The Ancient Massive Galaxy Mystery – 80 percent Appear Extremely Active and Growing

May 16, 2012 By Leave a Comment

NASA’s Chandra X-ray Observatory image above of the distant galaxy 3C295 shows an explosive galaxy enveloped by a vast cloud of fifty million degree gas. The gas cloud, which is visible only with an X-ray telescope, contains more than a hundred gala

xies and enough material to make a thousand more. The galaxies are too cool to be visible in X-rays. Roughly two million light years in diameter, the cloud and its cluster of galaxies are among the most massive objects in the universe. It is so distant that we see it as it was five billion years ago.

Important research at Tufts University in 2010 revealed that some of the most massive galaxies in the Universe may have formed billions of years earlier than the current models predicted. The identified galaxies were five to ten times more massive than our own Milky Way.
“We found a relatively large number of very massive, highly luminous galaxies that existed almost 12 billion years ago when the universe was still very young, about 1.5 billion years old. These results appear to disagree with the latest predictions from models of galaxy formation and evolution,” said Tufts astrophysicist Danilo Marchesini, lead author on the paper and assistant professor of physics and astronomy at the Tufts School of Arts and Sciences.

“Current understanding of the physical processes responsible in forming such massive galaxies has difficulty reproducing these observations.”

Collaborating with Marchesini were researchers from Yale University, Carnegie Observatories, Leiden University, Princeton University, the University of Kansas and the University of California-Santa Cruz.
Redshift refers to the phenomenon of a light wave stretching and moving toward longer wavelengths (the red end of the spectrum) as the emitting object travels away from an observer (Doppler Effect). This is similar to the pitch of a siren getting lower as the siren moves away.

The redshift of distant galaxies is due to the expansion of the universe. The larger the redshift, the more distant the galaxy is, or the farther back in time we are observing. The larger the redshift, the younger the universe in which the galaxy is observed.

By complementing existing data with deep images obtained through a new system of five customized near-infrared filters, the researchers were able to get a more complete view of the galaxy population at this early stage and more accurately characterize the sampled galaxies.

The researchers made another surprising discovery: More than 80 percent of these massive galaxies show very high infrared luminosities, which indicate that these galaxies are extremely active and most likely in a phase of intense growth. Massive galaxies in the local universe are instead quiescent and do not form stars at all.

The researchers noted that there are two likely causes of such luminosity: New stars may be forming in dust-enshrouded bursts at rates of a few thousand solar masses per year. This would be tens to several hundreds of times greater than the rates estimated by spectral energy distribution (SED) modeling. Alternatively, the high infrared luminosity could be due to highly-obscured active galactic nuclei (AGN) ferociously accreting matter onto rapidly growing super-massive black holes at the galaxies’ centers.

There might be an explanation that would at least partially reconcile observations with model-predicted densities. The redshifts of these massive galaxies, and hence their distances, were determined from the SED modeling and have not yet been confirmed spectroscopically. Redshift measurements from SED modeling are inherently less accurate than spectroscopy. Such “systemic uncertainties” in the determination of the distances of these galaxies might still allow for approximate agreement between observations and model predictions. But this is pure speculation, and highly doubtful.

If half of the massive galaxies are assumed to be slightly closer, at redshift z=2.6, when the universe was a bit older (2.5 billion years old) and very dusty (with dust absorbing much of the light emitted at ultra-violet and optical wavelengths), then the disagreement between observations and model predictions becomes only marginally significant.

However, the discovery of the existence of such massive, old and very dusty galaxies at redshift z=2.6 would itself be a notable discovery.

“Either way, it is clear that our understanding of how massive galaxies form is still far from satisfactory,” said Marchesini. “The existence of these galaxies so early in the history of the universe, as well as their properties, can provide very important clues on how galaxies formed and evolved shortly after the Big Bang.”

In prior findings, it appears that the early universe was a place of puzzling extremes and seeming contradictions. That’s the conclusion scientists are drawing from new infrared observations of a very distant, unusually bright and massive elliptical galaxy. This galaxy was spotted 10 billion light years away, and gives us a glimpse of what the Universe looked like when it was only about one-quarter of its current age.

Measurements show that the galaxy is as large and equally dense as elliptical galaxies that can be found much closer to us. Coupled with recent observations by a different research team – which found a very compact and extremely dense elliptical galaxy in the early Universe – the findings deepen the puzzle over how ‘fully grown’ galaxies can exist alongside seemingly ‘immature’ compact galaxies in the young universe.

‘What our observations show is that alongside these compact galaxies were other ellipticals that were anything up to 100 times less dense and between two and five times larger – essentially ‘fully grown’ — and much more like the ellipticals we see in the local universe around us,’ explains Michele Cappellari of Oxford University’s Department of Physics. ‘The mystery is how these two different extremes, ‘grown up’ and seemingly ‘immature’ ellipticals, co-existed so early on in the evolution of the Universe.’

Elliptical galaxies, which are regular in shape, can be over ten times as massive as spiral galaxies such as our own Milky Way and contain stars which formed over 10 billion years ago. One way of checking the density of such galaxies is to use the infrared spectrum they emit to measure the spread of the velocities of their stars, which has to balance the pull of gravity.

Measurements of a distant compact elliptical galaxy have shown that its stars were dispersing at a velocity of about 500 km per second, consistent with its size but unknown in local galaxies.

The new study, using the 8.3-m Japanese Subaru telescope in Hawaii, found a ‘fully grown’ elliptical with stars dispersing at a velocity of lower than 300 km per second, much more like similar galaxies close to us.

‘Our next step is to use the Subaru telescope to find the relative proportion of these two extremes, fully grown and compact ellipticals, and see how they fit in with the timeline of the evolution of the young Universe,’ Michele tells us. ‘Hopefully this will give us new insights into solving this cosmic puzzle.’

In earlier surveys, the Advanced camera for Survey (ACS) and the Infrared Camera for Multi-object Spectrometer (NICMOS), the Hubble Ultra Deep Field (HUDF) have revealed the presence of estimated 10,000 fully formed galaxies in a patch of sky in the constellation, Formax – a region just below the constellation, Orion. According to the NASA, these fully formed galaxies emerged just 700 million years after the Big Bang, when the universe was barely 5% of its current age.

Also, using ISAAC near- infrared instrument aboard ESO’s Very Large Telescope(VLT), and the phenomenon of gravitational lensing, a team of French and Swiss astronomers using Very Large Telescope (VLT) of the European Southern Observatory, have identified an extremely faint galaxy, Abell 1835 (image left).

According to interpretations, Abell 1835 must have formed just 460 million years after the universe was born, during the “Dark Age” when the first stars and galaxies were supposedly being born More recently, fully formed galaxies were discovered which are at a greater distance, over 13.1 billion light years (American Astronomical Society 2010), and which may have already been billions of years in age, over 13 billion years ago .

There are fully formed distant galaxies that must have already been billions of years old over 13 billion years ago; which would make them older than the Big Bang. Then there is the problem of the oldest globular clusters so far discovered, whose ages are in excess of 16 billion years. The Milky Way and other galaxies are also so old that they must have formed before the so called “Dark Ages” and thus almost immediately after the Big Bang, which is not consistent with theory.

Using the Infrared Array Camera (IRAC) aboard NASA’s Spitzer Space Telescope, astronomers have detected about a dozen very red galaxies at a distance of 10 to12 billion light years from Earth (cfa Harvard 2005). According to the Big Bang model, these galaxies existed when the universe was only about 1/5 of its present age of 13.75 billion years.

The unpredicted existence of “red and dead” galaxies so early in the universe challenges Big Bang theories relating to galaxy formation (cfa Harvard 2005). Analysis show that galaxies exhibit a large range of properties. Young galaxies with and without lots of dust, and old galaxies with and without dust.There is as much variety in the so called “early universe” as we see around “today” in galaxies closer to Earth.

Moreover, Spitzer Space Telescope, which is sensitive to the light from older and redder stars, has also revealed evidence for mature stars in less massive galaxies at similar distances (Spitzer 2005), when the Universe was supposedly less than one billion years old.

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”Missing matter” in nearby Universe located?

May 12, 2010 By Leave a Comment

Washington, May 12 (ANI): Astronomers have announced the discovery of a vast reservoir of intergalactic gas nearly 400 million light-years from the Earth.

Scientists used observations of NASA”s Chandra X-ray Observatory and ESA”s XMM-Newton to come up with the finding.

The find is the strongest evidence yet that the “missing matter” in the nearby Universe is located in an enormous web of hot, diffuse gas.

This missing matter – which is different from dark matter – comprises baryons, the particles, such as protons and electrons, that are found on the Earth, in stars, gas, galaxies, and so on.

A variety of measurements of distant gas clouds and galaxies have provided a good estimate of the amount of this “normal matter” present when the universe was only a few billion years old.

However, an inventory of the much older, nearby universe has turned up only about half as much normal matter, an embarrassingly large shortfall.

The mystery then is where does this missing matter reside in the nearby Universe?

This latest work supports predictions that it is mostly found in a web of hot, diffuse gas known as the Warm-Hot Intergalactic Medium (WHIM).

Scientists think the WHIM is material left over after the formation of galaxies, which was later enriched by elements blown out of galaxies.

Lead author of the study Taotao Fang, of the University of California at Irvine, said: “Evidence for the WHIM is really difficult to find because this stuff is so diffuse and easy to see right through.

“This differs from many areas of astronomy where we struggle to see through obscuring material.”

To look for the WHIM, the researchers examined X-ray observations of a rapidly growing supermassive black hole known as an active galactic nucleus, or AGN.

This AGN, which is about two billion light-years away, generates immense amounts of X-ray light as it pulls matter inwards.

Lying along the line of sight to this AGN, at a distance of about 400 million light-years, is the so-called Sculptor Wall.

This “wall”, which is a large diffuse structure stretching across tens of millions of light-years, contains thousands of galaxies and potentially a significant reservoir of the WHIM if the theoretical simulations are correct.

The WHIM in the wall should absorb some of the X-rays from the AGN as they make their journey across intergalactic space to Earth.

Using new data from Chandra and previous observations with both
Chandra and XMM-Newton, absorption of X-rays by oxygen atoms in the WHIM has clearly been detected by Fang and his colleagues.

The characteristics of the absorption are consistent with the distance of the Sculptor Wall as well as the predicted temperature and density of the WHIM. (ANI)

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Supermassive black hole gets kicked out of galaxy

May 12, 2010 By Leave a Comment

Washington, May 12 (ANI): An international team of astronomers has discovered what appears to be a supermassive black hole leaving its home galaxy at high speed.

For her final-year project, undergraduate student Marianne Heida of the University of Utrecht, worked at the SRON Netherlands Institute for Space Research, using the Chandra Source Catalog (made using the orbiting Chandra X-ray Observatory) to compare hundreds of thousands of sources of X-rays with the positions of millions of galaxies.

Normally each galaxy contains a supermassive black hole at its center. The material that falls into black holes heats up dramatically on its final journey and often means that black holes are strong X-ray sources.

X-rays are also able to penetrate the dust and gas that obscures the center of a galaxy, giving astronomers a clear view of the region around the black hole, with the bright source appearing as a starlike point.

Looking at one galaxy in the catalog, Marianne noticed that the point of light was offset from the center and yet was so bright that it could well be associated with a supermassive black hole.

The black hole appears to be in the process of being expelled from its galaxy at high speed. Given that these objects can have masses equivalent to 1 billion Suns, it takes a special set of conditions to cause this to happen.

Marianne”s newly-discovered object is probably the result of the merger of two smaller black holes. Supercomputer models suggest that the larger black hole that results is shot away at high speed, depending on the direction and speed in which the two black holes rotate before their collision.

In any case, it provides a fascinating insight into the way in which supermassive black holes develop in them center of galaxies.

Marianne”s research — which was carried out under the supervision of SRON researcher Peter Jonker — suggests this discovery may be only the tip of the iceberg, with others subject to future confirmation using the Chandra Observatory.

“We have found many more objects in this strange class of X-ray sources. With Chandra we should be able to make the accurate measurements we need to pinpoint them more precisely and identify their nature,” she said.

Finding more recoiling black holes will provide a better understanding of the characteristics of black holes before they merge.

In future, it might even be possible to observe this process with the planned LISA satellite, an instrument capable of measuring the gravity waves that the two merging black holes emit.

Ultimately this information will let scientists know if supermassive black holes in the cores of galaxies really are the result of many lighter black holes merging together.

This discovery appears in a paper in the journal Monthly Notices of the Royal Astronomical Society. (ANI)

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Fresh evidence for ‘survivor’ black holes from NASA

April 30, 2010 By Leave a Comment

Washington, April 30 (ANI): NASA”s Chandra X-ray Observatory and ESA”s XMM-Newton has brought out new evidence about the existence of two mid-sized black holes close to the center of a nearby starburst galaxy.

The black holes, known as ‘survivor’ black holes, avoided falling into the center of the galaxy and could be examples of the seeds required for the growth of supermassive black holes in galaxies, including the one in the Milky Way.

The researchers who were on a look-out for the black holes that are in-between recently found signatures in X-ray data of two mid-sized black holes in the starburst galaxy M82 located 12 million light years from Earth.

“This is the first time that good evidence for two mid-sized black holes has been found in one galaxy,” said Hua Feng of the Tsinghua University in China, who led two papers describing the results.

“Their location near the center of the galaxy might provide clues about the origin of the Universe”s largest black holes – supermassive black holes found in the centers of most galaxies,” Feng added.

The evidence for these two ‘survivor’ black holes comes from how their X-ray emission varies over time and analysis of their X-ray brightness and spectra, i.e., the distribution of X-rays with energy.

Chandra and XMM-Newton data has shown that the X-ray emission for one of these objects changes in a distinctive manner similar to stellar-mass black holes found in the Milky Way.

Thus, the team estimated this black hole”s mass is between 12,000 and 43,000 times the mass of the Sun. This mass is large enough for the black hole to generate copious X-rays by pulling gas directly from its surroundings.

The black hole is located at a projected distance of 290 light years from the center of M82.

The second object, located 600 light years in projection away from the center of M82, was observed by both Chandra and XMM-Newton.

“This result is one of the strongest pieces of evidence to date for the existence of an intermediate-mass black hole. This looks just like well-studied examples of stellar-mass black holes, except for being more than 20 times as massive,” Feng said. (ANI)

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Awesome power of supermassive black holes revealed

April 17, 2010 By Leave a Comment

Washington, April 17 (ANI): Nottingham University researchers have shed new light on the super destructive capacity of black holes.

For the study, Asa Bluck in the School of Physics and Astronomy and colleagues, used images of unprecedented depth and resolution from the Hubble Space Telescope and the Chandra X-Ray Observatory to detect black holes in distant galaxies.

Scientists looked for galaxies emitting high levels of radiation and x-rays – a classic signature of black holes devouring gas and dust through accretion, or attracting matter gravitationally.

As this matter swirls around the event horizon of a black hole it heats up and radiates energy – as an accretion disc.

In supermassive black holes this radiation can reach huge proportions, emitting X-ray radiation in far greater quantities then is emitted by the rest of the objects in the galaxy combined – meaning that the black hole ”shines” far brighter than the entire galaxy it lies at the heart of.

In fact, the amount of energy released is sufficient to strip the galaxy of gas at least 25 times over.

Results have also demonstrated that the vast majority of the X-ray radiation present in the universe is produced in these accretion discs surrounding supermassive black holes, with a small proportion produced by all other objects, including galaxies and neutron stars.

The accretions discs surrounding supermassive black holes produce so much energy that they heat up the cold gases lying at the heart of massive galaxies.

The accretion disc shines across all wavelengths – from radio waves to gamma waves.

This speeds up the random motions of the gas, making it rise in temperature and pushing it away from the galactic centre, where it becomes less dense.

Gas needs to be cold and dense to collapse under gravity to form new stars, this resulting hot, low-density material must cool down before gravity will take effect – a process which would take longer than the age of the universe to achieve.

Old stars are therefore left to die out with no new stars replacing them, leaving the galaxy to grow dark and die.

And by pushing gas away from the galactic centre, the accretion disc starves the supermassive black hole of new material to devour, leading to its eventual demise.

Asa Bluck, a PhD student at the University and a Fellow of the Royal Astronomical Society, said: “It”s thought that black holes form inside their host galaxies and grow in proportion to them, forming an accretion disc which will eventually destroy the host. In this sense they can be described as viral in nature.

“Massive galaxies are in the minority in our visible universe – about one in a thousand galaxies is thought to be massive, but it may be much less. And at least a third of these have supermassive black holes at their centre. That”s why it”s so interesting that this type of black hole produces most of the X-ray light in the universe. They are the minority but they dominate energy output.”

The study, a collaboration between researchers at The University of Nottingham and Imperial College London, was presented at the Royal Astronomical Society National Astronomy Meeting in Glasgow. (ANI)

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Astronomers discover most primitive supermassive black holes known

March 19, 2010 By Leave a Comment

Washington, March 19 (ANI): Astronomers, using NASA’s Spitzer Space Telescope, have discovered two of the earliest and most primitive supermassive black holes known.

The discovery will provide a better understanding of the roots of our universe, and how the very first black holes, galaxies and stars all came to be.

“We have found what are likely first-generation quasars, born in a dust-free medium and at the earliest stages of evolution,” said Linhua Jiang, a research associate at the University of Arizona’s Steward Observatory.

Quasars are basically hungry supermassive black holes.

As grimy and unkempt as our present-day universe is today, scientists believe the very early universe didn’t have any dust, which tells them that the most primitive quasars should also be dust-free.

But nobody had seen such pristine quasars – until now.

Spitzer has identified two such immaculate quasars – the smallest quasars on record – about 13 billion light-years away from Earth.

The two quasars, called J0005-0006 and J0303-0019, were first unveiled by Xiaohui Fan, a UA professor of astronomy who coauthored the paper.

NASA’s Chandra X-ray Observatory had also observed X-rays from one of the objects.

X-rays, ultraviolet and optical light stream out from quasars as the gas surrounding them is swallowed.

“As surrounding gas is swallowed by the supermassive black hole, it emits an enormous amount of light, making those quasars detectable literally at the edge of the observable universe,” said Fan.

When Jiang and his colleagues set out to observe J0005-0006 and J0303-0019 with Spitzer between 2006 and 2009, their targets didn’t stand out much from the usual quasar bunch.

Spitzer measured infrared light from the objects along with 18 others, all belonging to a class of the most distant quasars known.

Each quasar is anchored by a supermassive black hole weighing more than 100 million suns.

The Spitzer data showed that, of the 20 quasars, J0005-0006 and J0303-0019 lacked characteristic signatures of hot dust.

“We think these early black holes are forming around the time when the dust was first forming in the universe, less than one billion years after the Big Bang,” Fan said.

“The primordial universe did not contain any molecules that could coagulate to form dust. The elements necessary for this process were produced and pumped into the universe later by stars,” he added. (ANI)

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Radiation from massive stars may trigger many more stars than previously thought

August 13, 2009 By Leave a Comment

Washington, August 13 (ANI): A new study from two of NASA’s Great Observatories has shown that radiation from massive stars may trigger the formation of many more stars than previously thought.

While astronomers have long understood that stars and planets form from the collapse of a cloud of gas, the question of the main causes of this process has remained open.

One option is that the cloud cools, gravity gets the upper hand, and the cloud falls in on itself.

The other possibility is that a “trigger” from some external source – like radiation from a massive star or a shock from a supernova – initiates the collapse.

Some previous studies have noted a combination of triggering mechanisms in effect.

By combining observations of Cepheus B from the Chandra X-ray Observatory and Spitzer Space Telescope, researchers have taken an important step in addressing this question.

Cepheus B is a cloud of mainly cool molecular hydrogen located about 2,400 light years from the Earth.

There are hundreds of very young stars inside and around the cloud – ranging from a few millions years old outside the cloud to less than a million in the interior – making it an important testing ground for star formation.

“Astronomers have generally believed that it’s somewhat rare for stars and planets to be triggered into formation by radiation from massive stars,” said Konstantin Getman of Penn State University, and lead author of the study. “Our new result shows this belief is likely to be wrong,” he added.

This particular type of triggered star formation had previously been seen in small populations of a few dozen stars, but the latest result is the first time it has been clearly observed in a rich population of several hundred stars.

The new study suggests that star formation in Cepheus B is mainly triggered by radiation from one bright, massive star outside the molecular cloud.

According to theoretical models, radiation from this star would drive a compression wave into the cloud triggering star formation in the interior, while evaporating the cloud’s outer layers.

The Chandra-Spitzer analysis revealed slightly older stars outside the cloud while the youngest stars with the most protoplanetary disks congregate in the cloud interior – exactly what is predicted from the triggered star formation scenario.

“We essentially see a wave of star and planet formation that is rippling through this cloud,” said co-author Eric Feigelson, also of Penn State. “Outside the cloud, the stars probably have newly born planets while inside the cloud the planets are still gestating,” he added. (ANI)

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Astronomers see high-speed galaxy collision in action

July 10, 2009 By Leave a Comment

Washington, July 10 (ANI): Astronomers at the Chandra X-ray Observatory have spotted a galaxy collision in action, with one galaxy passing through the core of other galaxies at almost 2 million miles per hour.

The image obtained is of Stephan’s Quintet, a compact group of galaxies discovered about 130 years ago and located about 280 million light years from Earth.

Four of the galaxies in the group are visible in the optical image from the Canada-France-Hawaii Telescope.

A labeled version identifies these galaxies (NGC 7317, NGC 7318a, NGC 7318b and NGC 7319) as well as a prominent foreground galaxy (NGC 7320) that is not a member of the group.

The galaxy NGC 7318b is passing through the core of galaxies at almost 2 million miles per hour, and is thought to be causing the ridge of X-ray emission by generating a shock wave that heats the gas.

Additional heating by supernova explosions and stellar winds has also probably taken place in Stephan’s Quintet.

A larger halo of X-ray emission, detected by ESA’s (European Space Agency’s) XMM-Newton could be evidence of shock heating by previous collisions between galaxies in this group.

Some of the X-ray emissions are likely caused by binary systems containing massive stars that are losing material to neutron stars or black holes.

Stephan’s Quintet provides a rare opportunity to observe a galaxy group in the process of evolving from an X-ray faint system dominated by spiral galaxies to a more developed system dominated by elliptical galaxies and bright X-ray emission.

According to scientists, being able to witness the dramatic effect of collisions in causing this evolution is important for increasing the understanding of the origins of the hot, X-ray bright halos of gas in groups of galaxies.

Stephan’s Quintet shows an additional sign of complex interactions in the past, notably the long tails visible in the optical image.

These features were probably caused by one or more passages through the galaxy group by NGC 7317. (ANI)

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Mystery of Milky Way’s particle accelerators solved

June 27, 2009 By Leave a Comment

Munich, June 26 (ANI): With help of a unique “ballistic study” that combines data from ESO’s Very Large Telescope and NASA’s Chandra X-ray Observatory, astronomers have now solved a long-standing mystery of the Milky Way’s particle accelerators.

The study shows that cosmic rays from our galaxy are very efficiently accelerated in the remnants of exploded stars.

Galactic cosmic rays come from sources inside our home galaxy, the Milky Way, and consist mostly of protons moving at close to the speed of light, the “ultimate speed limit” in the Universe.

“It has long been thought that the super-accelerators that produce these cosmic rays in the Milky Way are the expanding envelopes created by exploded stars, but our observations reveal the smoking gun that proves it,” said Eveline Helder from the Astronomical Institute Utrecht of Utrecht University in the Netherlands, the first author of the new study.

“You could even say that we have now confirmed the caliber of the gun used to accelerate cosmic rays to their tremendous energies,” said collaborator Jacco Vink, also from the Astronomical Institute Utrecht.

“When a star explodes in what we call a supernova a large part of the explosion energy is used for accelerating some particles up to extremely high energies,” said Helder.

“The energy that is used for particle acceleration is at the expense of heating the gas, which is therefore much colder than theory predicts,” she added.

The researchers looked at the remnant of a star that exploded in AD 185, as recorded by Chinese astronomers.

The remnant, called RCW 86, is located about 8200 light-years away towards the constellation of Circinus (the Drawing Compass). It is probably the oldest record of the explosion of a star.

Using ESO’s Very Large Telescope, the team measured the temperature of the gas right behind the shock wave created by the stellar explosion.

They measured the speed of the shock wave as well, using images taken with NASA’s X-ray Observatory Chandra three years apart.

They found it to be moving at between 10 and 30 million km/h, between 1 and 3 percent the speed of light.

The temperature of the gas turned out to be 30 million degrees Celsius.

This is quite hot compared to everyday standards, but much lower than expected, given the measured shock wave’s velocity. This should have heated the gas up to at least half a billion degrees.

“The missing energy is what drives the cosmic rays,” concluded Vink. (ANI)

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“Cosmic blobs” a result of growing supermassive black holes

June 27, 2009 By Leave a Comment

Washington, June 25 (ANI): New data obtained from NASA’s Chandra X-ray Observatory and other telescopes has pinpointed the source of “cosmic blobs” as growing supermassive black holes.

This discovery helps resolve the true nature of gigantic blobs of gas observed around very young galaxies.

About a decade ago, astronomers discovered immense reservoirs of hydrogen gas, which they named “blobs”, while conducting surveys of young distant galaxies.

The blobs are glowing brightly in optical light, but the source of immense energy required to power this glow and the nature of these objects were unclear.

A long observation from Chandra has identified the source of this energy for the first time.

The X-ray data show that a significant source of power within these colossal structures is from growing supermassive black holes partially obscured by dense layers of dust and gas.

The fireworks of star formation in galaxies are also seen to play an important role, thanks to Spitzer Space Telescope and ground-based observations.

“For ten years, the secrets of the blobs had been buried from view, but now we’ve uncovered their power source,” said James Geach of Durham University in the United Kingdom, who led the study.

“Now, we can settle some important arguments about what role they played in the original construction of galaxies and black holes,” he added.

Galaxies are believed to form when gas flows inwards under the pull of gravity and cools by emitting radiation.

This process should stop when the gas is heated by radiation and outflows from galaxies and their black holes.

Blobs could be a sign of this first stage, or of the second.

Based on the new data and theoretical arguments, Geach and his colleagues show that heating of gas by growing supermassive black holes and bursts of star formation, rather than cooling of gas, most likely powers the blobs.

The implication is that blobs represent a stage when the galaxies and black holes are just starting to switch off their rapid growth because of these heating processes.

This is a crucial stage of the evolution of galaxies and black holes – known as “feedback” – and one that astronomers have long been trying to understand.

“We’re seeing signs that the galaxies and black holes inside these blobs are coming of age and are now pushing back on the infalling gas to prevent further growth,” said coauthor Bret Lehmer, also of Durham.

“Massive galaxies must go through a stage like this or they would form too many stars and so end up ridiculously large by the present day,” he added. (ANI)

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Cosmic “ghost” found lurking around supermassive black hole

May 29, 2009 By Leave a Comment

Washington, May 29 (ANI): NASA’s Chandra X-ray Observatory has found a cosmic “ghost” lurking around a distant supermassive black hole, which is the first detection of such a high-energy apparition, and may be evidence of a huge eruption produced by the black hole.

The X-ray ghost, so-called because a diffuse X-ray source has remained after other radiation from the outburst has died away, is in the Chandra Deep Field-North, one of the deepest X-ray images ever taken.

The source, a.k.a. HDF 130, is over 10 billion light-years away and existed at a time 3 billion years after the Big Bang, when galaxies and black holes were forming at a high rate.

“We’d seen this fuzzy object a few years ago, but didn’t realize until now that we were seeing a ghost”, said Andy Fabian of the Cambridge University in the United Kingdom.

“It’s not out there to haunt us, rather it’s telling us something – in this case what was happening in this galaxy billions of year ago,” he added.

Fabian and colleagues think the X-ray glow from HDF 130 is evidence for a powerful outburst from its central black hole in the form of jets of energetic particles traveling at almost the speed of light.

When the eruption was ongoing, it produced prodigious amounts of radio and X-radiation, but after several million years, the radio signal faded from view as the electrons radiated away their energy.

However, less energetic electrons can still produce X-rays by interacting with the pervasive sea of photons remaining from the Big Bang – the cosmic background radiation.

Collisions between these electrons and the background photons can impart enough energy to the photons to boost them into the X-ray energy band.

This process produces an extended X-ray source that lasts for another 30 million years or so.

“This ghost tells us about the black hole’s eruption long after it has died,” said co-author Scott Chapman, also of Cambridge University. “This means we don’t have to catch the black holes in the act to witness the big impact they have,” he added.

This is the first X-ray ghost ever seen after the demise of radio-bright jets.

In HDF 130, only a point source is detected in radio images, coinciding with the massive elliptical galaxy seen in its optical image.

This radio source indicates the presence of a growing supermassive black hole.

“This result hints that the X-ray sky should be littered with such ghosts, especially if black hole eruptions are as common as we think they are in the early Universe,” said co-author Caitlin Casey, also of Cambridge. (ANI)

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Mystery of Milky Way’s X-ray glow solved

May 2, 2009 By Leave a Comment

Washington, April 30 (ANI): An image of a region near the center of our galaxy has resolved a long-standing mystery about an X-ray glow along the plane of the galaxy, attributing it to hundreds of point-like X-ray sources, implying that the glow is due to millions of such sources.

The image shows an infrared view from the Spitzer Space Telescope of the central region of the Milky Way, with a pullout showing a Chandra X-ray Observatory image of a region located only 1.4 degrees away from the center of the galaxy.

The so-called galactic ridge X-ray emission was first detected more than two decades ago using early X-ray observatories such as HEAO-1 and Exosat.

The ridge was observed to extend about two degrees above and below the plane of the galaxy and about 40 degrees along the plane of the galaxy on either side of the galactic center. It appeared to be diffuse.

One interpretation of the galactic X-ray ridge is that it is emission from 100-million-degree gas.

This interpretation is problematic because the disk of the galaxy is not massive enough to confine such hot gas, which should flow away in a wind.

Replenishing the gas would then be a problem, since plausible sources of energy such as supernovas are not nearly powerful enough.

A very deep Chandra observation, lasting for about 12 days, was used to study the nature of this ridge emission.

The field was chosen to be close enough to the galactic plane so that the ridge emission was strong, but in a region with relatively little absorption from dust and gas to maximize the number of sources that might be detected.

A total of 473 sources were detected in an area on the sky only about 3 percent of the size of the full Moon, one of the highest densities of X-ray sources ever seen in our galaxy.

It was found that more than 80 percent of the seemingly diffuse ridge of X-ray emission was resolved into individual sources.

These are believed to be mostly white dwarfs pulling matter from companion stars and double stars with strong magnetic activity that are producing X-ray outbursts or flares that are similar to, but more powerful than the flares seen on the Sun.

These stars are unrelated to the large-scale structures seen towards the center of the Spitzer image, which are probably caused by young massive stars. (ANI)

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Black holes that can regulate the rate at which they grow

March 26, 2009 By Leave a Comment

Washington, March 26 (ANI): New results from NASA’s Chandra X-ray Observatory have suggested that a special class of black holes have a mechanism for regulating the rate at which they grow, and can shut off the high-speed jets they produce.

Some stellar-mass black holes launch powerful jets of particles and radiation, like seen in quasars, and are called “micro-quasars”.

The new study looks at a famous micro-quasar in our own Galaxy, and regions close to its event horizon, or point of no return.

This system, GRS 1915+105 (GRS 1915 for short), contains a black hole about 14 times the mass of the Sun that is feeding off material from a nearby companion star.

As the material swirls toward the black hole, an accretion disk forms.

This system shows remarkably unpredictable and complicated variability ranging from timescales of seconds to months, including 14 different patterns of variation.

These variations are caused by a poorly understood connection between the disk and the radio jet seen in GRS 1915.

Chandra, with its spectrograph, has observed GRS 1915 eleven times since its launch in 1999.

These studies reveal that the jet in GRS 1915 may be periodically choked off when a hot wind, seen in X-rays, is driven off the accretion disk around the black hole.

The wind is believed to shut down the jet by depriving it of matter that would have otherwise fueled it. Conversely, once the wind dies down, the jet can re-emerge.

“We think the jet and wind around this black hole are in a sort of tug of war,” said Joseph Neilsen, Harvard graduate student and lead author of the research paper. “Sometimes one is winning and then, for reasons we don’t entirely understand, the other one gets the upper hand,” he added.

The latest Chandra results also show that the wind and the jet carry about the same amount of matter away from the black hole.

This is evidence that the black hole is somehow regulating its accretion rate, which may be related to the toggling between mass expulsion via either a jet or a wind from the accretion disk.

Self-regulation is a common topic when discussing supermassive black holes, but this is the first clear evidence for it in stellar-mass black holes.

According to Julia Lee, assistant professor in the Astronomy department at the Harvard-Smithsonian Center for Astrophysics, “It is exciting that we may be on the track of explaining two mysteries at the same time: how black hole jets can be shut down and also how black holes regulate their growth.” By Sarda Lahangir (ANI)

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Scientists find oldest isolated pulsar ever

February 27, 2009 By Leave a Comment

Washington, Feb 27 (ANI): With the help of NASA’s Chandra X-ray Observatory, scientists have found the oldest isolated pulsar ever detected in X-rays.

The pulsar, PSR J0108-1431 (J0108 for short), which is about 200 million years old, turns out to be surprisingly active.

Among isolated pulsars, ones that have not been spun-up in a binary system, it is over 10 times older than the previous record holder with an X-ray detection.

At a distance of 770 light years, it is one of the nearest pulsars known.

Pulsars are born when stars that are much more massive than the Sun collapse in supernova explosions, leaving behind a small, incredibly weighty core, known as a neutron star.

At birth, these neutron stars, which contain the densest material known in the Universe, are spinning rapidly, up to a hundred revolutions per second.

As the rotating beams of their radiation are seen as pulses by distant observers, similar to a lighthouse beam, astronomers call them “pulsars”.

Astronomers observe a gradual slowing of the rotation of the pulsars as they radiate energy away.

Radio observations of J0108 show it to be one of the oldest and faintest pulsars known, spinning only slightly faster than one revolution per second.

The surprise came when a team of astronomers led by George Pavlov of Penn State University observed J0108 in X-rays with Chandra.

They found that it glows much brighter in X-rays than was expected for a pulsar of such advanced years.

Some of the energy that J0108 is losing as it spins more slowly is converted into X-ray radiation. The efficiency of this process for J0108 is found to be higher than for any other known pulsar.

“This pulsar is pumping out high-energy radiation much more efficiently than its younger cousins,” said Pavlov. “So, although it’s clearly fading as it ages, it is still more than holding its own with the younger generations,” he added.

At its advanced age, J0108 is close to the so-called “pulsar death line,” where its pulsed radiation is expected to switch off and it will become much harder, if not impossible, to observe.

“We can now explore the properties of this pulsar in a regime where no other pulsar has been detected outside the radio range,” said co-author Oleg Kargaltsev of the University of Florida.

“To understand the properties of ‘dying pulsars,’ it is important to study their radiation in X-rays. Our finding that a very old pulsar can be such an efficient X-ray emitter gives us hope to discover new nearby pulsars of this class via their X-ray emission,” he added. (ANI)

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