S. Lu, S. Markoff, D. P. Marrone, L. D. Matthews, J. M. Moran, C. Müller, F. Roelofs, E. Ros, H. Rottmann, S. Sánchez, R. P. J. Tilanus, P. de Vicente, M. Wielgus, J. A. Zensus, und G.-Y. Zhao. MPIfR co-authors are Jan Wagner, Thomas Krichbaum, Uwe Bach, Michael Kramer, Eduardo Ros and Anton Zensus.

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Local Contact

Dr. Thomas Krichbaum
Phone:+49 228 525-295
Email: tkrichbaum@mpifr-bonn.mpg.de
Max-Planck-Institut für Radioastronomie, Bonn

Prof. Dr. Eduardo Ros
Phone:+49 228 525-125
Email: ros@mpifr-bonn.mpg.de
Max-Planck-Institut für Radioastronomie, Bonn

Dr. Norbert Junkes
Press and Public Outreach
Phone:+49 228 525-399
Email: njunkes@mpifr-bonn.mpg.de
Max-Planck-Institut für Radioastronomie, Bonn

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Original Paper

The Size, Shape, and Scattering of Sagittarius A* at 86 GHz: First VLBI with ALMA
Sara Issaoun et al., 2019, The Astrophysical Journal 871, 30 (DOI: 10.3847/1538-4357/aaf732).

The Size, Shape, and Scattering of Sagittarius A* at 86 GHz: First VLBI with ALMA
Sara Issaoun et al., 2019 (on Preprint-Server astro-ph)

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Headline

Radio Astronomy / VLBI
Research Department "Radio Astronomy. VLBI" at MPIfR Bonn

Radioastro­nomische Fundamental­physik
Research Department "Fundamental Physics in Radio Astronomy" at MPIfR, Bonn, Germany

GMVA
Global Millimetre-VLBI Array (GMVA)

ALMA
Atacama Large Millimeter/submillimeter Array

RadioNet
RadioNet: Advanced Radio Astronomy in Europe

BlackHoleCam (BHC)
ERC project "BlackHoleCam"

EHT
Event Horizon Telescope (EHT)

ESO
European Southern Observatory (ESO)

Radboud
Department of Astrophysics, Radboud University, Nijmegen, The Netherlands

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Lifting the Veil on Star Formation in the Orion Nebula

The powerful wind from the newly formed star at the heart of the Orion Nebula is creating the bubble (black) and preventing new stars from forming in its neighborhood. At the same time, the wind pushes molecular gas (color) to the edges, creating a dense shell around the bubble where future generations of stars can form. © NASA/SOFIA/Pabst et. al

SOFIA discovers that the stellar wind from a newborn star in the Orion Nebula is preventing more stars from forming nearby

The stellar wind from a newborn star in the Orion Nebula is preventing more new stars from forming nearby, according to new research using NASA’s Stratospheric Observatory for Infrared Astronomy, SOFIA. This is surprising because until now, scientists thought that other processes, such as exploding stars called supernovae, were largely responsible for regulating the formation of stars. But SOFIA’s observations suggest that infant stars generate stellar winds that can blow away the seed material required to form new stars, a process called “feedback.” The results are published as "Advanced Online Publication" (AOP) in "Nature".

The Orion Nebula is among the best observed and most photographed objects in the night sky. It is the closest stellar nursery to Earth, and helps scientists explore how stars form. A veil of gas and dust makes this nebula extremely beautiful, but also shrouds the entire process of star birth from view. Fortunately, infrared light can pierce through this cloudy veil, allowing specialized observatories like SOFIA to reveal many of the star-formation secrets that would otherwise remain hidden.

At the heart of the nebula lies a small grouping of young, massive and luminous stars. Observations from SOFIA’s instrument, the German Receiver for Astronomy at Terahertz Frequencies, known as GREAT, revealed, for the first time, that the strong stellar wind from the brightest of these baby stars, designated Theta1 Orionis C (θ1 Ori C), has swept up a large shell of material from the cloud where this star formed, like a snow plow clearing a street by pushing snow to the road’s edges.

“The wind is responsible for blowing an enormous bubble around the central stars,” explained Cornelia Pabst, a Ph.D. student at the University of Leiden in the Netherlands and the lead author on the paper. “It disrupts the natal cloud and prevents the birth of new stars.”

Researchers used the GREAT instrument on SOFIA to measure the spectral line – which is like a chemical fingerprint – of ionized carbon. Because of SOFIA’s airborne location, flying above 99 percent of the water vapor in the Earth's atmosphere that blocks infrared light, researchers were able to study the physical properties of the stellar wind.

“The large scale Orion C+ observation demonstrates that such scale mapping is possible with SOFIA/upGREAT. The multi-pixel SOFIA/upGREAT receiver allows us to map larger regions in a shorter time compared to previous instruments. It is about 80 times faster than the single pixel HIFI receiver onboard the ESA cornerstone mission Herschel”, says Ronan Higgins who led the investigation from the University of Cologne side.

Similarly, astronomers use the ionized carbon’s spectral signature to determine the speed of the gas at all positions across the nebula and study the interactions between massive stars and the clouds where they were born. The signal is so strong that it reveals critical details and nuances of the stellar nurseries that are otherwise hidden. But this signal can only be detected with specialized instruments — like GREAT— that can study far-infrared light.

At the center of the Orion Nebula, the stellar wind from θ1 Ori C forms a bubble and disrupts star birth in its neighborhood. At the same time, it pushes molecular gas to the edges of the bubble, creating new regions of dense material where future stars might form.

These feedback effects regulate the physical conditions of the nebula, influence the star formation activity, and ultimately drive the evolution of the interstellar medium, the space between stars filled with gas and dust. Understanding how star formation interacts with the interstellar medium is key to understanding the origins of the stars we see today, and those that may form in the future.

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SOFIA is a Boeing 747SP jetliner modified to carry a 106-inch diameter telescope. It is a joint project of NASA and the German Aerospace Center, DLR. NASA’s Ames Research Center in California’s Silicon Valley manages the SOFIA program, science and mission operations in cooperation with the Universities Space Research Association headquartered in Columbia, Maryland, and the German SOFIA Institute (DSI) at the University of Stuttgart. The aircraft is maintained and operated from NASA’s Armstrong Flight Research Center Hangar 703, in Palmdale, California.

GREAT/upGREAT, the German Receiver for Astronomy at Terahertz Frequencies, was developed and built by a consortium of German research institutes (MPI for Radio Astronomy/MPIfR, Bonn and KOSMA/University of Cologne, in collaboration with the DLR Institute for Planetary Research, Berlin, and the MPI for Solar System Research, Göttingen). The GREAT Principal Investigator (PI) is Jürgen Stutzki from Cologne University, Deputy Principal Investigator (Co-PI) is Bernd Klein from MPIfR. The development of the instrument was financed by the participating institutes, Max Planck Society, the German Research Foundation (SFB 956) and the German Space Agency.

The research team comprises C. Pabst, R. Higgins, J.R. Goicoechea, D. Teyssier, O. Berne, E. Chambers, M. Wolfire, S. Suri, R. Güsten, J. Stutzki, U.U. Graf, C. Risacher and A.G.G.M. Tielens. Rolf Güsten and Christophe Risacher from the Max-Planck-Institut für Radioastronomie in Bonn/Germany are co-authors of the publication.

Source: Max Planck Institute for Radio Astronomy

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Local Contact

Prof. Dr. Jürgen Stutzki
Phone:+49 228 470-3494
Email: stutzki@ph1.uni-koeln.de
1. Physikalisches Institut der Universität zu Köln

Dr. Rolf Güstenv Phone:+49 228 525-383
Email: rguesten@mpifr-bonn.mpg.de
Max-Planck-Institut für Radioastronomie, Bonn

Dr. Norbert Junkes
Press and Public Outreach
Phone:+49 228 525-399
Email: njunkes@mpifr-bonn.mpg.de
Max-Planck-Institut für Radioastronomie, Bonn

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Original Paper

Disruption of the Orion Molecular Core 1 by the stellar wind of the massive star θ1 Ori C

C. Pabst, R. Higgins, J.R. Goicoechea, D. Teyssier, O. Berne, E. Chambers, M. Wolfire, S. Suri, R. Güsten, J. Stutzki, U.U. Graf, C. Risacher and A.G.G.M. Tielens, Nature Advanced Online Publication (AOP), DOI 10.1038/s41586-018-0844-1.

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Links

Stars & Planets from SOFIA, Spitzer & Citizen Scientists
Press conference at AAS meeting 233 (Seattle, 07 January 2019).

SFB 956
Collaborative Research Centre (CRC) 956

I. Physikalisches Institut
Cologne University

Leiden Observatory
Astrophysics at Leiden University/The Netherlands

NASA/SOFIA
SOFIA Mission

Deutsches SOFIA-Institut
DSI Website

GREAT at MPIfR
German Receiver at Terahertz Frequencies (GREAT)

SOFIA
DLR Website

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