Does Some Dark Matter Carry an Electric Charge?

This artist's impression shows the evolution of the Universe beginning with the Big Bang on the left followed by the appearance of the cosmic microwave background. The formation of the first stars ends the cosmic dark ages, followed by the formation of galaxies. CfA/M. Weiss. Low Resolution (jpg)

Cambridge, MA - Astronomers have proposed a new model for the invisible material that makes up most of the matter in the Universe. They have studied whether a fraction of dark matter particles may have a tiny electrical charge.

"You've heard of electric cars and e-books, but now we are talking about electric dark matter," said Julian Munoz of Harvard University in Cambridge, Mass., who led the study that has been published in the journal Nature. "However, this electric charge is on the very smallest of scales."

Munoz and his collaborator, Avi Loeb of the Harvard-Smithsonian Center for Astrophysics (CfA) in Cambridge, Mass., explore the possibility that these charged dark matter particles interact with normal matter by the electromagnetic force.

Their new work dovetails with a recently announced result from the Experiment to Detect the Global EoR (Epoch of Reionization) Signature (EDGES) collaboration. In February, scientists from this project said they had detected the radio signature from the first generation of stars, and possible evidence for interaction between dark matter and normal matter. Some astronomers quickly challenged the EDGES claim. Meanwhile, Munoz and Loeb were already looking at the theoretical basis underlying it.

"We're able to tell a fundamental physics story with our research no matter how you interpret the EDGES result," said Loeb, who is the chair of the Harvard astronomy department. "The nature of dark matter is one of the biggest mysteries in science and we need to use any related new data to tackle it."

The story begins with the first stars, which emitted ultraviolet (UV) light. According to the commonly accepted scenario, this UV light interacted with cold hydrogen atoms in gas lying between the stars and enabled them to absorb the cosmic microwave background (CMB) radiation, the leftover radiation from the Big Bang.

This absorption should have led to a drop in intensity of the CMB during this period, which occurs less than 200 million years after the Big Bang. The EDGES team claimed to detect evidence for this absorption of CMB light, though this has yet to be independently verified by other scientists.However, the temperature of the hydrogen gas in the EDGES data is about half of the expected value.

"If EDGES has detected cooler than expected hydrogen gas during this period, what could explain it?" said Munoz. "One possibility is that hydrogen was cooled by the dark matter."

At the time when CMB radiation is being absorbed, the any free electrons or protons associated with ordinary matter would have been moving at their slowest possible speeds (since later on they were heated by X-rays from the first black holes). Scattering of charged particles is most effective at low speeds. Therefore, any interactions between normal matter and dark matter during this time would have been the strongest if some of the dark matter particles are charged. This interaction would cause the hydrogen gas to cool because the dark matter is cold, potentially leaving an observational signature like that claimed by the EDGES project.

"We are constraining the possibility that dark matter particles carry a tiny electrical charge – equal to one millionth that of an electron – through measurable signals from the cosmic dawn," said Loeb. "Such tiny charges are impossible to observe even with the largest particle accelerators."

Only small amounts of dark matter with weak electrical charge can both explain the EDGES data and avoid disagreement with other observations. If most of the dark matter is charged, then these particles would have been deflected away from regions close to the disk of our own Galaxy, and prevented from reentering. This conflicts with observations showing that large amounts of dark matter are located close to the disk of the Milky Way.

Scientists know from observations of the CMB that protons and electrons combined in the early Universe to form neutral atoms. Only a small fraction of these charged particles, about one in a few thousand, remained free. Munoz and Loeb are considering the possibility that dark matter may have acted in a similar way. The data from EDGES, and similar experiments, might be the only way to detect the few remaining charged particles, as most of the dark matter would be neutral.

"The viable parameter space for this scenario is quite constrained, but if confirmed by future observations, of course we would be learning something fundamental about the nature of dark matter, one of the biggest puzzles that we have in physics today," said Harvard’s Cora Dvorkin who was not involved with the new study.

Lincoln Greenhill also from the CfA is currently testing the observational claim by the EDGES team. He leads the Large Aperture Experiment to Detect the Dark Ages (LEDA) project, which uses the Long Wavelength Array in Owen's Valley California and Socorro, New Mexico.

A paper describing these results appear in the May 31, 2018 issue of the journal Nature.

Headquartered in Cambridge, Mass., the Harvard-Smithsonian Center for Astrophysics (CfA) is a collaboration between the Smithsonian Astrophysical Observatory and the Harvard College Observatory. CfA scientists, organized into six research divisions, study the origin, evolution and ultimate fate of the universe.

For more information, contact:

Megan Watzke
Harvard-Smithsonian Center for Astrophysics
+1 617-496-7998
mwatzke@cfa.harvard.edu

Peter Edmonds
Harvard-Smithsonian Center for Astrophysics
+1 617-571-7279
pedmonds@cfa.harvard.edu

Source: Harvard-Smithsonian Center for Astrophysics (CfA)

A Crowded Neighbourhood

PR Image eso1816a

The rich region around the Tarantula Nebula in the Large Magellanic Cloud

PR Image eso1816b

Tarantula Nebula region in the constellation of Doradus

PR Image eso1816c

The rich region around the Tarantula Nebula in the Large Magellanic Cloud (annotated)

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Videos

PR Video eso1816a

ESOcast 162 Light: A Crowded Neighbourhood (4K UHD)

PR Video eso1816b

Zooming in on the Tarantula Nebula

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Glowing brightly about 160 000 light-years away, the Tarantula Nebula is the most spectacular feature of the Large Magellanic Cloud, a satellite galaxy to our Milky Way. The VLT Survey Telescope at ESO’s Paranal Observatory in Chile has imaged this region and its rich surroundings in exquisite detail. It reveals a cosmic landscape of star clusters, glowing gas clouds and the scattered remains of supernova explosions. This is the sharpest image ever of this entire field.

Taking advantage of the capacities of the VLT Survey Telescope (VST) at ESO’s Paranal Observatory in Chile, astronomers captured this very detailed new image of the Tarantula Nebula and its numerous neighbouring nebulae and star clusters. The Tarantula, which is also known as 30 Doradus, is the brightest and most energetic star-forming region in the Local Group of galaxies.

The Tarantula Nebula, at the top of this image, spans more than 1000 light-years and is located in the constellation of Dorado (The Dolphinfish) in the far southern sky. This stunning nebula is part of the Large Magellanic Cloud, a dwarf galaxy that measures about 14 000 light-years across. The Large Magellanic Cloud is one of the closest galaxies to the Milky Way.

At the core of the Tarantula Nebula lies a young, giant star cluster called NGC 2070, a starburst region whose dense core, R136, contains some of the most massive and luminous stars known. The bright glow of the Tarantula Nebula itself was first recorded by French astronomer Nicolas-Louis de Lacaille in 1751.

Another star cluster in the Tarantula Nebula is the much older Hodge 301, in which at least 40 stars are estimated to have exploded as supernovae, spreading gas throughout the region. One example of a supernova remnant is the superbubble SNR N157B, which encloses the open star cluster NGC 2060. This cluster was first observed by British astronomer John Herschel in 1836, using an 18.6-inch reflector telescope at the Cape of Good Hope in South Africa. On the outskirts of the Tarantula Nebula, on the lower right-hand side, it is possible to identify the location of the famous supernova SN 1987A [1].

Moving to the left-hand side of the Tarantula Nebula, one can see a bright open star cluster called NGC 2100, which displays a brilliant concentration of blue stars surrounded by red stars. This cluster was discovered by Scottish astronomer James Dunlop in 1826 while working in Australia, using his self-built 9-inch (23-cm) reflecting telescope.

At the centre of the image is the star cluster and emission nebula NGC 2074, another massive star-forming region discovered by John Herschel. Taking a closer look one can spot a dark seahorse-shaped dust structure — the “Seahorse of the Large Magellanic Cloud”. This is a gigantic pillar structure roughly 20 light-years long — almost five times the distance between the Sun and the nearest star, Alpha Centauri. The structure is condemned to disappear over the next million years; as more stars in the cluster form, their light and winds will slowly blow away the dust pillars.

Obtaining this image was only possible thanks to the VST’s specially designed 256-megapixel camera called OmegaCAM. The image was created from OmegaCAM images through four different coloured filters, including one designed to isolate the red glow of ionised hydrogen [2].

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Notes

[1] SN 1987A was the first supernova to be observed with modern telescopes and the brightest since Kepler’s Star in 1604. SN 1987A was so intense that it blazed with the power of 100 million suns for several months following its discovery on 23 February 1987.

[2] The H-alpha emission line is a red spectral line created when the electron inside a hydrogen atom loses energy. This happens in hydrogen around hot young stars when the gas becomes ionised by the intense ultraviolet radiation and electrons subsequently recombine with protons to form atoms again. The ability of OmegaCAM to detect this line allows astronomers to characterise the physics of giant molecular clouds where new stars and planets form.

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More Information

ESO is the foremost intergovernmental astronomy organisation in Europe and the world’s most productive ground-based astronomical observatory by far. It has 15 Member States: Austria, Belgium, the Czech Republic, Denmark, France, Finland, Germany, Italy, the Netherlands, Poland, Portugal, Spain, Sweden, Switzerland and the United Kingdom, along with the host state of Chile and with Australia as a strategic partner. ESO carries out an ambitious programme focused on the design, construction and operation of powerful ground-based observing facilities enabling astronomers to make important scientific discoveries. ESO also plays a leading role in promoting and organising cooperation in astronomical research. ESO operates three unique world-class observing sites in Chile: La Silla, Paranal and Chajnantor. At Paranal, ESO operates the Very Large Telescope and its world-leading Very Large Telescope Interferometer as well as two survey telescopes, VISTA working in the infrared and the visible-light VLT Survey Telescope. ESO is also a major partner in two facilities on Chajnantor, APEX and ALMA, the largest astronomical project in existence. And on Cerro Armazones, close to Paranal, ESO is building the 39-metre Extremely Large Telescope, the ELT, which will become “the world’s biggest eye on the sky”.

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Links

• Photos of the VLT Survey Telescope

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Contacts

Richard Hook
ESO Public Information Officer
Garching bei München, Germany
Tel: +49 89 3200 6655
Cell: +49 151 1537 3591
Email: rhook@eso.org

Source: ESO/News

Discovery of a Massive Pulsar

Artist's impression of the massive neutron star PSR J2215+5135, which heats up the inner face of its companion star.

Credit: G. Pérez-Díaz/IAC. Large format: [ JPG ]

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Researchers from the Universitat Politècnica de Catalunya (UPC) and the Instituto de Astrofísica de Canarias (IAC) report the discovery of one of the most massive known neutron stars using the William Herschel (WHT), the Gran Telescopio Canarias (GTC) and the IAC80 telescopes.

Neutron stars, also known as pulsars, are stars at the end of their evolution. They evolve from stars with masses ranging from 10 to 30 solar masses, and end as compact objects having a few solar masses, confined to a sphere just 20 kilometres diameter.

PSR J2215+5135, discovered in 2011, is a neutron star in a binary system, in which the two stars orbit around a common centre of mass. The companion star, or secondary, is of solar type and it is strongly irradiated by the neutron star.

Manuel Linares, a Marie-Curie researcher at the UPC, in collaboration with Tariq Shahbaz and Jorge Casares from the IAC, obtained photometric and spectroscopic data of PSR J2215+5135 using ACAM (in service time) and ISIS on the WHT, respectively. They also used GTC and IAC80 telescopes, and combined all the data, in a novel way, with dynamical models of irradiated binary stars, to directly obtain the mass of PSR J2215+5135. The WHT observations were key to measuring the optical light curve of the binary, modulated by the orbital motion of the irradiated companion star.

The team measured the mass of PSR J2215+5135 to be 2.3 solar masses, making it one of the most massive neutron stars ever observed, out of more than 2,000 neutron stars currently known.

The more massive the neutron star is, the faster its companion star orbits. The new method applied by Linares and collaborators consists of measuring the orbital speed of the companion star from the radial velocity of hydrogen and magnesium spectral lines. This allowed the team of astronomers to measure for the first time the speed of both the irradiated and shaded sides of the companion star, and to show that a neutron star can have a mass more than two solar masses.

Within the past 10 years, the Fermi-LAT NASA gamma-ray telescope has revealed dozens of pulsars similar to PSR J2215+5135. In principle, the method can also be used to measure the mass of black holes and white dwarfs (remnants of stars that die with more than 30 or less than 10 solar masses, respectively) when they are found in similar binary systems in which irradiation is important.

The determination of the maximum mass of a neutron star has important consequences for many fields of astrophysics, as well as for nuclear physics. How nucleons (the neutrons and protons that make up the nucleus of an atom) interact with each other at high densities is one of the great mysteries of physics today. Neutron stars are a natural laboratory for studying the densest and most exotic states of matter.

These results also suggest that, in order to support the weight of 2.3 solar masses, the repulsion between particles in the nucleus of the neutron star must be sufficiently strong. This would indicate that it's unlikely free quarks or other exotic forms of matter could be found in the centre of this neutron star.

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More Information

M. Linares et al., 2018, "Peering into the dark side: magnesium lines establish a massive neutron star in PSR J2215+5135", ApJ, 859, 54 [ ADS ].

Video "A massive pulsar irradiates a solar-type star".

Video "A 2.3 Solar-mass neutron star in PSR J2215+5135".

"Researchers from the UPC and the IAC discover one of the most massive neutron stars", IAC press release, 24 May 2018.

"A Massive Neutron Star with a Two-Faced Companion", AAS Nova, 25 May 2018.

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Source:  Isaac Newton Group of Telescopes

Hidden from view

NGC 5643

Credit: ESO/A. Alonso-Herrero et al.; ALMA (ESO/NAOJ/NRAO

This ESO Picture of the Week shows the centre of a galaxy named NGC 5643. This galaxy is located 55 million light-years from Earth in the constellation of Lupus (The Wolf), and is known as a Seyfert galaxy. Seyfert galaxies have very luminous centres — thought to be powered by material being accreted onto a supermassive black hole lurking within — that can also be shrouded and obscured by clouds of dust and intergalactic material.

As a result, it can be difficult to observe the active centre of a Seyfert galaxy. NGC 5643 poses a further challenge; it is viewed at a high inclination, making it even trickier to view its inner workings. However, scientists have used the Atacama Large Millimeter/submillimeter Array (ALMA) together with archival data from the Multi Unit Spectroscopic Explorer (MUSE) instrument on ESO’s Very Large Telescope to reveal this view of NGC 5643 — complete with energetic outflowing ionised gas pouring out into space.

These impressive outflows stretch out on either side of the galaxy, and are caused by matter being ejected from the accretion disc of the supermassive black hole at NGC 5643’s core. Combined, the ALMA and VLT data show the galaxy’s central region to have two distinct components: a spiraling, rotating disc (visible in red) consisting of cold molecular gas traced by carbon monoxide, and the outflowing gas, traced by ionised oxygen and hydrogen (in blue-orange hues) perpendicular to the inner nuclear disc.

Source: ESO/images/Potw

APEX takes a glimpse into the heart of darkness

Schematic diagram of the 1.3 mm VLBI observations of Sagittarius A* (Sgr A*) in the Galactic centre, which were performed in 2013. The insets show possible shapes of the source emission that are consistent with the measurements. For better visualization of the angular dimensions, a white circle of 50 micro-arcseconds in diameter is superimposed on the models. The location of the APEX telescope on the southern hemisphere in Chile now provides longer interferometric baselines, leading to a doubling of the angular resolution in comparison to earlier observations. This setup enables a spatial resolution of only 3 Schwarzschild radii in Sgr A*. © Eduardo Ros/Thomas Krichbaum (MPIfR)

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A global array of telescopes, including APEX, reveals the finest details so far on event horizon scales in the centre of our Galaxy

The 12 m radio telescope APEX in Chile has been outfitted with special equipment including broad bandwidth recorders and a stable hydrogen maser clock for performing joint interferometric observations with other telescopes at wavelengths as short as 1.3 mm and the goal to obtain the ultimate picture of the black hole shadow. The addition of APEX to the so-called Event Horizon Telescope (EHT), which until recently consisted of antennas only in the northern hemisphere, reveals new and unprecedented details in the structure of Sgr A* at the centre of the Milky Way. The increased angular resolution provided by the APEX telescope now reveals details in the asymmetric and not point-like source structure, which are as small as 36 million km. This corresponds to dimensions that are only 3 times larger than the hypothetical size of the black hole (3 Schwarzschild This corresponds to dimensions that are only 3 times larger than the hypothetical size of the black hole (3 Schwarzschild radii).

Astronomers are hunting for the ultimate proof of Einstein’s theory of general relativity, which is to obtain a direct image of the shadow of a black hole.  This is possible by combining radio telescopes spread over the globe using a technique which is called Very Long Baseline Interferometry (VLBI). The participating telescopes are located at high altitudes to minimize the disturbance from the atmosphere and on remote sites with clear skies, allowing to observe the compact radio source Sagittarius A* (Sgr A*) at the centre of the Milky Way.  

The research team observed Sgr A* in 2013 using VLBI telescopes at four sites. The telescopes include the APEX telescope in Chile, the CARMA array in California, the JCMT and the phased SMA in Hawaii, and the SMT telescope in Arizona. Sgr A* was detected with all stations and the longest baseline length reached up to almost 10,000 kilometers, indicating an ultra-compact and asymmetric (not point-like) source structure.

“The participation of the APEX telescope almost doubles the length of the longest baselines in comparison to earlier observations and leads to a spectacular resolution of 3 Schwarzschild radii only”, says Ru-Sen Lu from the Max Planck Institute for Radio Astronomy (MPIfR) in Bonn, Germany, the lead author of the publication. “It reveals details in the central radio source which are smaller than the expected size of the accretion disk”, adds Thomas Krichbaum, initiator of the mm-VLBI observations with APEX.

The location of APEX in the southern hemisphere considerably improves the image quality for a source as far south in the sky as Sagittarius A* (−29 degrees declination). APEX has paved the way towards the inclusion of the large and extremely sensitive ALMA telescope into the EHT observations, which are now being performed once a year.

“We have worked hard at an altitude of more than 5000 meters to install the equipment to make the APEX telescope ready for VLBI observations at 1.3 mm wavelength”, says Alan Roy, also from MPIfR who leads the VLBI team at APEX. “We are proud of the good performance of APEX in this experiment.”

The team employed a model-fitting procedure to investigate the event-horizon-scale-structure of Sgr A*. “We started to figure out what the horizon-scale structure may look like, rather than just draw generic conclusions from the visibilities that we sampled. It is very encouraging to see that the fitting of a ring-like structure agrees very well with the data, though we cannot exclude other models, e.g., a composition of bright spots.”, adds Ru-Sen Lu. Future observations with more telescopes added to the EHT will sort out residual ambiguities in the imaging.

The black hole at the center of the our galaxy is embedded in a dense interstellar medium, which may affect the propagation of electromagnetic waves along the line of sight.  “However, the interstellar scintillation, which in principle may lead to image distortions, is not a strongly dominating effect at 1.3 mm wavelength ”, says Dimitrios Psaltis from the University of Arizona, who is the EHT project scientist.

“The results are an important step to ongoing development of the Event Horizon Telescope”, says Sheperd Doeleman from the Harvard-Smithsonian Center for Astrophysics and director of the EHT project. “The analysis of new observations, which since 2017 also include ALMA, will bring us another step closer to imaging the black hole in the centre of our Galaxy.”

Source: Max Planck Institute for Astronomy

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The Atacama Pathfinder Experiment (APEX) is a collaboration between the Max Planck Institute for Radio Astronomy (MPIfR), the Onsala Space Observatory (OSO), and the European Southern Observatory (ESO) to construct and operate a modified prototype antenna of ALMA (Atacama Large Millimetre Array) as a single dish on the Chajnantor plateau at an altitude of 5,100 metres above sea level (Atacama Desert, Chile). The telescope was manufactured by VERTEX Antennentechnik in Duisburg, Germany. The operation of the telescope is entrusted to ESO.

The research team consists of Ru-Sen Lu, Thomas P. Krichbaum, Alan L. Roy, Vincent L. Fish, Sheperd S. Doeleman, Michael D. Johnson, Kazunori Akiyama, Dimitrios Psaltis, Walter Alef, Keiichi Asada, Christopher Beaudoin, Alessandra Bertarini, Lindy Blackburn, Ray Blundell, Geoffrey C. Bower, Christiaan Brinkerink, Avery E. Broderick, Roger Cappallo, Geoffrey B. Crew, Jason Dexter, Matt Dexter, Heino Falcke, Robert Freund, Per Friberg, Christopher H. Greer, Mark A. Gurwell, Paul T. P. Ho, Mareki Honma, Makoto Inoue, Junhan Kim, James Lamb, Michael Lindqvist, David MacMahon, Daniel P. Marrone, Ivan Martí-Vidal, Karl M. Menten, James M. Moran, Neil M. Nagar, Richard L. Plambeck, Rurik A. Primiani, Alan E. E. Rogers, Eduardo Ros, Helge Rottmann, Jason SooHoo, Justin Spilker, Jordan Stone, Peter Strittmatter, Remo P. J. Tilanus, Michael Titus, Laura Vertatschitsch, Jan Wagner, Jonathan Weintroub, Melvyn Wright, Ken H. Young, J. Anton Zensus and Lucy M. Ziurys.

Authors with MPIfR affiliation include Ru-Sen Lu, the first author, Thomas Krichbaum, Alan Roy, Walter Alef, Alessandra Bertarini, Karl Menten, Eduardo Ros, Helge Rottmann, Anton Zensus, and Heino Falcke.

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Local Contact:

Dr. Ru-Sen Lu
Phone:+49 228 525-292
Email: rslu@mpifr-bonn.mpg.de
Max-Planck-Institut für Radioastronomie, Bonn

Dr. Thomas Krichbaum
Phone:+49 228 525-295
Email: tkrichbaum@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: 

Detection of Intrinsic Source Structure at ∼ 3 Schwarzschild Radii with Millimeter-VLBI Observations of Sagittarius A*

Ru-Sen Lu et al., 2018, The Astrophysical Journal, Vol. 859, No. 1 (DOI: 10.3847/1538-4357)

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Links :

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

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APEX
The Atacama Pathfinder Experiment (APEX)

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CARMA 
Combined Array for Research in Millimeter-wave Astronomy (CARMA), Bishop, California

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JCMT 
James Clerk Maxwell Telescope, Mauna Kea, Hawaii (JCMT)

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SMA 
Submillimeter Array (SMA), Mauna Kea, Hawaii

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SMT (Heinrich Hertz Telescope) 
Submillimeter Telescope (SMT), Mt. Graham, Arizona

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EHT 
Event Horizon Telescope (EHT)

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Event Horizon Telescope
MPIfR web page for the EHT observations in April 2017

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E0102-72.3: Astronomers Spot a Distant and Lonely Neutron Star

1E 0102.2-7219

Credit: X-ray (NASA/CXC/ESO/F.Vogt et al); 

Optical (ESO/VLT/MUSE & NASA/STScI)

JPEG (979.2 kb) - Large JPEG (13.6 MB) - Tiff (113.2 MB) - More Images

Tour of E0102 - More Animations

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Astronomers have discovered a special kind of neutron star for the first time outside of the Milky Way galaxy, using data from NASA's Chandra X-ray Observatory and the European Southern Observatory's Very Large Telescope (VLT) in Chile.

Neutron stars are the ultra dense cores of massive stars that collapse and undergo a supernova explosion. This newly identified neutron star is a rare variety that has both a low magnetic field and no stellar companion.

The neutron star is located within the remains of a supernova — known as 1E 0102.2-7219 (E0102 for short) — in the Small Magellanic Cloud, located 200,000 light years from Earth.

This new composite image of E0102 allows astronomers to learn new details about this object that was discovered more than three decades ago. In this image, X-rays from Chandra are blue and purple, and visible light data from VLT's Multi Unit Spectroscopic Explorer (MUSE) instrument are bright red. Additional data from the Hubble Space Telescope are dark red and green.

Oxygen-rich supernova remnants like E0102 are important for understanding how massive stars fuse lighter elements into heavier ones before they explode. Seen up to a few thousand years after the original explosion, oxygen-rich remnants contain the debris ejected from the dead star's interior. This debris (visible as a green filamentary structure in the combined image) is observed today hurtling through space after being expelled at millions of miles per hour.

Chandra observations of E0102 show that the supernova remnant is dominated by a large ring-shaped structure in X-rays, associated with the blast wave of the supernova. The new MUSE data revealed a smaller ring of gas (in bright red) that is expanding more slowly than the blast wave. At the center of this ring is a blue point-like source of X-rays. Together, the small ring and point source act like a celestial bull's eye.

The combined Chandra and MUSE data suggest that this source is an isolated neutron star, created in the supernova explosion about two millennia ago. The X-ray energy signature, or "spectrum," of this source is very similar to that of the neutron stars located at the center of two other famous oxygen-rich supernova remnants: Cassiopeia A (Cas A) and Puppis A. These two neutron stars also do not have companion stars.

The lack of evidence for extended radio emission or pulsed X-ray radiation, typically associated with rapidly rotating highly-magnetized neutron stars, indicates that the astronomers have detected the X-radiation from the hot surface of an isolated neutron star with low magnetic fields. About ten such objects have been detected in the Milky Way galaxy, but this is the first one detected outside our galaxy.

But how did this neutron star end up in its current position, seemingly offset from the center of the circular shell of X-ray emission produced by the blast wave of the supernova? One possibility is that the supernova explosion did occur near the middle of the remnant, but the neutron star was kicked away from the site in an asymmetric explosion, at a high speed of about two million miles per hour. However, in this scenario, it is difficult to explain why the neutron star is, today, so neatly encircled by the recently discovered ring of gas seen at optical wavelengths.

Another possible explanation is that the neutron star is moving slowly and its current position is roughly where the supernova explosion happened. In this case, the material in the optical ring may have been ejected either during the supernova explosion, or by the doomed progenitor star up to a few thousand years before.

A challenge for this second scenario is that the explosion site would be located well away from the center of the remnant as determined by the extended X-ray emission. This would imply a special set of circumstances for the surroundings of E0102: for example, a cavity carved by winds from the progenitor star before the supernova explosion, and variations in the density of the interstellar gas and dust surrounding the remnant.

Future observations of E0102 at X-ray, optical, and radio wavelengths should help astronomers solve this exciting new puzzle posed by the lonely neutron star.

A paper describing these results was published in the April issue of Nature Astronomy, and is available online. NASA's Marshall Space Flight Center in Huntsville, Alabama, manages the Chandra program for NASA's Science Mission Directorate in Washington. The Smithsonian Astrophysical Observatory in Cambridge, Massachusetts, controls Chandra's science and flight operations.

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Fast Facts for E0102-72.3:

Scale: Image is about 2.85 arcmin (165 light years) across
Category: Supernovas & Supernova Remnants
Coordinates (J2000): RA 01h 04m 02.40s | Dec -72° 01´ 55.30"
Constellation: Tucana
Observation Date: 28 pointings between 2/01/2003 - 03/19/2017
Observation Time: 113 hours 21 seconds (4 days 17 hours 21 seconds)

Obs. ID: 3519-3520, 3544-3545, 5123-5124, 5130-5131, 6042-6043, 6074-6075, 6758-6759, 6765-6766, 8365,9694, 10654-10656, 11957, 13093, 14258, 15467, 16589, 18418, 19850

Instrument: ACIS
Also Known As: SN010102-72
References: Vogt, F. et al, 2018, Nature Astronomy, arXiv:1803.01006
Color Code: X-ray (blue, purple); Optical (red, green)
Distance Estimate: About 200,000 light years

Source: NASA’s Chandra X-ray Observatory

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Droids beat astronomers in predicting survivability of exoplanets

Artist's impression of Kepler-16b, discovered by NASA's Kepler mission and the first confirmed circumbinary planet. It is a gas giant that orbits close to the edge of its binary system's habitable zone. Credit: T. Pyle / NASA / JPL-Caltech

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Artificial intelligence is giving scientists new hope for studying the habitability of planets, in a study from astronomers Chris Lam and David Kipping. Their work looks at so-called ‘Tatooines’, and uses machine learning techniques to calculate how likely such planets are to survive into stable orbits. The study is published in the journal Monthly Notices of the Royal Astronomical Society. 

Circumbinary planets are those planets that orbit two stars instead of just one, much like the fictional planet Tatooine in the Star Wars franchise. Tens of these planets have so far been discovered, but working out whether they may be habitable or not can be difficult.

Moving around two stars instead of just one can lead to large changes in a planet’s orbit, which mean that it is often either ejected from the system entirely, or it crashes violently into one of its twin stars. Traditional approaches to calculating which of these occurs for a given planet get significantly more complicated as soon as the extra star is thrown into the mix.

“When we simulated millions of possible planets with different orbits using traditional methods, we found that planets were being predicted as stable that were clearly not, and vice versa,” explains Lam, lead author of the study and a recent graduate of Columbia University.

Planets need to survive for billions of years in order for life to evolve, so finding out whether orbits are stable or not is an important question for habitability. The new work shows how machine learning can make accurate predictions even if the standard approach - based on Newton’s laws of gravity and motion - breaks down.

“Classification with numerous complex, inter-connected parameters is the perfect problem for machine learning,” says Professor Kipping, supervisor of the work.

After creating ten million hypothetical Tatooines with different orbits, and simulating each one to test for stability, this huge training set was fed into the deep learning network. Within just a few hours, the network was able to out-perform the accuracy of the standard approach.

More circumbinary planets look set to be discovered by NASA’s Transiting Exoplanet Survey Satellite (TESS) mission, and Lam expects their work to help: “Our model helps astronomers to know which regions are best to search for planets around binary stars. This will hopefully help us discover new exoplanets and better understand their properties.”

Source:  Royal Astronomical Society (RAS)

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Media contacts 

Dr Morgan Hollis
Royal Astronomical Society
Mob: +44 (0)7802 877 700
mhollis@ras.ac.uk

Dr Robert Massey
Royal Astronomical Society
Mob: +44 (0)7802 877 699
rmassey@ras.ac.uk

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Science contacts

Mr Chris Lam
Columbia University
Tel: +1 954 540 1339
cl3425@columbia.edu

Prof. David Kipping
Columbia University
dkipping@astro.columbia.edu

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Video:

Prof. David Kipping explains why three-body systems are so tricky and how a neural network can save the day. Neural networks can capture borderline cases that are missed by even the most sophisticated mathematical solutions. He also highlights how neural networks might play an increasingly larger role in answering similarly complex science questions. Credit: D. Kipping / Cool Worlds Lab

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Further information

The new work appears in: "A machine learns to predict the stability of circumbinary planets", C. Lam & D. Kipping, Monthly Notices of the Royal Astronomical Society (2018) 476 (4): 5692-5697 (DOI: 10.1093/mnras/sty022).

A copy of the paper is available at: https://doi.org/10.1093/mnras/sty022

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Notes for editors 

The Royal Astronomical Society (RAS), founded in 1820, encourages and promotes the study of astronomy, solar-system science, geophysics and closely related branches of science. The RAS organizes scientific meetings, publishes international research and review journals, recognizes outstanding achievements by the award of medals and prizes, maintains an extensive library, supports education through grants and outreach activities and represents UK astronomy nationally and internationally. Its more than 4,000 members (Fellows), a third based overseas, include scientific researchers in universities, observatories and laboratories as well as historians of astronomy and others. The RAS accepts papers for its journals based on the principle of peer review, in which fellow experts on the editorial boards accept the paper as worth considering. The Society issues press releases based on a similar principle, but the organisations and scientists concerned have overall responsibility for their content. Follow the RAS on Twitter, Facebook and Instagram

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Hubble shows the local Universe in ultraviolet

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The glowing spiral arms of NGC 6744

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Dwarf galaxy UGCA 281

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Messier 66 — member of the Leo Triplet

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Pockets of star formation in DDO 68

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Wave of star formation in Messier 96

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Parts of Messier 106

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Using the unparalleled sharpness and ultraviolet observational capabilities of the NASA/ESA Hubble Space Telescope, an international team of astronomers has created the most comprehensive high-resolution ultraviolet-light survey of star-forming galaxies in the local Universe. The catalogue contains about 8000 clusters and 39 million hot blue stars.

Ultraviolet light is a major tracer of the youngest and hottest stars. These stars are short-lived and intensely bright. Astronomers have now finished a survey called LEGUS (Legacy ExtraGalactic UV Survey) that captured the details of 50 local galaxies within 60 million light-years of Earth in both visible and ultraviolet light.

The LEGUS team carefully selected its targets from among 500 candidate galaxies compiled from ground-based surveys. They chose the galaxies based on their mass, star-formation rate, and their abundances of elements heavier than hydrogen and helium. Because of the proximity of the selected galaxies, Hubble was able to resolve them into their main components: stars and star clusters. With the LEGUS data, the team created a catalogue with about 8000 young clusters and it also created a star catalogue comprising about 39 million stars that are at least five times more massive than our Sun.

The data, gathered with Hubble’s Wide Field Camera 3 and Advanced Camera for Surveys, provide detailed information on young, massive stars and star clusters, and how their environment affects their development. As such, the catalogue offers an extensive resource for understanding the complexities of star formation and galaxy evolution.

One of the key questions the survey may help astronomers answer is the connection between star formation and the major structures, such as spiral arms, that make up a galaxy. These structured distributions are particularly visible in the youngest stellar populations.

By resolving the fine details of the studied galaxies, while also studying the connection to larger galactic structures, the team aims to identify the physical mechanisms behind the observed distribution of stellar populations within galaxies.

Figuring out the final link between gas and star formation is key to fully understanding galaxy evolution. Astronomers are studying this link by looking at the effects of the environment on star clusters, and how their survival is linked to their surroundings.

LEGUS will not only allow astronomers to understand the local Universe. It will also help interpret views of distant galaxies, where the ultraviolet light from young stars is stretched to infrared wavelengths due to the expansion of space. The NASA/ESA/CSA James Webb Space Telescope and its ability to observe in the far infrared will complement the LEGUS views.

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More Information

The Hubble Space Telescope is a project of international cooperation between ESA and NASA.
Image credit: NASA, ESA, LEGUS team

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Links

• LEGUS survey page
• Already published galaxies from the LEGUS survey
• Hubblesite release

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Contacts

Linda Smith
European Space Agency
Baltimore, Maryland, USA
Tel: 001 4103384926
Email: lsmith@stsci.edu

Mathias Jäger
ESA/Hubble, Public Information Officer
Garching bei München, Germany
Cell: +49 176 62397500
Email: mjaeger@partner.eso.org

Source: ESA/Hubble/News

ALMA and VLT Find Evidence for Stars Forming Just 250 Million Years After Big Bang

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Hubble and ALMA image of MACS J1149.5+2223

 

PR Image eso1815b

Galaxy cluster MACS j1149.5+223

 

PR Image eso1815c

ALMA observation of distant galaxy MACS 1149-JD1

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Videos

PR Video eso1815a

ESOcast 161 Light: Distant galaxy reveals very early star formation (4K UHD)

PR Video eso1815b

Zooming in on the distant galaxy MACS1149, and beyond

PR Video eso1815c

Computer simulation of star formation in MACS1149-JD1

PR Video eso1815d

Zooming in on the distant galaxy MACS 1149-JD1

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Astronomers have used observations from the Atacama Large Millimeter/submillimeter Array (ALMA) and ESO’s Very Large Telescope (VLT) to determine that star formation in the very distant galaxy MACS1149-JD1 started at an unexpectedly early stage, only 250 million years after the Big Bang. This discovery also represents the most distant oxygen ever detected in the Universe and the most distant galaxy ever observed by ALMA or the VLT. The results will appear in the journal Nature on 17 May 2018.

An international team of astronomers used ALMA to observe a distant galaxy called MACS1149-JD1. They detected a very faint glow emitted by ionised oxygen in the galaxy. As this infrared light travelled across space, the expansion of the Universe stretched it to wavelengths more than ten times longer by the time it reached Earth and was detected by ALMA. The team inferred that the signal was emitted 13.3 billion years ago (or 500 million years after the Big Bang), making it the most distant oxygen ever detected by any telescope [1]. The presence of oxygen is a clear sign that there must have been even earlier generations of stars in this galaxy.

“I was thrilled to see the signal of the distant oxygen in the ALMA data,” says Takuya Hashimoto, the lead author of the new paper and a researcher at both Osaka Sangyo University and the National Astronomical Observatory of Japan. “This detection pushes back the frontiers of the observable Universe.”

In addition to the glow from oxygen picked up by ALMA, a weaker signal of hydrogen emission was also detected by ESO’s Very Large Telescope (VLT). The distance to the galaxy determined from this observation is consistent with the distance from the oxygen observation. This makes MACS1149-JD1 the most distant galaxy with a precise distance measurement and the most distant galaxy ever observed with ALMA or the VLT.

“This galaxy is seen at a time when the Universe was only 500 million years old and yet it already has a population of mature stars,” explains Nicolas Laporte, a researcher at University College London (UCL) in the UK and second author of the new paper. “We are therefore able to use this galaxy to probe into an earlier, completely uncharted period of cosmic history.”

For a period after the Big Bang there was no oxygen in the Universe; it was created by the fusion processes of the first stars and then released when these stars died. The detection of oxygen in MACS1149-JD1 indicates that these earlier generations of stars had been already formed and expelled oxygen by just 500 million years after the beginning of the Universe.

But when did this earlier star formation occur? To find out, the team reconstructed the earlier history of MACS1149-JD1 using infrared data taken with the NASA/ESA Hubble Space Telescope and the NASA Spitzer Space Telescope. They found that the observed brightness of the galaxy is well-explained by a model where the onset of star formation corresponds to only 250 million years after the Universe began [2].

The maturity of the stars seen in MACS1149-JD1 raises the question of when the very first galaxies emerged from total darkness, an epoch astronomers romantically term “cosmic dawn”. By establishing the age of MACS1149-JD1, the team has effectively demonstrated that galaxies existed earlier than those we can currently directly detect.

Richard Ellis, senior astronomer at UCL and co-author of the paper, concludes: “Determining when cosmic dawn occurred is akin to the Holy Grail of cosmology and galaxy formation. With these new observations of MACS1149-JD1 we are getting closer to directly witnessing the birth of starlight! Since we are all made of processed stellar material, this is really finding our own origins.”

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More Information

These results are published in a paper entitled: “The onset of star formation 250 million years after the Big Bang”, by T. Hashimoto et al., to appear in the journal Nature on 17 May 2018.

The research team members are: Takuya Hashimoto (Osaka Sangyo University/National Astronomical Observatory of Japan, Japan), Nicolas Laporte (University College London, United Kingdom), Ken Mawatari (Osaka Sangyo University, Japan), Richard S. Ellis (University College London, United Kingdom), Akio. K. Inoue (Osaka Sangyo University, Japan), Erik Zackrisson (Uppsala University, Sweden), Guido Roberts-Borsani (University College London, United Kingdom), Wei Zheng (Johns Hopkins University, Baltimore, Maryland, United States), Yoichi Tamura (Nagoya University, Japan), Franz E. Bauer (Pontificia Universidad Católica de Chile, Santiago, Chile), Thomas Fletcher (University College London, United Kingdom), Yuichi Harikane (The University of Tokyo, Japan), Bunyo Hatsukade (The University of Tokyo, Japan), Natsuki H. Hayatsu (The University of Tokyo, Japan; ESO, Garching, Germany), Yuichi Matsuda (National Astronomical Observatory of Japan/SOKENDAI, Japan), Hiroshi Matsuo (National Astronomical Observatory of Japan/SOKENDAI, Japan, Sapporo, Japan), Takashi Okamoto (Hokkaido University, Sapporo, Japan), Masami Ouchi (The University of Tokyo, Japan), Roser Pelló (Université de Toulouse, France), Claes-Erik Rydberg (Universität Heidelberg, Germany), Ikkoh Shimizu (Osaka University, Japan), Yoshiaki Taniguchi (The Open University of Japan, Chiba, Japan), Hideki Umehata (The University of Tokyo, Japan) and Naoki Yoshida (The University of Tokyo, Japan).

ESO is the foremost intergovernmental astronomy organisation in Europe and the world’s most productive ground-based astronomical observatory by far. It has 15 Member States: Austria, Belgium, the Czech Republic, Denmark, France, Finland, Germany, Italy, the Netherlands, Poland, Portugal, Spain, Sweden, Switzerland and the United Kingdom, along with the host state of Chile and with Australia as a strategic partner. ESO carries out an ambitious programme focused on the design, construction and operation of powerful ground-based observing facilities enabling astronomers to make important scientific discoveries. ESO also plays a leading role in promoting and organising cooperation in astronomical research. ESO operates three unique world-class observing sites in Chile: La Silla, Paranal and Chajnantor. At Paranal, ESO operates the Very Large Telescope and its world-leading Very Large Telescope Interferometer as well as two survey telescopes, VISTA working in the infrared and the visible-light VLT Survey Telescope. ESO is also a major partner in two facilities on Chajnantor, APEX and ALMA, the largest astronomical project in existence. And on Cerro Armazones, close to Paranal, ESO is building the 39-metre Extremely Large Telescope, the ELT, which will become “the world’s biggest eye on the sky”.

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Links

• Research paper in Nature
• Photos of the VLT
• Photos of ALMA

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Contacts:

Nicolas Laporte

University College London

London, United Kingdom

Tel: +44 7452 807 591

Email: n.laporte@ucl.ac.uk

Richard Ellis

University College London

London, United Kingdom

Tel: +44 7885 403 334

Email: richard.ellis@ucl.ac.uk

Richard Hook

ESO Public Information Officer

Garching bei München, Germany

Tel: +49 89 3200 6655

Cell: +49 151 1537 3591

Email: pio@eso.org

Source: ESO/News

Revealing the complexity of the nebula in NGC 1275 with SITELLE

Hα filamentary structure around NGC 1275.

Credits: Marie-Lou Gendron-Marsolais, Julie Hlavacek-Larrondo, Laurent Drissen and Maxime Pivin-Lapointe.  
Hi-res image

Movie showing how the filamentary structure of NGC 1275 varies with wavelength. 

Credits: Marie-Lou Gendron-Marsolais, Julie Hlavacek-Larrondo, Laurent Drissen and Maxime Pivin-Lapointe.

Ph.D. student Marie-Lou Gendron-Marsolais and professor Julie Hlavacek-Larrondo, from the Centre for Research in Astrophysics of Québec (CRAQ) and Université de Montréal, have joined the developers of SITELLE, Laurent Drissen and Thomas Martin from Université Laval, an instrument recently installed at the Canada-France-Hawaii telescope (CFHT), to reveal for the first time the intricate dynamic around the galaxy NGC 1275. 

Located 250 million light-years from earth, NGC 1275 is not an ordinary galaxy. It sits in the middle of the Perseus galaxy cluster, a gigantic cluster harboring thousands of galaxies in the constellation of the same name. NGC 1275 rests at the center of a hot and diffuse intracluster gas with an average temperature of tens of millions of degrees. This complex gas constitutes a large part of the luminous mass of galaxy clusters: the hot gas tends to cool and fall toward the galaxy while the central supermassive black hole releases powerful jets of energetic particles. These particles blow gigantic bubbles in the hot gas, preventing it from cooling. Astronomers generally dectect these bubbles by using radio radio telescopes. However, a spectacular network of thin intricate filaments surrounding the galaxy NGC 1275 is visible at specific optical wavelengths. "These types of filaments are often visible around galaxies that lie in similar environments... but their origin is a real mystery", declares Marie-Lou Gendron-Marsolais, lead author on the paper.

Extending over 250 000 light-years, two to three times the size of our own galaxy, the link between this large network of filaments and its environment is still unclear. Two theories are in conflict: the filaments could be condensing from the hot intracluster gas and sinking toward the center of the galaxy or being lifted by the bubbles created by the central supermassive black hole jets and dragged outward of the galaxy.

In order to unravel the mystery of these filaments, the international team of researchers have used SITELLE, an instrument at the Canada-France-Hawaii Telescope that enables the imaging of the galaxy at several different wavelengths at the same time. "This way we obtain a spectrum for each pixel of the image" declares Julie Hlavacek-Larrondo, a coauthor on the paper. "But what is unique about SITELLE is its incredibly large field of view, covering NGC 1275 in its entirety for the first time since the discovery of the nebula, 60 years ago", she adds.

Installed at the top of Maunakea on the Big Island in 2015, SITELLE is the product of the expertise of a team led by the astrophysicist Laurent Drissen as well as the optical design specialist Simon Thibault, both professors at the Faculté des sciences et de génie of Université Laval, as well as the knowledge of CFHT and the high-performance technology business ABB.

With a spectra for each pixel, it is now possible to obtain the radial velocity of each filament, revealing their dynamics at an unprecedented level. "The motion of this network of filaments seems to be very complex. It does not seem to be from a uniform motion, rather it is extremely chaotic", declares Marie-Lou Gendron-Marsolais. The team is convinced that such observations will help illuminate the mysteries of these structures. Understanding the filaments' dynamics aids astronmers in the understanding the processes of heating and cooling of the gas feeding the central black hole. Unlocking this process constitutes a key element in the study of galaxy evolution and, at larger scale, of environment such as clusters of galaxies.

The results from the work led by Marie-Lou Gendron-Marsolais, Julie Hlavacek-Larrondo, Laurent Drissen, Thomas Martin and their international collaborators are published in a letter of the latest issue of the Monthly Notices of the Royal Astronomical Society.

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Additional information:

Preprint (No login required)

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Contact Information:

Media contacts

Mary Beth Laychak
Outreach manager
Canada-France-Hawaii Telescope
mary@cfht.hawaii.edu

Robert Lamontagne
Public Outreach
Centre de recherche en astrophysique du Québec
Phone : (438) 495-3482
lamont@astro.umontreal.ca

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Science contacts:

Marie-Lou Gendron-Marsolais
Centre de recherche en astrophysique du Québec
Université de Montréal
marie-lou@astro.umontreal.ca

Professor Julie Hlavacek-Larrondo
Centre de recherche en astrophysique du Québec
Université de Montréal
juliehl@astro.umontreal.ca

Professor Laurent Drissen
Centre recherche en astrophysique du Québec
Université Laval
ldrissen@phy.ulaval.ca

Source: Canada-France-Hawaii Telescope (CFHT)

Dutch astronomers photograph possible toddler planet by chance

An infrared image of the binary CS Cha with the newly discovered companion in the dotted circle. After a mouse click you can see the image viewed with special polarization filters that make dust discs and exoplanets visible. The companion seems to have his own dust disc. (c) C. Ginski & SPHERE

 

An international team of astronomers headed by Dutch researchers from Leiden University has coincidently found a small companion around the young double star CS Cha. The astronomers examined the dust disc of the binary, while they stumbled upon the companion. The researchers suspect that it is a planet in his toddler years that is still growing. The astronomers used the SPHERE instrument on the European Very Large Telescope in Chile. They will soon publish their findings in an article that is accepted by the journal Astronomy & Astrophysics.

The binary star CS Cha and his special companion are located some six hundred light years away from Earth in a star formation area in the southern constellation Chameleon. The double star is just two to three million years young. The researchers wanted to study the star to search for a dust disc and for planets in the making.

During their research on the binary star, the astronomers saw a small dot on the edge of their images. The researchers dived into the telescope archives and discovered the dot, but much fainter, also on 19 year old photographs taken with the Hubble Space Telescope and on 11 year old photographs of the Very Large Telescope. Thanks to the old photographs, the astronomers were able to show that the companion moves with the binary and that they belong together.

What the companion looks like and how it was formed is unclear. The researchers tried to fit various models on the observations, but they do not give a hundred percent certainty. The companion may be a small brown dwarf star, but it can also be a big super-Jupiter.

Lead author Christian Ginski (Leiden Observatory, Leiden University) explains: "The most exciting part is that the light of the companion is highly polarized. Such a preference in the direction of polarization usually occurs when light is scattered along the way. We suspect that the companion is surrounded by his own dust disc. The tricky part is that the disc blocks a large part of the light and that is why we can hardly determine the mass of the companion. So it could be a brown dwarf but also a super-Jupiter in his toddler years. The classical planet-forming-models can't help us."

Infographic of the binary star CS Cha and its surrounding dust disc (left) with the newly discovered companion (right). The companion is located at more than 214 times the distance earth-sun fromthe binary, but clearly belongs to the system. The whole system is about 165 parsec (538 light years) away from Earth. (c) C. Ginski/G.A. Muro Arena

In the future, the researchers want to examine the star and the companion in more detail. They want to use the international ALMA telescope on the Chajnantor plateau in the North Chilean Andes.

SPHERE

SPHERE is the abbreviation of Spectro-Polarimetric High-contrast Exoplanet REsearch instrument. It is a powerful planet hunter that is attached to the European Very Large Telescope at Cerro Paranal in northern Chile. The instrument has partly been developed in the Netherlands. SPHERE can make direct images of exoplanets and dust discs around stars. The instrument bypasses the bright star and looks specifically at polarized light that is reflected by the atmosphere of an exoplanet or the dust disc around a star.

 
Reference:

"First direct detection of a polarized companion outside of a resolved circumbinary disk around CS Cha*", C. Ginski (1, 2), M. Benisty (3, 4), R.G. van Holstein (1), A. Juhász (5), T.O.B. Schmidt (6), G. Chauvin (3, 4) , J. de Boer (1), M. Wilby (1), C.F. Manara (7), P. Delorme (4), F. Ménard (4), P. Pinilla (8), T. Birnstiel (9), M. Flock(10), C. Keller (1), M. Kenworthy (1), J. Milli (4, 11), J. Olofsson (12, 13), L. Pérez (14), F. Snik (1), en N. Vogt (12). 1. Universiteit Leiden; 2. Universiteit van Amsterdam; 3 en 14. Universidad de Chile (Chili); 4. Univ. Grenoble Alpes (Frankrijk); 5. University of Cambridge (Verenigd Koninkrijk); 6. Sorbonne Paris Cité (Frankrijk); 7 ESA/ESTEC, Noordwijk; 8. The University of Arizona (Verenigde Staten); 9. Ludwig-Maximilians-Universität München (Duitsland); 10. Max-Planck-Institut für Astronomie (Duitsland); 11. European Southern Observatory (Chili); 12 en 13. Universidad de Valparaíso (Chili), 2018, accepted for publication in Astronomy and Astrophysics. (free preprint)

Dutch news release

Source: Astronomie.NL