Archive for National Optical Astronomy Observatory

RIVERSIDE: Astronomy professor awarded Sloan Fellowship – Press

By alkaon on February 23, 2013 No Comments

Naveen Reddy, an assistant professor of physics and astronomy at the University of California, Riverside, has been awarded a prestigious Sloan Research Fellowship from the Alfred P. Sloan Foundation, a philanthropic, not-for-profit grant-making institution based in New York City.

Reddy, who joined UC Riverside in 2011, specializes in the physics of the early universe, and extragalactic astronomy. He is especially interested in distant galaxies, their evolution in cosmic time, and the nature of heavy-element production in these galaxies. He is working on several projects aimed at understanding the history of star formation and buildup of stellar mass in the universe.

Reddy joins 125 other U.S. and Canadian researchers as recipients of Sloan Research Fellowships for 2013. Awarded annually since 1955, the fellowships are given to early-career scientists and scholars whose achievements and potential identify them as rising stars, the next generation of scientific leaders. This year’s fellows are drawn from 61 colleges and universities across the United States and Canada.

After receiving his doctoral degree from Caltech in 2006, Reddy held postdoctoral appointments at the National Optical Astronomy Observatory. His list of awards and honors include: Tinsley Visiting Scholar, University of Texas, Austin, 2011; Hubble Fellowship, 2008-2011; and National Science Foundation Graduate Research Fellowship, 2000-2003.

Administered and funded by the Sloan Foundation, the Sloan Research Fellowships are awarded in eight scientific fields — chemistry, computer science, economics, mathematics, evolutionary and computational molecular biology, neuroscience, ocean sciences, and physics. Fellows receive $50,000 to be used to further their research.

Article source: http://www.pe.com/local-news/riverside-county/riverside/riverside-headlines-index/20130222-riverside-astronomy-professor-awarded-sloan-fellowship.ece

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Galaxy Clusters Provide New Insight Into Nature of Dark Energy

By alkaon on November 22, 2012 No Comments

April Flowers for redOrbit.com – Your Universe Online

Dark Energy is one of the major puzzles of modern astronomy, and one tool that astronomers use to understand this force is encoded in the distribution of clusters of galaxies. A new study by a team of astronomers, led by Dr. Jeeseon Song at the University of Michigan, has yielded exquisitely precise distances of a large sample of clusters. These precise distances may lead to breakthroughs in understanding the expansion history of our universe.

For over 80 years, astronomers have known that our universe was expanding from the Big Bang event. The Nobel Prize in physics was awarded in 2011 for the discovery that the rate of that expansion is increasing rather than slowing down, as had been previously believed. And though dark energy is the cause, it is not well understood.

Dr. Jeeseon Song remarked: “By looking at galaxy clusters at different epochs in cosmic history, astronomers can explore whether dark energy has acted differently at different times in the history of the universe. Galaxies, including our own Milky Way galaxy, are vast assemblages of stars and gas. Clusters of galaxies, conglomerates of tens to hundreds of galaxies, are the largest structures in the universe. They are dynamically changing and aging over time. And that is very crucial in cosmological studies, because that’s where we can see how dark energy is acting on the Universe, pulling the clusters apart.”

In a feat of reverse engineering, the astronomers have been able to gain insight into the nature of dark energy by studying the distribution of clusters at different times in the past and detecting what the dark energy does to the universe

Song and her team have identified an important sample of galaxy clusters whose distances have been determined accurately enough to study how the density of galaxy clusters varies with the age of the universe. The team began their investigation with observations from the South Pole Telescope, a millimeter-wavelength survey telescope, and followed up with work at the Blanco 4-meter telescope at Cerro Tololo Inter-American Observatory, a division of the National Optical Astronomy Observatory (NOAO). This enabled them to refine cluster distances to within a few percent. Although the Blanco telescope in Chile celebrates its 50th anniversary this year, it still plays a vital role in cutting edge research using modern instrumentation such as the Mosaic camera used in this study.

The farther away an object is, the faster it is receding from us. Scientists measure velocity of an object by observing the color of the light wavelength. As an object moves farther away, its light undergoes a shift to longer, red wavelengths in a process known as redshift. An object moving closer displays a shift to longer, blue wavelengths. This simple color shift, called a Doppler shift, is used by highway patrols to measure the velocity of cars on the highway.

Objects with large redshifts are not only far away, they are also observed as they were a long time in the past because of the expansion of the universe. Astronomers refer to this redshift using the letter Z when measuring distant objects in the universe. The clusters that the team studied had an average redshift, z, of about 0.6, at which point the universe was only half of its present age of 13.7 billion years. The clusters, however, span a range in distance from those close enough to be seen nearly as they are in present time, to some with z as large as 1.4.  This means we see these more distant galaxies as they appeared when the universe was less than a third of its present age.

The team also discovered new information about a phenomenon called Bright Cluster Galaxies, or BCGs. These are the brightest and biggest galaxy in each cluster.

The paper’s second author Alfredo Zenteno of Germany’s Ludwig-Maximilians-University in Munich said: “The position of a BCG within a cluster indicates if the cluster is undergoing some violent internal motion – perhaps because it has suffered a smashup with another cluster. By studying the frequency of such collisions, we learn if these clusters are unique or not. This is crucial to understanding dark energy in clusters.”

Article source: http://www.redorbit.com/news/space/1112735494/galaxy-clusters-dark-energy-112112/

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Galaxy Clusters Provide New Insight Into Nature of Dark Energy

By alkaon on November 22, 2012 No Comments

April Flowers for redOrbit.com – Your Universe Online

Dark Energy is one of the major puzzles of modern astronomy, and one tool that astronomers use to understand this force is encoded in the distribution of clusters of galaxies. A new study by a team of astronomers, led by Dr. Jeeseon Song at the University of Michigan, has yielded exquisitely precise distances of a large sample of clusters. These precise distances may lead to breakthroughs in understanding the expansion history of our universe.

For over 80 years, astronomers have known that our universe was expanding from the Big Bang event. The Nobel Prize in physics was awarded in 2011 for the discovery that the rate of that expansion is increasing rather than slowing down, as had been previously believed. And though dark energy is the cause, it is not well understood.

Dr. Jeeseon Song remarked: “By looking at galaxy clusters at different epochs in cosmic history, astronomers can explore whether dark energy has acted differently at different times in the history of the universe. Galaxies, including our own Milky Way galaxy, are vast assemblages of stars and gas. Clusters of galaxies, conglomerates of tens to hundreds of galaxies, are the largest structures in the universe. They are dynamically changing and aging over time. And that is very crucial in cosmological studies, because that’s where we can see how dark energy is acting on the Universe, pulling the clusters apart.”

In a feat of reverse engineering, the astronomers have been able to gain insight into the nature of dark energy by studying the distribution of clusters at different times in the past and detecting what the dark energy does to the universe

Song and her team have identified an important sample of galaxy clusters whose distances have been determined accurately enough to study how the density of galaxy clusters varies with the age of the universe. The team began their investigation with observations from the South Pole Telescope, a millimeter-wavelength survey telescope, and followed up with work at the Blanco 4-meter telescope at Cerro Tololo Inter-American Observatory, a division of the National Optical Astronomy Observatory (NOAO). This enabled them to refine cluster distances to within a few percent. Although the Blanco telescope in Chile celebrates its 50th anniversary this year, it still plays a vital role in cutting edge research using modern instrumentation such as the Mosaic camera used in this study.

The farther away an object is, the faster it is receding from us. Scientists measure velocity of an object by observing the color of the light wavelength. As an object moves farther away, its light undergoes a shift to longer, red wavelengths in a process known as redshift. An object moving closer displays a shift to longer, blue wavelengths. This simple color shift, called a Doppler shift, is used by highway patrols to measure the velocity of cars on the highway.

Objects with large redshifts are not only far away, they are also observed as they were a long time in the past because of the expansion of the universe. Astronomers refer to this redshift using the letter Z when measuring distant objects in the universe. The clusters that the team studied had an average redshift, z, of about 0.6, at which point the universe was only half of its present age of 13.7 billion years. The clusters, however, span a range in distance from those close enough to be seen nearly as they are in present time, to some with z as large as 1.4.  This means we see these more distant galaxies as they appeared when the universe was less than a third of its present age.

The team also discovered new information about a phenomenon called Bright Cluster Galaxies, or BCGs. These are the brightest and biggest galaxy in each cluster.

The paper’s second author Alfredo Zenteno of Germany’s Ludwig-Maximilians-University in Munich said: “The position of a BCG within a cluster indicates if the cluster is undergoing some violent internal motion – perhaps because it has suffered a smashup with another cluster. By studying the frequency of such collisions, we learn if these clusters are unique or not. This is crucial to understanding dark energy in clusters.”

Article source: http://www.redorbit.com/news/space/1112735494/galaxy-clusters-dark-energy-112112/

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Scientists monitor comet breakup

By alkaon on November 6, 2012 No Comments

Comet-HergenrotherThe Hergenrother comet is currently traversing the inner solar system. Amateur and professional astronomers alike have been following the icy dirtball over the past several weeks as it has been generating a series of impressive outbursts of cometary dust material. Now comes word that the comet’s nucleus has taken the next step in its relationship with Mother Nature.

“Comet Hergenrother is splitting apart,” said Rachel Stevenson from NASA’s Jet Propulsion Laboratory in Pasadena, California. “Using the National Optical Astronomy Observatory’s Gemini North Telescope on top of Mauna Kea, Hawaii, we have resolved that the nucleus of the comet has separated into at least four distinct pieces, resulting in a large increase in dust material in its coma.”

With more material to reflect the Sun’s rays, the comet’s coma has brightened considerably.

“The comet fragments are considerably fainter than the nucleus,” said James Bauer from the California Institute of Technology in Pasadena. “This is suggestive of chunks of material being ejected from the surface.”

The comet’s fragmentation event was initially detected October 26 by a team of astronomers from the Remanzacco Observatory, using the Faulkes Telescope North in Haleakala, Hawaii. The WIYN telescope group at Kitt Peak National Observatory in Arizona also imaged the initial fragment.

For those interested in viewing Hergenrother — with a larger-sized telescope and a dark sky — the comet can be seen between the constellations Andromeda and Lacerta.

The orbit of Comet 168P/Hergenrother is well understood. The comet nor any of its fragments are a threat to Earth.

Article source: http://www.astronomy.com/~/link.aspx?_id=ca95a577-391b-417b-afd4-b63511ab63b2

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Art makes stars out of astronomers

By alkaon on November 3, 2012 No Comments

I photographed him during the month’s residency at NOAO (National Optical Astronomy Observatory). I was there as the first part of a project I am sharing with Jane Grisewood to make sense  of astronomy and astronomers through the lens  of contemporary art. The second part will be to  go to the Cerro Tololo Observatory in the foothills of the Andes in the Atacama Desert, Chile, in three weeks’ time.

I photographed the astronomers at work and generally they were rooted both in their offices and in the observatories, looking at a computer screen, rather than through the lens of a telescope, or, as here, protecting their eyes from the blinding glare of direct, magnified, sunlight. All were dedicated  to ideals of education and research, but most of  all to a vision of a still mysterious universe, which challenged them to understand it a little better,  on a mountain top, on the Tohono O’odham Native American reservation.

A limited-edition artist’s book made from some  of the material gathered won the Birgit Skiold  Award for Excellence. For more information,  email judy@judygoldhill.com

Article source: http://www.independent.co.uk/arts-entertainment/art/news/art-makes-stars-out-of-astronomers-8274002.html

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Monster Galaxy’s Core Is Biggest Ever Seen

By alkaon on October 28, 2012 No Comments




The giant elliptical galaxy in the center of this image, taken by NASA’s Hubble Space Telescope, is the most massive and brightest member of the galaxy cluster Abell 2261. Image released Oct. 25, 2012.
CREDIT: NASA, ESA, M. Postman (STScI), T. Lauer (NOAO), and the CLASH team


A faraway galaxy’s core is the largest ever seen, and it may have been puffed up by the merger of two black holes, a new study reports.

The core of the elliptical galaxy A2261-BCG is about 10,000 light-years across, astronomers using NASA’s Hubble Space Telescope discovered. That’s unexpectedly huge, even for a galaxy 10 times wider than our own Milky Way. The core is also strangely diffuse, without a concentrated peak of light around an obvious central black hole.

That last detail is a bit of a surprise, since supermassive black holes are thought to lurk at the core of most, if not all, galaxies.

“Expecting to find a black hole in every galaxy is sort of like expecting to find a pit inside a peach,”study co-author Tod Lauer, of the National Optical Astronomy Observatory in Tucson, Ariz., said in a statement. “With this Hubble observation, we cut into the biggest peach and we can’t find the pit. We don’t know for sure that the black hole is not there, but Hubble shows that there’s no concentration of stars in the core.” [Photos: Black Holes of the Universe]

 

A2261-BCG (short for Abell 2261 Brightest Cluster Galaxy) is 1 million light-years wide and is found 3 billion light-years from Earth. Its strangely bloated core is three times larger than the centers of other extremely luminous galaxies, researchers said.

The astronomers think a black hole merger — involving objects containing several billion times the mass of our sun — may have puffed up the galaxy’s core. This could have happened in two different ways, they say.

In one scenario, the merger gravitationally stirred up and scattered the stars. The black holes lost momentum in the process and fell into each other, forming a supermassive black hole that resides at A2261-BCG’s heart today.

In the other, the black-hole merger created gravity waves, which are ripples in the fabric of space-time. These waves radiated most strongly in one direction, booting the merged black hole from the galaxy.

“The black hole is the anchor for the stars,”Lauer said. “If you take it out, all of a sudden you have a lot less mass. The stars aren’t held together very well and they move outwards, enlarging the core even more.”

The ejection theory may sound far-fetched,”but that’s what makes observing the universe so intriguing — sometimes you find the unexpected,” said study lead author Marc Postman, of the Space Telescope Science Institute in Baltimore.

The research team is now actively searching for evidence of A2261-BCG’s black hole, if it exists. The astronomers expect that material falling onto a black hole should generate radio waves, so they’re probing the galaxy with New Mexico’s Very Large Aray radio telescope.

The study was published in the Sept. 10 issue of The Astrophysical Journal.

This story was provided by SPACE.com, a sister site to LiveScience. Follow SPACE.com on Twitter @Spacedotcom. We’re also on Facebook  Google+.

Article source: http://www.livescience.com/24341-giant-galaxy-core-black-hole-hubble.html

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Monster galaxy may have been stirred up by black-hole mischief

By alkaon on October 27, 2012 No Comments

Monster-galaxyAstronomers using NASA’s Hubble Space Telescope have obtained a remarkable new view of a whopper of an elliptical galaxy that may have been puffed up by the actions of one or more black holes in its core.

Spanning a little more than 1 million light-years, the galaxy is about 10 times the diameter of the Milky Way Galaxy. The bloated galaxy is a member of an unusual class of galaxies with a diffuse core filled with a fog of starlight where there would normally be a concentrated peak of light around a central black hole. Viewing the core is like seeing a city with no downtown, just houses sprinkled across a vast landscape.

Astronomers used Hubble’s Advanced Camera for Surveys and Wide Field Camera 3 to measure the amount of starlight across the galaxy, dubbed A2261-BCG. The Hubble observations revealed that the galaxy’s puffy core, measuring about 10,000 light-years, is the largest yet seen.

A galaxy’s core size typically is correlated to the dimensions of its host galaxy, but in this case, the central region is much larger than astronomers would expect for the galaxy’s size. In fact, the bloated core is more than three times larger than the center of other luminous galaxies. Located 3 billion light-years away, the galaxy is the most massive and brightest galaxy in the Abell 2261 cluster.

Astronomers have proposed two possibilities for the puffy core. One scenario is that a pair of merging black holes gravitationally stirred up and scattered the stars. Another idea is that the merging black holes were ejected from the core. Left without an anchor, the stars began spreading out even more, creating the puffy-looking core.

Previous Hubble observations have revealed that supermassive black holes, weighing millions or billions times more than the Sun, reside at the centers of nearly all galaxies and may play a role in shaping those central regions.

“Expecting to find a black hole in every galaxy is sort of like expecting to find a pit inside a peach,” said Tod Lauer of the National Optical Astronomy Observatory in Tucson, Arizona. “With this Hubble observation, we cut into the biggest peach, and we can’t find the pit. We don’t know for sure that the black hole is not there, but Hubble shows that there’s no concentration of stars in the core.”

“When I first saw the image of this galaxy, I knew right away it was unusual,” said Marc Postman from the Space Telescope Science Institute in Baltimore, Maryland. “The core was very diffuse and very large. The challenge was then to make sense of all the data, given what we knew from previous Hubble observations, and come up with a plausible explanation for the intriguing nature of this particular galaxy.”

The astronomers expected to see a slight cusp of light in the galaxy’s center, marking the location of the black hole and attendant stars. Instead, the starlight’s intensity remained fairly even across the galaxy.

One possibility for the puffy core may be due to two central black holes orbiting each other. These black holes collectively could have been as massive as several billion Suns. Though one of the black holes would be native to the galaxy, a second black hole could have been added from a smaller galaxy that was gobbled up by the massive elliptical.

In this scenario, stars circling in the giant galaxy’s center came close to the twin black holes. The stars were then given a gravitational boot out of the core. Each gravitational slingshot robbed the black holes of momentum, moving the pair ever closer together, until finally they merged, forming one supermassive black hole that still resides in the galaxy’s center.

Another related possibility is that the black-hole merger created gravity waves, which are ripples in the fabric of space. According to the general theory of relativity, a pair of merging black holes produces ripples of gravity that radiate away. If the black holes are of unequal mass, then some of the energy may radiate more strongly in one direction, producing the equivalent of a rocket thrust. The imbalance of forces would have ejected the merged black hole from the center at speeds of millions of miles per hour, resulting in the rarity of a galaxy without a central black hole. “The black hole is the anchor for the stars,” Lauer said. “If you take it out, all of a sudden you have a lot less mass. The stars don’t get held down very well and they expand out, enlarging the core even more.”

The team admits that the ejected black-hole scenario may sound far-fetched, “but that’s what makes observing the universe so intriguing — sometimes you find the unexpected,” said Postman.

“This is a system that’s interesting enough that it pushes against a lot of questions,” said Lauer. “We have thought an awful lot about what black holes do, but we haven’t been able to test our theories. This is an interesting place where a lot of the ideas we’ve had can come together and can be tested, fairly exotic ideas about how black holes may interact with each other dynamically and how they would affect the surrounding stellar population.”

The team is now conducting follow-up observations with the Very Large Array (VLA) radio telescope in New Mexico. The astronomers expect material falling onto a black hole to emit radio waves, among other types of radiation. They will compare the VLA data with the Hubble images to more precisely pin down the location of the black hole, if it indeed exists.

The Abell 2261 cluster is part of a multiwavelength survey, led by Postman, called the Cluster Lensing And Supernova survey with Hubble (CLASH). The survey probes the distribution of dark matter in 25 massive galaxy clusters.

Article source: http://www.astronomy.com/~/link.aspx?_id=120cbc12-37f6-4fe4-8a20-b1a42cf0ef1e

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Monster Galaxy’s Core Is Biggest Ever Seen

By alkaon on October 26, 2012 No Comments




Monster Galaxy Lacks a Bright Core

The giant elliptical galaxy in the center of this image, taken by NASA’s Hubble Space Telescope, is the most massive and brightest member of the galaxy cluster Abell 2261. Image released Oct. 25, 2012.
CREDIT: NASA, ESA, M. Postman (STScI), T. Lauer (NOAO), and the CLASH team


A faraway galaxy’s core is the largest ever seen, and it may have been puffed up by the merger of two black holes, a new study reports.

The core of the elliptical galaxy A2261-BCG is about 10,000 light-years across, astronomers using NASA’s Hubble Space Telescope discovered. That’s unexpectedly huge, even for a galaxy 10 times wider than our own Milky Way. The core is also strangely diffuse, without a concentrated peak of light around an obvious central black hole.

That last detail is a bit of a surprise, since supermassive black holes are thought to lurk at the core of most, if not all, galaxies.

“Expecting to find a black hole in every galaxy is sort of like expecting to find a pit inside a peach,”study co-author Tod Lauer, of the National Optical Astronomy Observatory in Tucson, Ariz., said in a statement. “With this Hubble observation, we cut into the biggest peach and we can’t find the pit. We don’t know for sure that the black hole is not there, but Hubble shows that there’s no concentration of stars in the core.” [Photos: Black Holes of the Universe]

A2261-BCG (short for Abell 2261 Brightest Cluster Galaxy) is 1 million light-years wide and is found 3 billion light-years from Earth. Its strangely bloated core is three times larger than the centers of other extremely luminous galaxies, researchers said.

The astronomers think a black hole merger — involving objects containing several billion times the mass of our sun — may have puffed up the galaxy’s core. This could have happened in two different ways, they say.

In one scenario, the merger gravitationally stirred up and scattered the stars. The black holes lost momentum in the process and fell into each other, forming a supermassive black hole that resides at A2261-BCG’s heart today.

In the other, the black-hole merger created gravity waves, which are ripples in the fabric of space-time. These waves radiated most strongly in one direction, booting the merged black hole from the galaxy.

“The black hole is the anchor for the stars,”Lauer said. “If you take it out, all of a sudden you have a lot less mass. The stars aren’t held together very well and they move outwards, enlarging the core even more.”

The ejection theory may sound far-fetched,”but that’s what makes observing the universe so intriguing — sometimes you find the unexpected,” said study lead author Marc Postman, of the Space Telescope Science Institute in Baltimore.

The research team is now actively searching for evidence of A2261-BCG’s black hole, if it exists. The astronomers expect that material falling onto a black hole should generate radio waves, so they’re probing the galaxy with New Mexico’s Very Large Aray radio telescope.

The study was published in the Sept. 10 issue of The Astrophysical Journal.

Follow SPACE.com on Twitter @Spacedotcom. We’re also on Facebook  Google+.

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Article source: http://www.space.com/18226-giant-galaxy-core-black-hole-hubble.html

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IU Astronomy, Pervasive Technology Institute get ‘big picture’ with …

By alkaon on September 27, 2012 No Comments

Last modified: Wednesday,

September 26,
2012

IU Astronomy, Pervasive Technology Institute get ‘big picture’ with collaboration on new camera

Bigger, sharper images to be refined, processed, stored at IU

FOR IMMEDIATE RELEASE

Sept. 26, 2012

BLOOMINGTON, Ind. — Recording light from millions of light years away and then sending it to the Indiana University Data Center at the corner of 10th Street and the State Road 45/46 Bypass, a new camera at Kitt Peak National Observatory in Arizona’s Sonoran desert will image an area of sky five times that of the full moon, yet still focus at the equivalent of seeing a baseball from 30 miles away.

The new One Degree Imager camera at Kitt Peak’s WIYN 3.5-meter telescope will offer IU astronomers — like IU College of Arts and Sciences’ Astronomy Department assistant professor Katherine Rhode, who studies distant globular star clusters — superb image quality across the camera’s entire field of view. The camera provides image sharpness and resolution for objects as small as 0.3 arc seconds — one arc second is 1/3600 of a degree — and the field of view will eventually cover a full one degree across.

One Degree Imager

The WIYN telescope has a new camera, the One Degree Imager (pictured), that offers a wide field of view and exceptional image resolution. The two-gigabyte images will be refined and processed at IU’s Pervasive Technology Institute.

Print-Quality Photo

“This new camera represents a major step forward for IU Astronomy, the WIYN Observatory partners and the astronomical community as it will enable IU researchers and students to study the universe in big chunks instead of tiny pieces,” Rhode said. “We can image entire star clusters, galaxies and groups of galaxies all at once, while still seeing the detailed features of each object. We can study a globular cluster made up of tens of thousands of stars, while at the same time imaging the individual stars that are packed into the cluster’s central regions. We can study a giant spiral galaxy while simultaneously resolving the individual knots of star formation embedded within its spiral arms. And we can image dozens of galaxies in a galaxy cluster, measuring the light coming from each individual galaxy as well as studying how the galaxies and their stars and gas interact with each other as they orbit a common center of gravity.”

Those huge images — each will be two gigabytes in size — will also generate between two and four terabytes of data each week, and that’s where IU’s Pervasive Technology Institute is contributing to the massive effort needed to process the data from those different types of images.

PTI is developing the Web-based science gateway, called the ODI Pipeline, Portal and Archive, to help researchers pool resources and analyze, manipulate and store data from the camera. Data will be moved from Kitt Peak to IU, initially to the Data Capacitor system hosted in the IU Data Center, so that initial images can be refined and processed. Those refinements will take place on XSEDE — the eXtreme Science and Engineering Discovery Environment — a national grid of supercomputers that IU helps operate. Processed, science-grade images are then stored in the highly secure IU Scholarly Data Archives.

“The ODI-PPA gateway allows astronomers to work with large data sets without having to download it to a personal computer, and to get their visual analysis as well as data processing done on a massive distributed grid and cloud-based computer resources via our portal,” said Arvind Gopu, the University Information Technology Services Research Technologies and PTI project manager in charge of the gateway. “With our gateway, astronomers from all over, not just IU, can search, download and process data in the cloud, allowing the ODI instrument to truly achieve its full potential. This is a perfect example of PTI and IU research scientists collaborating to develop tools that benefit research at IU and worldwide.”

Once data are moved to and archived at the IU Data Center, astronomers will no longer need to transfer all the intermediate stages of their data to their home computers. Instead, they’ll be able to work in a cloud configuration, downloading only their final results.

The WIYN telescope is operated by IU, Yale University, the University of Wisconsin and the National Optical Astronomy Observatory, and astronomers from all over the world apply for time to use what is considered one of the best telescopes for optical imaging in use today. The telescope can be controlled by a computer in Swain Hall West on the Bloomington campus, and students and faculty can video conference with Kitt Peak and manipulate the WIYN telescope’s instruments as if there.

“One important role our graduate students are playing right now is to help with commissioning the new camera, since once a new instrument is installed, it needs to be adjusted to obtain the best image quality, thoroughly tested to make sure everything works as expected, and then characterized to quantify and document how it responds to incoming light and how it can be used to obtain precision flux measurements in various wavebands,” Rhode said. “Working on the commissioning of a world-class imager like this is a great opportunity for our students, since — as part of their graduate education — they are learning about how to develop and use astronomical cameras and other instruments.”

Images from the new 2,800-pound camera will be stabilized to compensate for motion due to atmospheric turbulence, telescope shake and tracking errors by using a technology called Orthogonal Transfer Array charge-coupled device sensing. The initial configuration of the camera includes 13 charge-coupled device detector arrays; when ODI is fully deployed, it will include 64 charge-coupled device detector arrays, with a total of over a billion pixels.

Rhode said having a camera with a wide field of view allows for imaging of objects like a Milky Way open star cluster, or a giant spiral galaxy with its own population of globular star clusters, in a single pointing. That means more efficient observing and an easier way to accurately compare multiple objects and characterize fluxes of those objects.

“Having a wide field will allow us to study these objects in their entirety to measure accurate global properties and to study how their properties vary spatially across the field,” she said.

For more information or to speak with scientists and technologists involved with ODI, please contact Steve Chaplin, IU Communications, at 812-856-1896 or stjchap@iu.edu.

Article source: http://newsinfo.iu.edu/news/page/normal/23171.html

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Berkeley Lab Sensors Enable First Light for the Dark Energy Camera

By alkaon on September 20, 2012 No Comments

Early in the morning of September 12 the Dark Energy Camera (DECam), mounted on the Victor Blanco Telescope at the Cerro Tololo Inter-American Observatory in Chile, recorded its first images of a southern sky spangled with galaxies.

Galaxies up to eight billion light years away were captured on DECam’s focal plane, whose imager consists of 62 charge-coupled devices (CCDs) invented and developed by engineers and physicists at the U.S. Department of Energy’s Lawrence Berkeley National Laboratory (Berkeley Lab).

Berkeley Lab CCDs are noted for their exceptionally high sensitivity to light (quantum efficiency), particularly in the red and infrared regions of the spectrum – a crucial advantage for astronomical CCDs searching for objects at extremely high redshifts.

Combining the 570-million-pixel focal plane made of Berkeley Lab CCDs with the light-gathering power of the Blanco telescope’s 4-meter mirror, DECam has unique ability to reach wide and deep into the night sky.

DECam was built by the Dark Energy Survey (DES) collaboration based at the Fermi National Accelerator Laboratory. A photometric imaging camera, it measures the amount of light in various colors from astronomical objects rather than details of their spectra.

DECAM’s goal is to measure the expansion history of the universe by collecting images of 4,000 distant supernovae and 300 million distant galaxies within the next five years.

“Early in the planning of DECam, Fermilab realized that the high-redshift galaxies they sought would require longer exposures to get secure photometric results, and that the Berkeley Lab CCD’s higher quantum efficiency in the near infrared would make the survey much faster and more efficient,” says Natalie Roe, Director of Berkeley Lab’s Physics Division and, in the early 2000s, the leader of the Lab’s CCD Group.

When DECam began construction, Roe worked closely with Peoples, DECam project manager Brenna Flaugher, Juan Estrada, Tom Diehl, and others in the Dark Energy Survey collaboration based at Fermilab.

Manufacture of the DECam CCDs was overseen by Steve Holland, a senior engineer in Berkeley Lab’s Engineering Division, who invented the Berkeley Lab CCD in the mid-1990s as a spin-off from research and development of detectors for high-energy physics.

Most astronomical CCDs at the time were fragile affairs because, to be sensitive to faint light, they had to be thinned to about 20 micrometers (millionths of a meter), a fraction of the roughly 100-micrometer width of a human hair.

Berkeley Lab CCDs are beefy by contrast – the DECam CCDs measuring a robust 250 micrometers thick – yet they maintain high resolution across the spectrum, including in blue light.

When photons hit the back surface of the chip, the holes they create (the positively charged equivalents of electrons) are pulled through to the circuitry on the front by an electric field generated by a bias voltage, which permeates the entire thickness of the CCD.

In red light, with more material to capture long-wavelength red photons and enough thickness to suppress surface reflections that cause interference fringes, Berkeley Lab CCDs are far superior to the typical astronomical CCD.

Fabrication methods for ultrapure silicon originally developed for high-energy physics insure that the Berkeley Lab CCD’s “dark current” – charges originating inside the chip, a source of false signals – is also low.

“Fermilab was attracted to our CCDs because of their improved red response,” says Holland, “but considering that there were as yet no big cameras using them when DECam was planned, they had to decide to take a risk.”

The DECam chips were fabricated by Berkeley Lab’s industrial partner, Teledyne DALSA Semiconductor, and the Physics Division’s MicroSystems Laboratory. Partially finished wafers holding four CCDs, each with eight of eleven masking steps completed, were commercially thinned, then sent to the MicroSystems Laboratory for completion.

“Cold-probe” tests at minus 45 degrees Celsius were performed to detect shorts, defects, and excessive dark current. The CCDs were cut from the wafer and sent to Fermilab for mounting and final testing of the science-grade devices.

“In the first months, manufacturing went slowly,” Roe says, “but we used data from each lot of wafers to feed back processing improvements, and the yield steadily improved. We used conservative estimates and overshot the requirements – at the end, we produced twice as many science-grade CCDs as needed.”

Because collaboration between Fermilab and Berkeley Lab on DECam began early in the large-scale development of the Berkeley Lab CCD, the experience benefited both parties.

DECam will produce the largest-ever 3-D map of the universe, a record currently held by the third Sloan Digital Sky Survey and its largest component, the Baryon Oscillation Spectroscopic Survey (BOSS), led by Berkeley Lab astrophysicists. The red channel of the SDSS-III spectrograph, whose development was led by Roe, also uses Berkeley Lab CCDs.

Says Holland, “We could not have made the BOSS CCDs, which are twice the size of the DECam CCDs, without learning what we did in ramping up for DECam.”

Roe adds, “Delivery of CCDs has often ended up being the bottleneck for astronomical instrumentation, but in this case we delivered on time and things came together as planned. It was an example of great teamwork between Berkeley Lab and Fermilab.”

This work was principally supported by DOE’s Office of Science and by the National Science Foundation, through the National Optical Astronomy Observatory operated by the Association of Universities for Research in Astronomy. Current and former members of the Berkeley Lab Physics and Engineering Divisions who contributed to DECam include Chris Bebek, Kyle Dawson (now at the University of Utah), John Emes, Don Groom, Steve Holland, Armin Karcher, Bill Kolbe, Julie Lee, Michael Levi, Nick Palaio, Natalie Roe, Co Tran, and Guobin Wang.

Article source: http://www.spacedaily.com/reports/Berkeley_Lab_Sensors_Enable_First_Light_for_the_Dark_Energy_Camera_999.html

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NASA Image of the day

The Engine Burns Blue

 
This image shows a cutting-edge solar-electric propulsion thruster in development at NASA's Jet Propulsion Laboratory, Pasadena, Calif., that uses xenon ions for propulsion. An earlier version of this solar-electric propulsion engine has been flying on NASA's Dawn mission to the asteroid belt. This engine is being considered as part of the Asteroid Initiative, a proposal to robotically capture a small near-Earth asteroid and redirect it safely to a stable orbit in the Earth-moon system where astronauts can visit and explore it. This image was taken through a porthole in a vacuum chamber at JPL where the ion engine is being tested. Image credit: NASA/JPL-Caltech
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