|
Topic Name: UBC Astronomers Discover white dwarf stars are born with a natal kick
Category: STAR (Space, Telecommunications & Radioscience)
Research persons: Prof. Harvey Richer, David Saul Davis
Location: University of British Columbia, Canada
Details
University of British Columbia astronomer
Harvey Richer and UBC graduate student Saul Davis have discovered that white
dwarf stars are born with a natal kick, explaining why these smoldering embers
of Sun-like stars are found on the edge rather than at the centre of globular star
clusters.
White dwarfs represent the third major stage of a star’s evolution. Like
the Sun, each star begins its life with a long stable state where nuclear
reactions take place in the core supplying the energy. After the core fuel is
depleted, it swells up and turns into a huge red giant. Later, the red giant
ejects its outer atmosphere and its core becomes a white dwarf that slowly cools
over time and radiates its stored thermal heat into space.
Using NASA’s Hubble telescope, Richer
and his team looked at the position of white dwarfs in NGC 6397, one of the
globular star clusters closest to Earth. Globular clusters are dense swarms of
hundreds of thousands of stars. About 150 of these clusters exist in the Milky
Way, each containing between 100,000 and one million stars.
“The distribution of young white dwarfs is the exact opposite of what we
expected,” says Prof. Richer, whose study will appear in the Monthly Notices
of the Royal Astronomical Society Letters in January 2008.
Richer explains that globular clusters sort out stars according to their
mass, governed by a gravitational billiard-ball game among stars. Heavier stars
slow down and sink to the cluster’s core, while lighter stars pick up speed
and move across the cluster to its outskirts. The team found that the older
white dwarfs were behaving as expected; they were scattered throughout the
cluster according to weight.
“Newly-minted white dwarfs should be near the center, but they are not,”
says Richer. “Our idea is that when these white dwarfs were born, they were
given a small kick of 7,000 to 11,000 miles an hour (three to five kilometers a
second), which rocketed them to the outer reaches of the cluster.”
Using computer simulations, Richer and his team showed that when white dwarfs
were born, their own mass acts like “rocket fuel” propelling them forward.
“If more of this mass is ejected in one direction, it could propel the
emerging white dwarf through space, just as exhaust from a rocket engine thrusts
it from the launch pad,” says Richer.
The researchers studied 22 young white dwarfs up to about 800 million years
old and 62 older white dwarfs between 1.4 and 3.5 billion years old. They
distinguished the younger from the older white dwarfs based on their color and
brightness. The younger ones are hotter, and therefore bluer and brighter than
the older ones.
Study co-authors are: I. King, University of Washington; J.Anderson, Space
Telescope Science Institute; J. Coffey, UBC, G. Fahlman, National Research
Council of Canada's Herzberg Institute of Astrophysics; J Hurley. Swinburne,
University of Technology; and J. Kalirai, University of California, Santa
Cruz.
Note for White dwarf
A white dwarf, also called a degenerate dwarf, is a small star composed mostly of electron-degenerate matter. As white dwarfs have mass comparable to the Sun's and their volume is comparable to the Earth's, they are very dense. Their faint luminosity comes from the emission of stored
heat. They comprise roughly 6% of all known stars in the solar neighborhood. The unusual faintness of white dwarfs was first recognized in 1910 by Henry Norris Russell, Edward Charles Pickering and Williamina
Fleming;, p. 1 the name white dwarf was coined by Willem Luyten in 1922.
White dwarfs are thought to be the final evolutionary state of all stars whose mass is not too high—over 97% of the stars in our
Galaxy., §1. After the hydrogen-fusing lifetime of a main-sequence star of low or medium mass ends, it will expand to a red giant which fuses helium to carbon and oxygen in its core by the triple-alpha process. If a red giant has insufficient mass to generate the core temperatures required to fuse carbon, an inert mass of carbon and oxygen will build up at its center. After shedding its outer layers to form a planetary nebula, it will leave behind this core, which forms the remnant white
dwarf. Usually, therefore, white dwarfs are composed of carbon and oxygen. It is also possible that core temperatures suffice to fuse carbon but not neon, in which case an oxygen-neon-magnesium white dwarf may be
formed. Also, some helium white dwarfs appear to have been formed by mass loss in binary systems.
Note for Globular cluster
A globular cluster is a spherical collection of stars that orbits a galactic core as a satellite. Globular clusters are very tightly bound by gravity, which gives them their spherical shapes and relatively high stellar densities toward their centers. The name of this category of star cluster is derived from the Latin globulus—a small sphere. A globular cluster is sometimes known more simply as a globular.
Globular clusters, which are found in the halo of a galaxy, contain considerably more stars and are much older than the less dense galactic, or open clusters, which are found in the disk. Globular clusters are fairly common; there are about 150 currently known globular clusters in the Milky Way, with perhaps 10–20 more
undiscovered. Large galaxies can have more: Andromeda, for instance, may have as many as
500. Some giant elliptical galaxies, such as M87, may have as many as 10,000 globular clusters. These globular clusters orbit the galaxy out to large radii, 40 kiloparsecs (approximately 131 thousand light years) or
more.
Every galaxy of sufficient mass in the Local Group has an associated group of globular clusters, and almost every large galaxy surveyed has been found to possess a system of globular
clusters. The Sagittarius Dwarf and Canis Major Dwarf galaxies appear to be in the process of donating their associated globular clusters (such as Palomar 12) to the Milky
Way. This demonstrates how many of this galaxy's globular clusters were acquired in the
past.
Although it appears that globular clusters contain some of the first stars to be produced in the galaxy, their origins and their role in galactic evolution are still unclear. It does appear clear that globular clusters are significantly different from dwarf elliptical galaxies and were formed as part of the star formation of the parent galaxy rather than as a separate galaxy.
About Researcher
Prof. Harvey Richer
David Saul
Davis
 
| Related research: |
'Thermometer Camera' ; 12-m telescope which allow to map large areas on the sky with high sensitivity, An international team of physicists suggests burst of gamma rays possibly lacked a gravitational wave, APL Astronomer Spies Conditions 'Just Right' for Building an Earth, Arecibo Observatory finds Neutron Stars can be Considerably more Massive and also difficult to form Black Holes, Astronomers have Found 10 new Planets Outside Solar System Using a System of Robotic Cameras, Cassini is on the Trail of a Runaway Mystery, Chandra discovers One of the fastest moving stars, cosmic cannonball, Did the big bang spawn trillions of black holes?, Discovery of the largest example of a “small” black hole, Fe-60 in the galaxy, Fleeting blue flashes of radiation emitted by particles may help crack cosmic mystery, Milky Way keeps a light grip on speedy neighbours, MU Engineers Develop an efficient and highly sophisticated mathematical algorithm for Complex Space Missions, Nano-sized Electronic Circuit Promises Bright View of Early Universe, NASA Goddard Lunar Science on a Roll, NASA Scientist Available for Interviews About New Jupiter Findings, NASA Spacecraft Is a 'Go' for Asteroid Belt, New Research Found that Comet Dust resembles Asteroid Materials with Samples from the Comet Wild 2 Carried by Stardust Mission, New Research have Made the Best Determination of the Power of a Supernova Explosion Using X-ray and Optical Observations, New SU Supercomputer SUGAR May Help Astronomers to Identify the Sound of a Celestial Black Hole, Ohio University Astronomers have Discovered a Faraway Binary Star System May Progenitor of a Rare Type of Supernova, Physicists have Observed the most Energetic Particles in the Universe Rarely Reach Earth at Full Strength, Physicists unveil the history of the solar system in grains of comet dust, Princeton Scientist found A dwarf star with a surprisingly magnetic personality, Research Team has Found New light on Mysterious Dark Energy Using ESO’s Very Large Telescope
|
|
