Posted on by Anne Minard

Balloon Experiment Solves Mystery of Far Infrared Background

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Scientists have found a way to look past Earth’s atmosphere — and ancient cosmic dust — to glimpse galaxies that were formed in the first 5 billion years of the Universe.

A new study, released today in the journal Nature, reveals first-ever news from star-forming regions both near and far — including some from the edges of the Universe, which are racing away from us the fastest because of the Universe’s expansion.

The findings also clear up the sources of the Far Infrared Background, long shrouded in mystery.

The discoveries hail from the Balloon-borne Large Aperture Submillimetre Telescope (BLAST), which floated 120,000 feet (36,576 meters) above Antarctica in 2006.

The BLAST team chose to map a particular region of the sky called the Great Observatories Origins Deep Survey–South (GOODS-South), which was studied at other wavelengths by NASA’s three “great observatories” — the Hubble, Spitzer, and Chandra space telescopes. In one epic 11-day balloon flight, BLAST found more than 10 times the total number of submillimeter starburst galaxies detected in a decade of ground-based observations.

“We measured everything, from thousands of small clouds in our own galaxy undergoing star formation to galaxies in the Universe when it was only a quarter of its present age,” said lead author Mark Devlin, from the University of Pennsylvania.

In the 1980s and 1990s, certain galaxies called Ultraluminous InfraRed Galaxies were found to be birthing hundreds of times more stars than our own local galaxies. These “starburst” galaxies, 7-10 billion light years away, were thought to make up the Far Infrared Background discovered by the COBE satellite. Since the initial measurement of this background radiation, higher-resolution experiments have tried to detect the individual galaxies that comprise it.

The BLAST study combines telescope survey measurements at wavelengths below 1 millimeter with data at much shorter infrared wavelengths from the Spitzer Space Telescope. The results confirm that all the Far Infrared Background comes from individual distant galaxies, essentially solving a decade-old question of the radiation’s origin.

Star formation takes place in clouds composed of hydrogen gas and a small amount of dust. The dust absorbs the starlight from young, hot stars, heating the clouds to roughly 30 degrees above absolute zero (or 30 Kelvin). The light is re-emitted at much longer infrared and submillimeter wavelengths.

Thus, as much as 50 percent of the Universe’s light energy is infrared light from young, forming galaxies. In fact, there is as much energy in the Far Infrared Background as there is in the total optical light emitted by stars and galaxies in the Universe. Familiar optical images of the night sky are missing half of the picture describing the cosmic history of star formation, the authors say.

“BLAST has given us a new view of the Universe,” said Barth Netterfield of the University of Toronto, the Canadian principal investigator for BLAST, “enabling the BLAST team to make discoveries in topics ranging from the formation of stars to the evolution of distant Galaxies.”

In an accompanying News & Views piece, author Ian Smail, a computational cosmologist from Durham University in the UK, wrote that “the implication of these observations is that the active growth phase of most galaxies that are seen today is well behind them — they are declining into their equivalent of middle age.”

He also pointed out that studies of these extreme star-forming events in the early Universe will be aided by three major advances due over the next year or so: the submillimeter camera on the ESA/NASA Herschel Space Observatory; the development of large-format detectors working at submillimeter wavelengths, including one mounted on the James Clerk Maxwell Telescope; and the first phase of the Atacama Large Millimeter Array (ALMA).

“Such observations will allow astronomers to study the distribution of gas and star formation within these early galaxies,” Smail wrote, “which in turn will help to identify the physical process that triggers these ultraluminous bursts of star formation and their role in the formation of the galaxies we see in the Universe today.”

LEAD IMAGE CAPTION: The BLAST telescope just before launch in Antarctica. BLAST is in the foreground, next the 28 million cubic foot balloon, in the background is the volcano Mount Erebus. Credit: Mark Halpern

Source: Nature and a University of Pennsylvania press release (not yet online).  Images, photographs, sky maps and the complete study are available at the BLAST Web site.

Posted on by Anne Minard

Have a Cigar! New Observations of Messier 82

ESA’s space-borne X-ray observatory, XMM-Newton, has carried out an exclusive, 50-plus-hour observation of the starburst galaxy Messier 82, for the ‘100 Hours of Astronomy’ cornerstone project for the International Year of Astronomy 2009.

This first image shows bright knots in the plane of the galaxy, indicating a region of intense star formation, and emerging plumes of supergalactic winds glowing in X-rays. 

XMM-Newton has been studying the sky in X-ray, optical and ultraviolet wavelengths simultaneously, since its launch in December 1999.  

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Messier 82 has several names including: M82, the Cigar Galaxy and NGC 3034. Located in the constellation Ursa Major at a distance of about 12 million light-years, it is the nearest and one of the most active starburst galaxies, meaning it shows an exceptionally high rate of star formation.

M82 is interacting gravitationally with its neighbour, the spiral galaxy Messier 81, which is probably the cause for the violent starburst activity in the region around its center.

This second image of Messier 82, compiled from observations in the optical and infrared, shows the very bright starry disc of the galaxy with striking dust lanes. 

Source: ESA. More images, including a downloadable poster, are here. 100 Hours of Astronomy ended on Sunday, but the website still has loads of fun information. The International Year of Astronomy 2009 celebration is, of course, ongoing!

Posted on by Anne Minard

Hubble Scores a Ring

The NASA/ESA Hubble Space Telescope captured this image of NGC 7049 in the constellation of Indus, in the southern sky. Credit: NASA, ESA and W. Harris (McMaster University, Ontario, Canada)

Credit: NASA, ESA and W. Harris (McMaster University, Ontario, Canada)

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

The Hubble Space Telescope has captured a new image of NGC 7049, a mysterious looking galaxy that blurs the boundary between spiral and elliptical galaxies.

This picture, taken with a small ground-based camera, shows on its central-left portion the constellation of Indus, in the southern sky. Credit: A. Fujii
This picture, taken with a small ground-based camera, shows on its central-left portion the constellation of Indus, in the southern sky. Credit: A. Fujii

NGC 7049 is found in the constellation of Indus, and is the brightest of a cluster of galaxies, a so-called Brightest Cluster Galaxy. They represent some of the oldest and most massive galaxies, and they allow astronomers to study the elusive globular clusters lurking within.

Globular clusters are very dense and compact groupings of a few hundreds of thousands of young stars bound together by gravity. The globular clusters in NGC 7049 are seen as the sprinkling of small faint points of light in the galaxy’s halo. The halo – the ghostly region of diffuse light surrounding the galaxy – comprises myriad individual stars and provides a luminous background to the remarkable swirling ring of dust lanes surrounding NGC 7049’s core. The dust lanes appear as a lacy ring.

The image was taken by the Advanced Camera for Surveys on Hubble, which is optimized to hunt for galaxies and galaxy clusters in the remote and ancient Universe, at a time when our cosmos was very young. 

The constellation of Indus, or the Indian, is one of the least conspicuous in the southern sky. It was named in the 16th century by Dutch astronomer Petrus Plancius from observations made by Dutch navigator Pieter Dirkszoon Keyser and Dutch explorer Frederick de Houtman.

Source: NASA/ESA Hubble site

Posted on by Nancy Atkinson

Two Unique Galaxies Revealed During 100 Hours of Astronomy Event

Irregular Galaxy NGC 55. Credit: ESO. Click for larger version.

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As part of the International Year of Astronomy project, 100 Hours of Astronomy, the ambitious “Around the World in 80 Telescopes” event had a live webcast, going around the globe to some of the most advanced observatories on and off the planet. In celebration of this world tour of observatories, many of the telescopes are releasing wonderful, and previously unseen, astronomical images. Here are two observed by telescopes at the La Silla and Paranal observatories. Above is the irregular galaxy NGC 55, a galaxy that is about 70,000 light-years across, just a tad smaller than our own Milky Way, and below is NGC 7793, about half that size.

NGC 55 is a member of the prominent Sculptor group of galaxies in the southern constellation of Sculptor. By studying about 20 planetary nebulae in this image, a team of astronomers found that NGC 55 is located about 7.5 million light-years away. Planetary nebulae are the final blooming of Sun-like stars before their retirement as white dwarfs.

This striking image of NGC 55, obtained with the Wide Field Imager on the 2.2-metre MPG/ESO telescope at La Silla, is dusted with a flurry of reddish nebulae, created by young, hot massive stars. A large number of individual stars that can be counted within NGC 55.

Spiral Galaxy NGC 7793. Credit: ESO. Click for larger version.
Spiral Galaxy NGC 7793. Credit: ESO. Click for larger version.

The second image shows another galaxy belonging to the Sculptor group. This is NGC 7793, which has a chaotic spiral structure, unlike the class of grand-design spiral galaxies to which our Milky Way belongs. The image shows how difficult it is to identify any particular spiral arm in these chaotic structures, although it is possible to guess at a general rotating pattern. NGC 7793 is located slightly further away than NGC 55, about 12.5 million light-years from us.

NGC 7793 was observed with one of the workhorses of the ESO Paranal Observatory, the FORS instrument, attached to the Very Large Telescope.

Source: ESO

Posted on by Anne Minard

New Image Reveals M33 is Bigger Than Thought (and it’s Headed Our Way)

The Triangulum Galaxy. Image credit: NASA/JPL-Caltech/University of Arizona

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NASA’s Spitzer Space Telescope has captured this new image of M33, also known as the Triangulum Galaxy, and released it as part of the “Around the World in 80 Telescopes” event for the International Year of Astronomy.

Besides the pretty colors, the new image reveals something else about M33: it’s more than meets the eye.

M33 is located about 2.9 million light-years away in the constellation Triangulum. It is a member of what’s known as our Local Group of galaxies. Along with our own Milky Way and Andromeda, the group of about 50 galaxies travels together in the universe, bound to one another by gravity. In fact, M33 is one of the few galaxies that is moving toward the Milky Way despite the fact that space is expanding, causing most galaxies in the universe to grow farther and farther apart. 

The new image reveals M33 to be surprising large – bigger than its visible-light appearance would suggest. With its ability to detect cold, dark dust, Spitzer can see emission from cooler material well beyond the visible range of M33’s disk. Exactly how this cold material moved outward from the galaxy is still a mystery, but winds from giant stars or supernovas may be responsible. 

The image is a three-color composite showing infrared observations from two of Spitzer instruments. Stars appear as glistening blue gems (several of which are actually foreground stars in our own galaxy), while dust rich in organic molecules glows green. The diffuse orange-red glowing areas indicate star-forming regions, while small red flecks outside the spiral disk of M33 are probably distant background galaxies. 

As for the technical details, the blue parts of the image represents combined 3.6- and 4.5-micron light, and green shows light of 8 microns, both captured by Spitzer’s infrared array camera. Red is 24-micron light detected by Spitzer’s multiband imaging photometer.

Source: NASA’s Spitzer site

Posted on by Anne Minard

And the Winner Is …

Earlier this week, the Hubble Space Telescope photographed the winning target in the Space Telescope Science Institute’s “You Decide” competition in celebration of the International Year of Astronomy.

The winning object, above, received 67,021 votes out of the nearly 140,000 votes cast for the six candidate targets.


Arp 274, also known as NGC 5679, is a system of three galaxies that appear to be partially overlapping in the image, although they may be at somewhat different distances. The spiral shapes of two of these galaxies appear mostly intact. The third galaxy (to the far left) is more compact, but shows evidence of star formation.

Two of the three galaxies are forming new stars at a high rate. This is evident in the bright blue knots of star formation that are strung along the arms of the galaxy on the right and along the small galaxy on the left.

The largest component is located in the middle of the three. It appears as a spiral galaxy, which may be barred. The entire system resides at about 400 million light-years away from Earth in the constellation Virgo.

Hubble’s Wide Field Planetary Camera 2 was used to image Arp 274. Blue, visible, and infrared filters were combined with a filter that isolates hydrogen emission. The colors in this image reflect the intrinsic color of the different stellar populations that make up the galaxies. Yellowish older stars can be seen in the central bulge of each galaxy. A bright central cluster of stars pinpoint each nucleus. Younger blue stars trace the spiral arms, along with pinkish nebulae that are illuminated by new star formation. Interstellar dust is silhouetted against the starry population. A pair of foreground stars inside our own Milky Way are at far right.

The International Year of Astronomy is the celebration of the 400th anniversary of Galileo’s first observations with a telescope. The ongoing “100 Hours of Astronomy,” April 2 to 5, is part of the fun, geared toward encouraging as many people as possible to experience the night sky.

Image credit: NASA, ESA, and M. Livio and the Hubble Heritage Team (STScI/AURA)

For images, videos, and more information about Arp 274, visit the Hubble site,  the Hubble Heritage Project , NASA’s Hubble site or 100 Hours of Astronomy


Posted on by Nancy Atkinson

Astronomers Compile Most Detailed Map of Nearby Universe

The clustering pattern of about 100,000 nearby galaxies, revealed by the 6dF Galaxy Survey. Each galaxy is shown as a dot. The galaxy we live in is at the centre of the pattern. Credit: Dr Chris Fluke, Centre for Astrophysics and Supercomputing, Swinburne University of Technology.

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A new detailed map of the nearby Universe reveals not only where local galaxies are currently, but where they are heading, how fast and why. “It’s like taking a snapshot of wildebeest on the African plain,” said Dr. Heath Jones of the Anglo-Australian Observatory (AAO), lead scientist for the Six-Degree Field Galaxy Survey (6dFGS), the most detailed survey of nearby galaxies to date. “We can tell which waterholes they’re heading to, and how fast they’re traveling.”

The project was a collaboration between astronomers from Australia, the UK and the USA. The survey was carried out with the 1.2-m UK Schmidt Telescope, which is operated by Siding Spring Observatory in New South Wales, Australia. Broader and shallower than previous comparable surveys (it covered twice as much sky as the Sloan Digital Sky Survey) it has recorded the positions of more than 110,000 galaxies over more than 80% of the Southern sky, out to about two thousand million light-years from Earth, (a redshift of 0.15).

Galaxies are tugged around by each other’s gravity. By measuring the galaxies’ movements, the researchers were able to map the gravitational forces at work in the local Universe, and so show how matter, both seen and unseen, is distributed.

Giant superclusters of galaxies are huge concentrations of mass, but they can’t be weighed accurately by looking at their light alone.

“Light can be obscured, but you can’t hide gravity,” said Dr. Jones.

The UK Schmidt Telescope. Photo: Shaun Amy
The UK Schmidt Telescope. Photo: Shaun Amy

The survey shows strings and clusters of nearby galaxies on large scales in unprecedented detail, and has revealed more than 500 voids—”empty” areas of space with no galaxies.

The special aspect of this survey is that it will let the researchers disentangle two causes of galaxy movements.

As well as being pulled on by gravity, galaxies also ride along with the overall expansion of the Universe.

For about 10% of their galaxies, the 6dFGS researchers will tease apart these two velocity components: the one associated with the Universe’s expansion, and the one representing a galaxy’s individual, “peculiar”, motion.

“The peculiar velocities collected as part of this survey number more than five times as many as in any previous survey,” said Professor Elaine Sadler of the University of Sydney, a 6dFGS team member.

Source: Anglo-Australian Observatory

Posted on by Nancy Atkinson

Help Galaxy Zoo Reach Its Goal!

The "Zoonometer"

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Reminiscent of a telethon or a community fundraiser, Galaxy Zoo has challenged the public to complete one million classification clicks of galaxies from the Sloan Digital Sky Survey during the 100 Hours of Astronomy. The clock started ticking at 12:00 GMT on Wednesday, April 1st, with the challenge ending at 16:00 GMT on Sunday April 5th. The Galaxy Zoo site even includes a thermometer-like gadget called the Zoonometer to provide up-to-the minute ticks on the number of clicks. If you have just returned from a cave on Mars and haven’t heard of Galaxy Zoo, or if you don’t know what the 100 Hours of Astronomy is about, keep reading. Otherwise, head on over to Galaxy Zoo and start clicking!

Galaxy Zoo was launched in July 2007, with a data set of a million galaxies, imaged with a robotic telescope, the Sloan Digital Sky Survey. In order to understand how these galaxies formed, the idea was to get the public to help classify them according to their shapes. The human brain can do this task better than even the fastest computer. With so many galaxies, the team thought that it might take at least two years for visitors to the site to work through them all. Within 24 hours of launch, the site was receiving 70,000 classifications an hour, and more than 50 million classifications were received by the project during its first year, from almost 150,000 people. With the public’s help the Zoo team has published six papers from the findings, and have received viewing time with other, bigger telescopes to clarify the discoveries.

Zoo 2 launched a few months ago, and focuses on the nearest, brightest and most beautiful galaxies, and asks users to make more detailed classifications.

100 Hours of Astronomy is an event of the International Year of Astronomy that wants to get as many people as possible to look through a telescope – just as Galileo did 400 years ago. This four-day event encompasses astronomy clubs, groups, individuals, observatories, science centers and more around the world as they reach out to the public to achieve this common goal. There’s lots of great events, so check out Tammy’s article to find out more, or check out the 100 Hours of Astronomy website – but hurry – you’ve only got until Sunday April 5th to participate!

Posted on by Anne Minard

New Study: Some Massive Galaxies Were Practically Born That Way

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New research is casting doubt on the prevailing view that the heaviest galaxies in the universe started out small and gained mass by devouring other matter that ventured too close.

Peering at galaxies two-thirds of the way back in time to the Big Bang, an international team of astronomers is suggesting that some of the giants we see today were just as massive in that earlier age as they are now.

The new findings were released today in the journal Nature.

Lead author Chris Collins, an astronomer at the United Kindgdom’s Liverpool John Moores University, and his colleagues made their discovery using one of the largest optical telescopes in the World, called Subaru (named after the Japanese word for the Pleiades star cluster), located on the Island of Hawaii and owned by the National Observatory of Japan.

They focused on brightest cluster galaxies (BCGs), located at the centers of galaxy clusters. The massive galaxies constitute a separate population from bright elliptical galaxies, and both their predictability and extreme luminosity have motivated their use as standard candles for cosmology, the authors point out.

Analysing the light from these remote galaxies, the astronomers effectively weighed them and found that despite feeding on a constant diet of small galaxies, the heaviest galaxies have not increased their weight over the last 9 billion years. In a universe whose age is 13.7 billion years old, these results spark a debate as to how these galaxies put on so much weight in the first few billion years after the Big Bang.

“Current predictions using simulations run on super computers suggest that at such a young age these galaxies should be only 20 percent of their final weight, so to find galaxies so large suggests that galaxy formation is a much more rapid process than we previously thought,” Collins said, “and perhaps the theories are missing some important physics.”

John Stott, Collin’s colleague at LJMU and a co-author on the paper, said the team was “surprised to find that the largest and brightest galaxies in the Universe have remained essentially unchanged for the last 9 billion years, having grown rapidly soon after the Big Bang.”

One possibility being considered is that the galaxies formed by the collapse of an already massive cloud at the dawn of the universe.

MORE ABOUT LEAD IMAGE: The image shows the central 1.5 x 1.5 arc min of the cluster corresponding to 0.75 Mpc at this distance. The clusters X-ray emission is used to pinpoint the location of the brightest galaxy in the cluster as shown by the green contours which represent the X-ray intensity as measured by the XMM-Newton X-ray satellite.

Source: LJMU’s Astrophysics Research Institute

Posted on by Nancy Atkinson

Galaxy Zoo Team Discovers New Class of Galaxy Cluster

Unusual galaxy cluster discovered by Galaxy Zoo volunteers. Credit: Galaxy Zoo

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A new class of galaxy clusters has been identified by volunteers and astronomers of the Galaxy Zoo project, together with the Sloan Digital Sky Survey. These clusters are rare, and have apparently gone unnoticed before, despite their unusual linear properties. Astronomers believe the identification of these types of clusters depend on the visual inspection of large numbers of galaxies, a feat which has only recently been made possible by the Galaxy Zoo project, and this may explain why they haven’t been discovered until now. “Space is, after all, really big,” said the Galaxy Zoo scientists, “and full of really surprising things.”

These clusters are unusually elongated, possess young and highly dynamic galaxy populations, and most unexpectedly, present neatly typeset, left-justified, messages written in the English language. One sample even includes punctuation similar to an exclamation mark. (See image below.)

SDSS colour composite image (vri) for another unusual galaxy cluster, at RA = ?2h61m12s, Dec = +124?17?72?? , identified by Galaxy Zoo participants.
SDSS colour composite image (vri) for another unusual galaxy cluster, at RA = ?2h61m12s, Dec = +124?17?72?? , identified by Galaxy Zoo participants.

The occurrence of these new galaxy phenomena could potentially lend support to some of the more exotic models for Dark Energy or modified gravity, which one of the Universe Today trolls may find extremely notable. More controversially, as most occurrences of English sentences are considered to be the work of intelligent beings, the existence of these messages might indicate intelligent life beyond our own.

Conversely, however, they could indicate that many phenomena usually attributed to intelligent life on Earth may actually occur spontaneously, without any thought necessarily being involved at all. While these new discoveries may have profound implications for cosmology, the most important thing to consider is the date of this publication, being April 1.

The Galaxy Zoo team stresses that, despite their implausible appearance, the galaxies comprising each individual character in the figures presented here are taken directly from the SDSS multicolour composite imaging. Note, however, that some degree of translation and rotation has been performed to the individual characters, for presentation purposes.