Temperamental monsters: massive stars may slim down in eruptive bursts."[I]t is now again on the increase. It is, and has been for a month, brighter than [the star] Canopus. Half-way indeed between him and Sirius, and very red." --Astronomer Charles P. Smyth, from letter dated Jan. 1, 1845 Late in 1837, a dim Milky Way Milky Way, the galaxy of which the sun and solar system are a part, seen as a broad band of light arching across the night sky from horizon to horizon; if not blocked by the horizon, it would be seen as a circle around the entire sky. star called Eta Carinae Eta Carinae (η Carinae or η Car) is a highly luminous hypergiant double star. Estimates of its mass range from 100–150 times the mass of the Sun, and its luminosity is about four million times that of the Sun. suddenly blossomed and soon became the second-brightest star, next to Sirius, in the night sky. During the next 19 years, a period now known as the Great Eruption, the star ejected two billowing bil·low n. 1. A large wave or swell of water. 2. A great swell, surge, or undulating mass, as of smoke or sound. v. bil·lowed, bil·low·ing, bil·lows v.intr. 1. , mushroom-shaped gas clouds, each 100 times as wide as our solar system solar system, the sun and the surrounding planets, natural satellites, dwarf planets, asteroids, meteoroids, and comets that are bound by its gravity. The sun is by far the most massive part of the solar system, containing almost 99.9% of the system's total mass. and containing enough mass to make 10 suns. Eta Carinae suffered another substantial, but less dramatic, eruption in 1890, and evidence is accumulating that it had undergone several other severe outbursts during the past 10,000 years. Even today, the star, which tips the scale at a whopping 100 solar masses, hurls the equivalent of two Earths of gas and dust into space each day. Although the outbursts have made Eta Carinae a striking spectacle, astronomers have long regarded the star as a freak of nature. Astronomical models indicate that most heavyweights expel large amounts of matter before they die, but that they eject this material relatively slowly, over their entire 3-to-4-million-year lifetimes. But new evidence--a combination of theory and observations--suggests that Eta Carinae's temperamental behavior may be the norm, not an anomaly, among extremely massive stars. Simulations indicate that the first stars to form were all extremely massive. Because these stars were the main sources of every element heavier than helium in the early universe, the evidence of widespread temperamental behavior may prompt a new look at how the cosmos acquired its assortment of chemical elements, including those necessary for life. The findings may in particular shed new light on the fate of the first stars in the universe. "There's a paradigm shift A dramatic change in methodology or practice. It often refers to a major change in thinking and planning, which ultimately changes the way projects are implemented. For example, accessing applications and data from the Web instead of from local servers is a paradigm shift. See paradigm. in our understanding of massive stars" that may affect views of how these stars live and die, the remnants they leave behind, and their contribution to the chemical makeup of the early universe, says Nathan Smith Nathan Smith may refer to:
WINDS OF CHANGE All massive stars lead short lives. The heaviest ones have a life span only about a thousandth of that of a star such as the sun. They can weigh 50 to 150 times the mass of the sun at birth, but during their life spans, they lose much of that mass via a steady, outgoing wind. Eventually, they die a fiery death in an explosion called a 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. . Before exploding, these stars, then known as Wolf-Rayet stars, have lost their outer atmosphere and slimmed down to a mere 10 to 20 times the mass of the sun. Until the explosion, the stars burn hydrogen at their cores, transforming it into helium. The nuclear reaction creates ultraviolet (UV) radiation, which ionizes an array of elements in the stars' outer layers. These 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 atoms absorb the radiation, and the kick imparted by the process blows off gas, creating a continuous, outward flow of matter. But just how much mass those winds carry away is now an open question, Smith and others say. Astronomers had assumed that the UV-absorbing ions are distributed smoothly and uniformly throughout a star's outer layers. Calculations using that assumption show that the winds are indeed intense enough to put heavy stars on a slow but steady diet, reducing their mass by tens of solar masses over several million years. Recent studies indicate that observers may have overestimated the strength of stellar winds. The new data show out that the material that absorbs radiation is unevenly distributed in the atmospheres of stars. Researchers measure the brightness of a star to deduce the amount of mass carried off by a wind. The greater the emission, the larger the mass loss. But an atmosphere that consists of dense clumps of ions will radiate ra·di·ate v. 1. To spread out in all directions from a center. 2. To emit or be emitted as radiation. ra more strongly than an atmosphere containing the same amount of material distributed more uniformly. If astronomers don't account for the higher intensity of light emitted by a dumpier atmosphere, they can be fooled into thinking that the wind carries away more mass than it really does. "Currently accepted mass-loss rates may need to be revised downward as a consequence of previously neglected clumping, note Joachim Puls of the University of Sternwarte in Munich and his colleagues in a review article recently posted on the Internet (http:/xxx.lanl.gov/astro-ph/0607290). 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. Smith, Stanley P. Owocki of the University of Delaware [3] The student body at the University of Delaware is largely an undergraduate population. Delaware students have a great deal of access to work and internship opportunities. in Newark, and other researchers, the total wind may be only one-tenth as strong as models had indicated. That's too gentle to blow away all the matter that astronomers know must be expelled by massive stars before they explode. "Steady winds are simply inadequate for the envelope shedding needed to form a Wolf-Rayet star" Smith and Owocki note in the July 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. Smith also reviewed the evidence for episodic outbursts among heavyweights in May at a meeting on massive stars at 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 ODD NORMAL? Instead of the weight-loss-by-wind theory, researchers now propose that most extremely massive stars slim down Verb 1. slim down - take off weight lose weight, melt off, slim, slenderize, thin, reduce sweat off - lose weight by sweating; "I sweated off 3 pounds in the sauna" by undergoing extraordinarily violent eruptions like the one that convulsed Eta Carinae in the mid-1800s. The eruptions would occur during the era just before a massive star enters its Wolf-Rayet phase. During this stage, heavy stars such as Eta Carinae are known as luminous blue variables. This phase lasts for less than 100,000 years--a mere blink in astronomical time mean solar time reckoned by counting the hours continuously up to twenty-four from one noon to the next. See also: Time . One eruption wouldn't be enough to shed all the mass, but several at different times during the entire luminous-blue-variable era would suffice, Smith proposes. His idea is more than just a pie-in-the-sky theory. For example, nested shells of material surrounding the mushroom-shaped clouds recently cast out by the star suggest that Eta Carinae had in fact suffered previous outbursts over several thousand years. There's compelling circumstantial evidence circumstantial evidence In law, evidence that is drawn not from direct observation of a fact at issue but from events or circumstances that surround it. If a witness arrives at a crime scene seconds after hearing a gunshot to find someone standing over a corpse and holding a that the star had undergone eruptions similar to the one witnessed some 150 years ago, says theorist Mario Livio Mario Livio (born 1945) is an astrophysicist and an author of works that popularize science and mathematics. He is currently Senior Astrophysicist at the Hubble Space Telescope Science Institute. of the Space Telescope Science Institute. Astronomers don't fully understand what set off Eta Carinae, but a few other stars seem to have undergone similar outbursts. A Milky Way star called P Cygni P Cygni is a variable star in the constellation Cygnus. It is a hypergiant luminous blue variable (LBV) star of spectral type B2 Ia that is one of the most luminous stars in the Milky Way galaxy and is located about 5000 to 6000 light years from Earth. , which brightened and shed a tenth of a solar mass in 1600, may have undergone even fiercer outbursts over the past few thousand years, Smith and others note. Furthermore, astronomers have recently identified in other galaxies several stars that they call "supernova imposters." These stars haven't yet blown themselves to bits in supernovas, but their eruptions are extremely bright and energetic. Indeed, some of these stars resemble models of what an Eta Carinae--like eruption might look like a few thousand years after it happened, notes astrophysicist Paul Crowther of the University of Sheffield The University of Sheffield is a research university, located in Sheffield in South Yorkshire, England. Reputation Sheffield was the Sunday Times University of the Year in 2001 and has consistently appeared as their top 20 institutions. in England. What's more, shells of material that surround some bona fide [Latin, In good faith.] Honest; genuine; actual; authentic; acting without the intention of defrauding. A bona fide purchaser is one who purchases property for a valuable consideration that is inducement for entering into a contract and without suspicion of being supernovas indicate that these once-massive stars ejected large amounts of material only a few thousand years before they exploded. The challenge to proving Smith's hypothesis, adds Crowther, is the brevity of the luminous-blue-variable era. Massive stars are rare, and it's hard to find one that is actually in that brief phase of evolution. "We have only a very small number of these objects to play with, Crowther says. While acknowledging the merits of Smith's work, Crowther says that he's not entirely swayed by the arguments. In the old scenario, he notes, winds accounted for all the mass lost by heavy stars. In the new picture, powerful eruptions over a short time either replace or overshadow o·ver·shad·ow tr.v. o·ver·shad·owed, o·ver·shad·ow·ing, o·ver·shad·ows 1. To cast a shadow over; darken or obscure. 2. To make insignificant by comparison; dominate. the wind scenario. "Nathan [Smith] sells a great story," says Crowther, but "I think the reality is somewhere in between," those two pictures. BIG PAYOFF The recognition that massive stars may shed a significant amount of their heft through brief eruptions is likely to change the way astronomers think of these heavyweights, Crowther. The presumed temperature, composition, turbulence, and other properties of these stars must differ if they expel most of their mass in a few late-stage, concentrated bursts rather than steadily throughout their lives, Smith agrees. Those properties, in turn, determine when a star finishes burning its main fuel, hydrogen, and how long it lives. Determining when in its life a massive star spews material is crucial for understanding the chemical composition of the universe. Stars produce heavier elements as they age, fusing hydrogen into helium, helium into carbon, and carbon into oxygen. A steady wind driving out material early in the life of a star would litter the cosmos with lighter elements than would a series of late-stage eruptions. It's too soon to tell exactly how this would alter estimates of the chemical contents of the cosmos, but the consequences are likely to be most dramatic early in the universe, says Smith. Current theory holds that the first stars in the universe were much heavier than stars are today and that they ranged from 100 to several hundred times the mass of the sun. Those early stars contained only the elements forged in the aftermath of 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. : hydrogen, helium, and traces of lithium. According to the old stellar-wind model of mass loss, the first stars wouldn't have shed any material before dying as Supernovas because the winds are generated only by the absorption of radiation by heavier elements. In Smith's eruption model, these stars would expel some material a few thousand years before they die as supernovas rather than stockpiling all of it until the bitter end bitter end n. 1. A final, painful, or disastrous extremity. 2. Nautical The inboard end of a chain, rope, or cable, especially the end of a rope or cable that is wound around a bitt. . That's because the proposed eruptions don't depend on whether the star has made heavy elements. "The main question is whether a [first-generation] massive star shed most of its mass before or during a supernova event" notes Smith. A series of episodic Eta Carinae--like eruptions would have decreased the weight of early stars before they finally exploded as supernovas, perhaps influencing the type of supernovas they became. According to most theorists, many of the heaviest stars in the early universe were obliterated o·blit·er·ate tr.v. o·blit·er·at·ed, o·blit·er·at·ing, o·blit·er·ates 1. To do away with completely so as to leave no trace. See Synonyms at abolish. 2. by their explosions and blasted into space every heavy element that they had forged. But with less mass, some of those stars would be more likely to have left behind an ultradense cinder--a black hole--when they became supernovas. Several solar masses of iron and perhaps a few other heavy elements would be trapped inside the black holes and never make their way out into interstellar space interstellar space See under space. Noun 1. interstellar space - the space between stars outer space, space - any location outside the Earth's atmosphere; "the astronauts walked in outer space without a tether"; "the first . Livio says that if eruptions such as those of Eta Carinae were common among the most-massive stars, "it may change significantly the [assumed] end products of those stars, including black holes and supernovas." |
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