Getting the GOODS on galaxies: a telescope views patches of the universe in a rainbow of colors.Over the past decade, the Hubble Space Telescope Hubble Space Telescope (HST), the first large optical orbiting observatory. Built from 1978 to 1990 at a cost of $1.5 billion, the HST (named for astronomer E. P. Hubble) was expected to provide the clearest view yet obtained of the universe. has literally changed our view of the universe. Much of what we now understand about galaxy formation has been gleaned from Hubble staring for 10 days at a single tiny patch of sky. Within this region, the Earth-orbiting telescope has catalogued the shape, brightness, and color of galaxies that are only 500-millionths as bright as the eye can see. But if one sharp eye on the universe is good, then two, three, four, or more are better. In an ambitious new program, Hubble recently joined forces with NASA's orbiting Chandra X-ray Observatory Chandra X-ray Observatory U.S. X-ray space telescope. It was named after astrophysicist Subrahmanyan Chandrasekhar and was launched into orbit in 1999. Its mirror, with an aperture of 1.2 m (4 ft) and a focal length of 10 m (33 ft), produces unprecedented resolution. and several of the world's largest ground-based telescopes to expand astronomers' view to a panoply pan·o·ply n. pl. pan·o·plies 1. A splendid or striking array: a panoply of colorful flags. See Synonyms at display. 2. of wavelengths. These observatories, which are about to be joined by the Space Infrared Telescope Facility Space Infrared Telescope Facility: see observatory, orbiting. , launched late last month, are shedding light on galaxy assembly in a way that no single telescope, looking at the sky at a limited set of wavelengths, could ever manage. It's the difference between viewing a photograph in color versus black-and-white, except that the range of wavelengths is millions of times larger than those depicted in a color photo. Known as the Great Observatories Origins Deep Survey (GOODS), the coordinated effort focuses on two regions of the heavens. One swath, known as the Hubble Deep Field The Hubble Deep Field (HDF) is an image of a small region in the constellation Ursa Major, based on the results of a series of observations by the Hubble Space Telescope. It covers an area 144 arcseconds across, equivalent in angular size to a tennis ball at a distance of 100 North, was originally examined by Hubble's wide-field and planetary camera in late 1995 and has recently has been scanned by an even more-sensitive instrument, Hubble's Advanced Camera for Surveys The Advanced Camera for Surveys (ACS) is a third generation axial instrument aboard the Hubble Space Telescope (HST). The initial design and scientific capabilities of ACS were defined by a team based at Johns Hopkins University. , installed 2 years ago. This camera has more than twice the field of view of the older detector. The other section of sky is known as Chandra Deep Field South. The area encompassed by the two regions is nearly half the size of the full moon as viewed from Earth and 70 times the original Hubble Deep Field North. Each of the two fields examined by GOODS contains tens of thousands of galaxies, some so distant that they hail from a time when the 13.7-year-old universe was only a billion years old. "This is the first time that the cosmic tale of how galaxies build themselves has been traced reliably to such early times in the universe's life," says GOODS researcher Mauro Giavalisco of the Space Telescope Science Institute The Space Telescope Science Institute (STScI) is the science operations center for the Hubble Space Telescope (HST; in orbit since 1990) and for the James Webb Space Telescope (JWST; scheduled to be launched in 2013). (STScI) in Baltimore. DISTANT OR DUSTY? After comparing recent Chandra and Hubble images of the Chandra Deep Field South, astronomers are faced with a mystery. Chandra found seven strong X-ray sources that can't be seen all in visible light. Usually when astronomers such intense the source has been whirlpool of matter a supermassive black hole. However, black holes at the centers of galaxy where stars produce amounts of visible ultraviolet light Ultraviolet light A portion of the light spectrum not visible to the eye. Two bands of the UV spectrum, UVA and UVB, are used to treat psoriasis and other skin diseases. . "We should see the optical galaxies in our Hubble images ... but we don't see notes Anton Koekemoer who will describe his team's study in an upcoming Astrophysical Journal The Astrophysical Journal, often abbreviated to ApJ, is a scientific journal covering astronomy and astrophysics. It was founded in 1895 by George Ellery Hale and James E. Keeler. It currently (October 2006) publishes three issues per month, with 500 pages per issue. devoted to early findings from the GOODS survey. One explanation is that the X rays that Chandra recorded come from the most distant supermassive black holes known in the universe, dating from a time when the cosmos might have been only about 600 million years old, or just 7 percent of its current age. In that case, Hubble wouldn't detect the remote galaxy housing the black hole because the expansion of the universe would have shifted all of the galaxy's ultraviolet and visible light to wavelengths much redder than the telescope can record. Such ancient supermassive black holes are of keen interest because recent evidence suggests that they're intimately connected to the growth of the galaxies in which they reside (SN: 4;/5/03, p. 214;). There could be, however, a more mundane explanation for the X-ray findings, cautions Koekemoer. The X-ray sources could be supermassive black holes that lie much closer to Earth but whose small host galaxies are shrouded in so much dust that they can't be seen in visible light. If so, calculations show that the galaxies would have to be dustier than any other group of galaxies known. In fact, the dust would have to be so implausibly thick that some astronomers favor the first explanation. Scientists may soon have a solution to this puzzle. "The next steps really will be to see what the Space Infrared Telescope Facility can tell us about these objects," notes Koekemoer. If the X-ray sources come from remote galaxies, the visible starlight that these galaxies have radiated will have been shifted into the midinfrared, exactly the wavelehgth range in Which the new infrared telescope infrared telescope A telescope, similar in operation to an optical telescope, that is designed to detect infrared radiation. Because infrared radiation is emitted by warm objects, infrared telescopes need to be shielded from local heat sources, as by is sensitive. On the other hand, if the galaxies are nearby, the abundant dust would radiate ra·di·ate v. 1. To spread out in all directions from a center. 2. To emit or be emitted as radiation. ra large amounts of infrared radiation, and the telescope "should be able to measure how much dust they contain," says Koekemoer. Results from the newly launched observatory are expected within a year. BUILDING GALAXIES Combining GOODS observations taken by Hubble with near-infrared and visible-light images taken from the ground has already given astronomers the first evidence that galaxies were forming substantial numbers of stars early in the universe. Casey Papovich of the University of Arizona (body, education) University of Arizona - The University was founded in 1885 as a Land Grant institution with a three-fold mission of teaching, research and public service. in Tucson and his colleagues report in the special issue of Astrophysical Journal that when the universe was 2 to 3 billion years old, galaxies bulked up, increasing their stellar mass by about 40 percent. That number is only a rough estimate, notes Papovich, because it's not based on a galaxy-by-galaxy measurement. Instead, he and his colleagues added up all the near-infrared and visible light from two sets of galaxies observed in the GOODS survey. In one set, galaxies were observed as they appeared 12 billion years ago; in the other, a billion years later. The increase in light output over this interval indicates that the latter group has more stars. "It looks like you are actually seeing galaxies build up their stellar mass, and we hadn't actually seen that" so early in the universe, says Harry Ferguson Henry George (Harry) Ferguson (November 4, 1884 - October 25, 1960) developed the modern agricultural tractor. He was also an early Irish aviator. He was born at Growell, near Dromore, County Down, Ireland (in what is now Northern Ireland), and was the son of an Irish farmer. of STScI. A large sample of galaxies hailing from 12 billion years back in cosmic history had never been detected before the Advanced Camera for Surveys was installed on Hubble, he notes. Previous studies had indicated that about 7 billion years ago, star formation dropped to about one-tenth its earlier rate. This indicates that galaxy assembly trailed off when the universe was about half its current age. The Space Infrared Telescope Facility is likely to refine these numbers, as that observatory will conduct a more representative census of stellar mass among distant galaxies, which date from a time when the universe was young. The bulk of stars radiates at visible and near-infrared wavelengths, and for distant galaxies, this radiation is shifted into the infrared. In a related result, Ferguson and his colleagues used GOODS data to find that galaxies have continuously increased their size since the time the universe was about 1 billion to 6 billion years old. Both the build-up of stars and galaxy size are consistent with the standard, bottom-up model (programming) bottom-up model - A method for estimating the cost of a complete software project by combining estimates for each component. of galaxy formation, Ferguson notes. In that model, galaxies start out small and grow by merging with other, similar-size galaxies and capturing smaller, satellite ones (SN: 8/16/03, p. 99). Driving that activity is the unseen but ubiquitous material dubbed dark matter. In the bottom-up model, dark matter is the universe's first stuff to coalesce co·a·lesce intr.v. co·a·lesced, co·a·lesc·ing, co·a·lesc·es 1. To grow together; fuse. 2. To come together so as to form one whole; unite: , and the gravity that results then drives ordinary, visible matter to gather into galaxies. SUPER FINDINGS Astronomers expect GOODS observations to answer another question: Is the mysterious force called dark energy causing the universe to expand at an ever-faster rate? Until 1998, the standard theory of cosmology held that, ever since the Big Bang big bang Model of the origin of the universe, which holds that it emerged from a state of extremely high temperature and density in an explosive expansion 10 billion–15 billion years ago. , gravity's tug has slowed the expansion of the universe. Then, measurements of the intensity of distant, exploding stars called type lA supernovas caused a scientific sensation by describing a universe whose expansion is accelerating (SN: 4/7/01, p.218) Now, by repeatedly observing the two patches of sky in the GOODS survey, Hubble's Advance Camera for Surveys has identified 10 extremely distant type la supernovas. These remote supernovas should put dark energy to the ultimate test, says Adam Riess Adam Riess is an astrophysicist at Johns Hopkins University and the Space Telescope Science Institute and is widely known for his research in using supernovae as Cosmological Probes. of STScI. Astronomers refer to these supernovas as standard candles
the output or consumption of an electric device expressed in watts. . Most previous observations recorded type la supernovas that were several billion light-years from Earth, so astronomers see the supernovas as they appeared when the universe was several billion years younger than it is today. If gravity had continuously slowed cosmic expansion, the distance between Earth and those supernovas ought to be less than if the expansion rate had remained constant or sped up. Because the supernovas wouldn't lie as far away, they should appear brighter. Yet two teams of astronomers announced in 1998 that they had found just the opposite. Supernovas were 20 percent dimmer dim·mer n. 1. A rheostat or other device used to vary the intensity of an electric light. 2. a. A parking light on a motor vehicle. b. A low beam. than expected if cosmic expansion had remained constant. That suggested that cosmic expansion had in fact sped up and that the space between Earth and those supernovas had stretched out more than anticipated. Researchers ascribe this strange state of affairs to dark energy, an entity that's the flip side Flip side In the context of general equities, opposite side to a proposition or position (buy, if sell is the proposition and vice versa). of gravity. Where ordinary gravity pulls objects together, dark energy pushes them apart. Not everyone has been convinced by the supernova supernova, a massive star in the latter stages of stellar evolution that suddenly contracts and then explodes, increasing its energy output as much as a billionfold. data. Some astronomers worry that supernovas were intrinsically different in the past or that cosmic dust cosmic dust n. Clouds of fine solid particles of matter in interstellar space. Noun 1. cosmic dust - clouds of particles or gases occurring throughout interstellar space could make the supernovas appear dimmer than they really are. But there is a test that could allay such concerns. According to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. some theorists, dark energy has remained constant in strength throughout the history of the universe. In contrast, the density of matter, which gives rise to gravity's familiar tug between objects, was much higher in the past, when the universe was smaller. In fact, more than 5 billion years ago, the density of all the matter in the universe would have been so great that its pull would have overwhelmed dark energy's push. During that early time, ordinary gravity was at the helm, slowing cosmic expansion. If all this holds true, then supernovas that are extremely remote and hail from the distant past ought to be slightly closer to Earth and thus appear brighter than they would if the universe has been expanding at either a constant or accelerated rate. That's not an effect that dust, for example, could mimic. Astronomers have observed only a few supernovas that are distant enough to qualify for this test, but their brightness supports the hypothesis that dark energy is driving cosmic expansion. "We definitely have the data in the can, enough to tell us the expansion history [of the universe] and whether there was a deceleration deceleration /de·cel·er·a·tion/ (de-sel?er-a´shun) decrease in rate or speed. early deceleration phase prior to an accelerated expansion or whether there's some strange surprise in store," Riess says. His team expects to have preliminary results in October. Next year, the Hubble camera will take an even deeper look at the two sky regions already examined by GOODS. By including the most powerful telescopes on Earth and in space, "the survey is giving us a uniquely comprehensive history of galaxies from early epochs to the relatively recent past,' says Mark Dickinson of STScI. The findings, he adds, will also serve as a bridge to future explorations with Hubble's proposed successor, the James Webb Space Telescope This article or section documents a scheduled or expected spaceflight. Details may change as the launch date approaches or more information becomes available. . Scheduled to be launched a decade from now, it will have the capability to peer even farther back in time to see the very first galaxies and stars in the universe. |
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