News Release

Herschel finds source of cosmic dust in a stellar explosion

Peer-Reviewed Publication

University College London

Image of SN 1987A

image: This is an image of SN 1987A. view more 

Credit: AAAS/ESA/NASA/Herschel

ESA's Herschel Space Observatory is helping unravel the mystery of where cosmic dust comes from. Thanks to the resolution and sensitivity of Herschel, astronomers have been able to detect cosmic dust from a supernovae, adding weight to the theory that these cosmic fireworks are responsible for its creation.

The origin of the dust is important because it plays a crucial role in the formation of stars, particularly billions of years ago when star formation was at its peak. Galaxies like our own Milky Way are not simply collections of stars, but also contain clouds of gas and dust, crucial to the formation of new stars.

"Interestingly, this brand new clue does not come from observations of very distant galaxies, but from one of our closest galactic neighbours," comments Mikako Matsuura from UCL (University College London), who led a recent study published in the journal Science. Supernovae in our Galaxy are very rare, but 24 years ago astronomers were treated to one in the Large Magellanic Cloud, a small galaxy about 160,000 light years away.

On 23rd February 1987 the aging star could no longer support its own weight and collapsed in a violent supernova. The resulting shockwave energised material in a disc of gas and dust around the star, and is still travelling outwards at speeds of up to 6000 km/s (13 million miles per hour).

The pulse of light from the supernova lit up a ring of material almost a light year (10 million million km) across, dozens of times the size of our Solar System. This material glows in visible and ultraviolet light, as well as in x-rays. Small amounts of dust in the ring were warmed to a temperature of -100 Celsius, and this glows faintly in infrared light.

Twenty three years after the initial explosion the Herschel Space Observatory observed the supernova remnant. As well as the warm dust in the glowing ring, the new measurements have shown that there is dust in the centre of the remnant with a temperature of below -250 C, just 20 degrees above absolute zero. There is much more of this cold dust than the warm dust previously seen – in fact enough to form more than 200,000 Earths.

"We didn't expect to see SN1987A when we planned the survey," explains Margaret Meixner, from the Space Telescope Science Institute in Baltimore, USA, and who leads the HERITAGE survey for which these observations were taken. "Based on our existing knowledge of dust in supernovae, we could not have anticipated that Herschel would have detected this source. It has definitely been one of the biggest surprises of our project," she adds.

The dust was formed from material that was thrown away from the star in the initial explosion, and if similar amounts are created in all such explosions, this could explain the origin of much of the dust seen in the Large Magellanic Cloud.

"Since no facility comparable to Herschel has existed during the past two decades, we cannot say for certain large amount of cold dust was produced," notes Matsuura. "But we have proved that a supernova can produce an amount of dust comparable to the mass of the Sun over a period of, at most, a couple of dozen years—a blink of an eye with respect to a star's lifetime," she adds.

The observations of SN1978a are crucial for understanding the remnants of supernova that Herschel is observing in our own Galaxy, which exploded hundreds or thousands of years ago. But this latest result also has much further reaching consequences. "With objects like SN1987a, we can investigate details that are almost impossible to discern in supernovae inside more distant galaxies. This helps us improve our understanding of these stellar explosions, which we can then apply to the broader context of galaxy evolution," explained Matsuura.

Most of the galaxies seen in the very distant Universe appear bright in the far-infrared as seen by Herschel, but very faint in visible light. This is because they contain large quantities of dust, which blocks most of the visible light from the stars in the galaxies, and these observations by Herschel of SN1987a help to explain where most of that dust comes from. Astronomers are very interested in this because these galaxies are seen as they were 8-10 billion years ago, a period in the Universe when stars were forming at rates higher than ever before or since.

These observation show the power of Herschel for investigating the origin of dust across the ages, from our own Galactic neighbourhood to galaxies in the distant Universe", remarked Matt Griffin, from Cardiff University and principal investigator of the SPIRE instrument. "In turn, this is helping us understand the formation of the stars we see today".

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For more information see:

www.herscheltelescope.org.uk
www.esa.int/herschel

Contacts

Mikako Matsuura
Lead Author
University College London
Email: mikako.matsuura@ucl.ac.uk
Tel: +44 (0)20 7679 4348

Mike Barlow
University College London
Email: mjb@star.ucl.ac.uk
Tel: +44 (0)20 7679 7160

Chris North
UK Herschel Outreach Officer
Cardiff University
Email: chris.north@astro.cf.ac.uk
Tel: +44 (0)29 20 870 537

Margaret Meixner
Principal Investigator of the Key Programme HERITAGE
Space Telescope Science Institute
Baltimore, MD, USA
Email: meixner@stsci.edu
Phone: +1 (0)410-338-5013

Matt Griffin
Principal Investigator of SPIRE instrument
Cardiff University
Email: matt.griffin@astro.cf.ac.uk
Tel: +44 (0)29 20 874 203

Notes for editors

Herschel is an ESA space observatory with science instruments provided by European-led Principal Investigator consortia and with important participation from NASA.

The observations of SN1987a were made as part of the HERITAGE open-time key programme of the Herschel mission. HERITAGE project is using the SPIRE and PACS instruments on Herschel to map the Large and Small Magellanic Clouds, two very nearby dwarf galaxies which are in orbit around our own Milky Way galaxy. By mapping these galaxies with PACS and SPIRE, HERITAGE is providing a key insight into the life cycle of galaxies. The far-infrared emission shows the coldest interstellar dust, the most deeply embedded young stars, and the dust ejected by older stars. This will allow a census of the massive young proto-stars, and an inventory of the dust produced by massive stars and supernovae. Spectroscopy using PACS maps the locations of ionised carbon, oxygen and ionised nitrogen in the galaxies, probing the warmer material. Together, the images and spectra help constrain the physical conditions of the interstellar medium required to form stars. By bridging the gap between studies of the Milky Way and slightly more distant galaxies, studies of the Magellanic Clouds will allow extrapolation to the early Universe.

SN1987A

The star would originally have been around 20 times the mass of the Sun, but in the later stages of its life it lost around a third of its mass into a giant cloud. Such enveloping clouds are one possible source of dust in the Universe, but can only account for a tiny fraction of what is observed. The explosion resulting from a collapsing star is one of the most violent events in the Universe, and this event, called "SN1987a", was no different. The supernova glowed with the brightness of 100 million Suns for around a month, while most of the material that made up the star was blown outwards at immense speeds.

Most of the dust found by Herschel in the form of silicates, not dissimilar to sand or quartz, though there are smaller amounts of carbon and iron present as well. The dust is probably being heated by a range of processes, either by x-rays emitted by the glowing ring, or by the radioactive decay of heavy elements, such as titanium, which were created in the star's final moments.

SPIRE

The SPIRE instrument contains an imaging photometer (camera) and an imaging spectrometer. The camera operates in three wavelength bands centred on 250, 350 and 500 μm, and so can make images of the sky simultaneously in three sub-millimetre colours. SPIRE has been developed by a consortium of institutes led by Cardiff Univ. (UK) and including Univ. Lethbridge (Canada); NAOC (China); CEA, LAM (France); IFSI, Univ. Padua (Italy); IAC (Spain); Stockholm Observatory (Sweden); Imperial College London, RAL, UCL-MSSL, UKATC, Univ. Sussex (UK); Caltech, JPL, NHSC, Univ. Colorado (USA). This development has been supported by national funding agencies: CSA (Canada); NAOC (China); CEA, CNES, CNRS (France); ASI (Italy); MCINN (Spain); SNSB (Sweden); STFC (UK); and NASA (USA).

PACS

PACS is also an imaging photometer (camera) and an imaging spectrometer. The camera operates in three bands centred on 70, 100, and 160 μm, respectively. PACS has been developed by a consortium of institutes led by MPE (Germany) and including UVIE (Austria); KUL, CSL, IMEC (Belgium); CEA, OAMP (France); MPIA (Germany); IFSI, OAP/AOT, OAA/CAISMI, LENS, SISSA (Italy); IAC (Spain). This development has been supported by the funding agencies BMVIT (Austria), ESA- PRODEX (Belgium), CEA/CNES (France), DLR (Germany), ASI (Italy), and CICT/MCT (Spain).


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