After Hubble: the Next Generation: probing the final frontier.Call them postcards from the edge Postcards from the Edge is a semi-autobiographical novel written by Carrie Fisher, first published in 1987. It was later adapted, by Fisher herself, into a motion picture directed by Mike Nichols which was released by Columbia Pictures in 1990. . Images from telescopes like the space-based Hubble and the giant W.M. Keck atop Hawaii's Mauna Kea Mauna Kea (mou`nə kā`ə), dormant volcano, 13,796 ft (4,205 m) high, in the south central part of the island of Hawaii. It is the loftiest peak in the Hawaiian Islands and the highest island mountain in the world, rising c. are revealing what galaxies looked like several billion years ago, when the universe was only 10 percent of its current age. Displaying a mind-boggling assortment of galaxies still in the first blush Noun 1. first blush - at the first glimpse or impression; "at first blush the idea possesses considerable intuitive appeal but on closer examination it fails" of youth, these pictures illuminate, but don't solve, the riddle of galaxy formation. Astronomers are still seeking views of the very first flickers of starlight and the birth of the first galaxies. For that, they'll need a telescope that can probe still deeper into space and farther back in time. Indeed, for over a year now, researchers have been gathering ideas and making plans for such a device, which they expect would replace the aging Hubble in 2007. Like Hubble, this instrument would fly above Earth, avoiding the blurring of images caused by the planet's turbulent atmosphere. To see faint objects, it must have a light-collecting area much larger than Hubble's 2.4-meter-wide primary mirror. In addition, because the expansion of the universe shifts the light emitted by distant objects to longer, or redder, wavelengths, this telescope must record images at wavelengths farther into the infrared than can reach the ground or be detected by Hubble. In early April, just 2 months after astronauts gave Hubble a major upgrade, researchers convened at NASA's Goddard Space Flight Center The Goddard Space Flight Center (GSFC) is a major NASA space research laboratory established on May 1, 1959 as NASA's first space flight center. GSFC employs approximately 10,000 civil servants and contractors, and is located approximately 6.5 miles northeast of Washington, D.C. in Greenbelt, Md., to discuss plans for Hubble's successor. They call the proposed instrument the Next Generation Space Telescope (NGST NGST Next Generation Space Telescope NGST Northrop-Grumman Space Technology NGST Next Generation Shopping Tool ). Plans are still rough, and NASA NASA: see National Aeronautics and Space Administration. NASA in full National Aeronautics and Space Administration Independent U.S. Administrator Daniel S. Goldin has limited the project to $500 million-one-fourth the amount spent to build and launch Hubble. Most designs call for a mirror 6 m to 8 m in diameter. Fully deployed, a telescope this big cannot fit inside any U.S. launch vehicle now in operation. Researchers say, however, that several foreign-made transport devices, including Russia's Proton vehicle, could be widened at relatively low cost to accommodate a 6-m telescope. J. Roger Angel, a famed mirror maker from 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, has already built a prototype of a one-piece 6-m mirror. An ultrathin ul·tra·thin adj. Very thin. glass shell supported by a lightweight backing, this reflecting surface does not require perfect casting. Instead, some 3,000 tiny, adjustable screws beneath the shell would correct for sagging or other defects. Other teams have drawn up blueprints for an 8-m telescope composed of several smaller mirrors. In one design, the mirrors would stack on top of each other for launching. Once the telescope is in orbit, they would fit together like pieces of a jigsaw puzzle. In another design, eight mirrors would surround a circular mirror like petals on a daisy; to fit inside a launch vehicle, four of the petals would fold up and the other four would fold down. Angel cautions that although devices that can fold or stack would allow for the launch of a larger telescope, the possibility that they will fail to open may make these designs unacceptable. Among other challenges, NGST must stay cold throughout its estimated 5-year life span. Otherwise, infrared radiation, or heat, generated by the telescope would swamp observations of the extraordinarily faint, distant celestial sources that the telescope is designed to detect. Rather than using a costly cryogenic system to keep the telescope cold, scientists hope to rely on the frigid environs of space itself. In one strategy, the telescope would be launched into a high-altitude orbit 1.5 million kilometers above Earth, where the ambient temperature Outside temperature at any given altitude, preferably expressed in degrees centigrade. is a mere 30 kelvins. To maintain this temperature inside the telescope, an umbrella-like shield must protect NGST from the sun's glare at all times. For John C. Mather John Cromwell Mather (b. August 7, 1946, Roanoke, Virginia) is an American astrophysicist, cosmologist and Nobel Prize in Physics laureate for his discovery with George Smoot "...of the black body form and anisotropy of the cosmic microwave background radiation. of Goddard, plans for NGST had their roots in a satellite, the Cosmic Background Explorer Cosmic Background Explorer: see infrared astronomy. Cosmic Background Explorer (COBE) U.S. satellite that from 1989 to 1993 mapped the cosmic background radiation field. In 1964, microwave radiation was discovered that permeated the cosmos uniformly. (COBE COBE: see infrared astronomy. ), that he helped design. In a triumph for cosmology, COBE found tiny temperature fluctuations in the otherwise uniform whisper of microwave radiation left over from 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. . These fluctuations correspond to lumps in the sea of matter dating from about 300,000 years after the birth of the universe (SN: 5/2/92, p. 292). Over time, the tiny lumps drew together more and more material, providing the seeds for the clusters and superclusters of galaxies seen by Keck, Hubble, and myriad other telescopes. COBE's mission ended 3 years ago, and Mather began searching for other challenges. Even before a NASA-funded panel recommended last year that the space agency build a large, infrared successor to Hubble, he and his colleagues had envisioned such an instrument. Above all, says Mather, he hopes that the new telescope will begin to fill in the murky gap between the minuscule lumps recorded by COBE and the large-scale structure that emerged less than 1 billion years later. Moreover, "if we can see signs of the first [visible-light] things turning on, we might learn something about the dark matter," adds Mather, now an NGST project scientist. These unseen, exotic particles, which clumped together before ordinary matter did, are invoked by theorists to explain how structures such as galaxies and galaxy clusters This page lists some of the more interesting galaxy clusters and groups. Defining the limits of galaxy clusters is imprecise as many clusters are still forming. In particular, clusters close to the Milky Way tend to be classified as galaxy clusters even when they are much smaller arose relatively rapidly in the cosmos. Believed to make up 90 to 99 percent of the mass of the universe, "dark matter is presumably pre·sum·a·ble adj. That can be presumed or taken for granted; reasonable as a supposition: presumable causes of the disaster. the stuff that makes ordinary matter move," he says. In the April 1 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. Letters, Jordi Miralda-Escuda of the University of Pennsylvania (body, education) University of Pennsylvania - The home of ENIAC and Machiavelli. http://upenn.edu/. Address: Philadelphia, PA, USA. in Philadelphia and Martin J. Rees of the University of Cambridge in England calculate that NGST should detect with relative ease a key signature from that early era-supernovas marking the death of the very first massive stars. In any stellar population, the heaviest stars burn the brightest and are the first to die. Stars between about eight and 30 times the mass of the sun end their brief lives with a bang, hurling into space their outer layers and leaving behind a collapsed, dense core. Even today, these violent outbursts may reach one-tenth the brightness of the galaxy in which they lie. In the early universe, when galaxies were smaller and less luminous, supernovas were the unquestionable champs, outshining the fledgling galaxies in which they resided, Miralda-Escuda and Rees note. "These supernovas could be the brightest things in the [early] universe," says Robert P. Kirshner of Harvard University Harvard University, mainly at Cambridge, Mass., including Harvard College, the oldest American college. Harvard College Harvard College, originally for men, was founded in 1636 with a grant from the General Court of the Massachusetts Bay Colony. . Being bright won't suffice. In order for supernovas to be easily recorded by NGST, they must also take place with reasonable frequency. Two factors suggest that these explosions, though rare, did occur often enough to make observations worthwhile, Miralda-Escuda and Rees argue. They base their assertion on two related findings by Keck astronomers over the past few years. In the course of observing quasars Proper naming of quasars are by Catalogue Entry, Qxxxx±yy using B1950 coordinates, or QSO Jxxxx±yyyy using J2000 coordinates. This page lists quasars.
adj. Being or occurring between galaxies: intergalactic space. in elements are highly ionized i·on·ize tr. & intr.v. i·on·ized, i·on·iz·ing, i·on·iz·es To convert or be converted totally or partially into ions. i . That presents two problems: Where did these elements come from, and what source of energy ionizes them? 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. emitted by the very first massive stars are the most likely source of the ionizing radiation-provided there were enough such stars. Those stars must also have produced the first heavy elements in the universe, because the Big Bang forged only hydrogen, helium, and trace amounts of beryllium beryllium (bərĭl`ēəm) [from beryl ], metallic chemical element; symbol Be; at. no. 4; at. wt. 9.01218; m.p. about 1,278°C;; b.p. 2,970°C; (estimated); sp. gr. 1.85 at 20°C;; valence +2. and boron boron (bōr`ŏn) [New Gr. from borax], chemical element; symbol B; at. no. 5; at. wt. 10.81; m.p. about 2,300°C;; sublimation point about 2,550°C;; sp. gr. 2.3 at 25°C;; valence +3. . Supernova explosions of these stars would have seeded the universe, including the hydrogen clouds, with the observed heavy elements-but only if the supernovas were sufficiently common. A phenomenon brought about by the expansion of the universe should help NGST capture a glimpse of these fiery explosions. Although the brightest emissions from a supernova peter out after about 20 days, expansion stretches out that time in the viewer's frame of reference. For instance, the brilliant light of a supernova emitted at a redshift redshift Displacement of the spectrum of an astronomical object toward longer wavelengths (visible light shifts toward the red end of the spectrum). In 1929 Edwin Hubble reported that distant galaxies had redshifts proportionate to their distances (see of 10-when the universe was less than 1 billion years old-would last a year. Miralda-Escuda and Rees estimate that NGST should spy, on average, one of these supernovas every year in a patch of sky one seven-hundredth the size of the full moon. Kirshner suggests that the telescope sweep through 10 patches of sky every month, staring for about an hour at each patch. The monthly observations should be more than enough to catch a supernova, he says. "This really ought to be quite a feasible enterprise." As an added benefit, the monthly visits would develop a body of data on each of the 10 patches that far surpasses what Hubble achieved when it stared at a single region of sky for 10 days in late 1995 (SN: 1/20/96, p. 36). In contrast to those observations, 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 , Kirshner calls his proposed set of observations the Deep Sweep. Abraham Loeb of Harvard and his colleagues argue that even though supernovas are the clear standouts in the early universe, clusters of the first generation of stars would have been about 1,000 times more common and should also be visible to NGST. Individual stars in this distant first generation would be too faint to detect. "I think it's much more interesting to see a population of stars at higher redshift than the supernovas" that arose from them, says Loeb. NGST "would see not just the remnants of massive stars but the whole population." With its large mirror and ability to detect infrared wavelengths invisible from the ground, NGST would have a unique capability to view the most distant reaches of the cosmos. Yet several astronomers at the NGST conference emphasized that the telescope could also shed light on the evolution of remote, but somewhat closer, galaxies already viewed by Hubble and by an assortment of ground-based instruments, including Keck and the Canada-France-Hawaii Telescope on Mauna Kea. These instruments provide information on the number, brightness, colors, shapes, and star formation rates of galaxies over a huge span of cosmic time, beginning a few billion years after the Big Bang and continuing to the present. To the surprise of many astronomers, this body of data suggests that the vast majority of stars didn't begin forming until relatively late, when the cosmos was perhaps 20 percent of its current age. The peak of star birth seems to have occurred even later, when the cosmos was about half as old as it is today. "It looks as though there really was a kind of baby boom, a burst of star formation" at that time, says Kirshner. In that sense, says cosmologist Simon D.M. White, director of the Max Planck Institute for Astrophysics The Max Planck Institute for Astrophysics is a Max Planck Institute, located in Garching, near Munich, Bavaria, Germany. It was founded as Max Planck Institute for Physics and Astrophysics in Garching, Germany, "we have [already] seen the epoch of galaxy formation." However, he adds, current observations paint only a sketchy picture of the process. Carlos S. Frenk of the University of Durham (body, education) University of Durham - A busy research and teaching community in the historic cathedral city of Durham, UK (population 61000). Its work covers key branches of science and technology and traditional areas of scholarship. in England likens the current state of affairs to having a snapshot of different individuals at selected stages of development-say a baby, an infant, a teenager, and an old person-and then trying to piece together a theory of human growth. The gaps between pictures, says White, are too great to reveal a complete theory. In addition, most of these images, as well as those to be taken by a new generation of ground-based telescopes, are recorded in visible light. For distant objects, visible light reaching Earth corresponds to radiation emitted in the ultraviolet-a set of wavelengths radiated almost entirely by the hottest, brightest, and shortest-lived stars in a galaxy. NGST's ability to examine longer wavelengths will provide a more accurate portrait of a distant galaxy, focusing on the lower-energy light emitted by the bulk of lower-mass, longer-lived stars. Such images may dramatically alter our view of galaxy evolution, says Richard S. Ellis of Cambridge. The puzzle of galaxy formation is far from over, Ellis notes. "We want to know much more about the physical processes that are shaping the galaxies that we see around us today." Telescopes like NGST, he adds, are vital for solving that puzzle. |
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