Hail the cosmic revolution.With nicknames such as Gilgamesh, Aphrodite Aphrodite (ăfrədī`tē), in Greek religion and mythology, goddess of fertility, love, and beauty. Homer designated her the child of Zeus and Dione. , and Athena--as well as Elvis--10 recently discovered supernovas are something special. Indeed, these supernovas provide what appears to be proof of one of the weirdest properties of the universe: Something is pushing objects in the cosmos apart at an ever-faster rate. Adam G. Riess 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). in Baltimore is presenting the new findings this week at a cosmology symposium at Case Western Reserve University in Cleveland. The data "will help us understand the nature of cosmic acceleration," says cosmologist Michael S. Turner of the University of Chicago. The notion of a universe speeding up its expansion rate has been in the spotlight since 1998, when two teams of astronomers measured the brightness of type 1a supernovas that were remote but considerably closer to Earth than the newfound crop (SN: 3/21/98, p. 185). Because type 1a supernovas all have about the same intrinsic brightness, like lightbulbs of the same wattage wattage the output or consumption of an electric device expressed in watts. , it's easy to predict how bright they ought to appear on the basis of their distance from Earth. But the measured brightness of these stellar explosions proved puzzling: If the universe has expanded at a constant or diminishing rate 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. , then the supernovas are about 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 the universe's expansion has been speeding up over the past several billion years, however, the supernovas would be farther away than astronomers originally thought and therefore would have to appear dimmer. But scientists worried that intergalactic in·ter·ga·lac·tic adj. Being or occurring between galaxies: intergalactic space. in dust, rather than distance, could account for the dimming. Or maybe these supernova explosions, which popped off at a time when the universe was about 10 billion years old, were intrinsically dimmer than younger ones. The new findings sweep away those concerns, says Riess. The results rely on the relative densities in the early universe of matter and the mysterious entity believed to have revved up cosmic expansion. That entity, which some cosmologists call dark energy, opposes gravity's familiar tug by pushing bodies apart. Dark energy is believed to have been constant or nearly so for most of cosmic history. In contrast, the density of matter, which gives rise to gravitational grav·i·ta·tion n. 1. Physics a. The natural phenomenon of attraction between physical objects with mass or energy. b. The act or process of moving under the influence of this attraction. 2. attraction, was much larger in the past because the universe was much smaller. During the first several billion years of the cosmos, the density of matter was so great that its pull would have overwhelmed dark energy's push. Supernovas that hail from such an era, in which the cosmos' expansion was slowing down, ought to appear brighter than supernovas in a universe that was always expanding at a constant or accelerated rate. In contrast, such confounding confounding when the effects of two, or more, processes on results cannot be separated, the results are said to be confounded, a cause of bias in disease studies. confounding factor effects as dust could only make distant supernovas look dimmer. Two years ago, Riess' team reported that observations of a single type 1a supernova--the most distant ever found--revealed the brightening indicative of an early cosmic slowdown (SN: 3/31/01, p. 196). Now, using the Hubble Space Telescope'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. (SN: 9/6/03, p. 155), the researchers have found 10 other remote supernovas that show the same brightening. Riess' data are "the first that provide direct and solid evidence for an earlier, decelerating phase" of the universe, says Turner. That leaves theorists to puzzle over exactly what provides the cosmic push. If dark energy provides the impetus, researchers aren't sure of its source. Alternatively, the accelerated expansion may be due to a new feature of gravity that makes its presence known only on the very large scales of the present-day universe. The new supernova data are "very important to us" because they will help reveal whether new gravitational physics is at play, says one of the theory's founders, Georgi Dvali of New York University New York University, mainly in New York City; coeducational; chartered 1831, opened 1832 as the Univ. of the City of New York, renamed 1896. It comprises 13 schools and colleges, maintaining 4 main centers (including the Medical Center) in the city, as well as the . |
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