CHANDRA
Chandra Captures Giant Ring of Black Holes
by Nancy Atkinson on February 9, 2011 of UniverseToday.com
Arp 147 contains a spiral galaxy (right) that collided with an elliptical galaxy (left), triggering a wave of star formation. Credit: X-ray: NASA/CXC/MIT/S.Rappaport et al, Optical: NASA/STScI
Just in time for Valentine’s Day comes a new image of a ring — not of jewels — but of black holes. This composite image of Arp 147, a pair of interacting galaxies located about 430 million light years from Earth, shows X-rays from the NASA’s Chandra X-ray Observatory (pink) and optical data from the Hubble Space Telescope (red, green, blue) produced by the Space Telescope Science Institute (STScI) in Baltimore, Md.
Arp 147 contains the remnant of a spiral galaxy (right) that collided with the elliptical galaxy on the left. This collision has produced an expanding wave of star formation that shows up as a blue ring containing in abundance of massive young stars. These stars race through their evolution in a few million years or less and explode as supernovas, leaving behind neutron stars and black holes.
A fraction of the neutron stars and black holes will have companion stars, and may become bright X-ray sources as they pull in matter from their companions. The nine X-ray sources scattered around the ring in Arp 147 are so bright that they must be black holes, with masses that are likely ten to twenty times that of the Sun.
This composite image of Arp 147 shows Chandra X-ray data in pink, Hubble optical data in red, green and blue, ultraviolet GALEX data in green and infrared Spitzer data in red. (Credit: X-ray: NASA/CXC/MIT/S.Rappaport et al, Optical: NASA/STScI)
An X-ray source is also detected in the nucleus of the red galaxy on the left and may be powered by a poorly-fed supermassive black hole. This source is not obvious in the composite image but can easily be seen in the X-ray image. Other objects unrelated to Arp 147 are also visible: a foreground star in the lower left of the image and a background quasar as the pink source above and to the left of the red galaxy.
Infrared observations with NASA’s Spitzer Space Telescope and ultraviolet observations with NASA’s Galaxy Evolution Explorer (GALEX) have allowed estimates of the rate of star formation in the ring. These estimates, combined with the use of models for the evolution of binary stars have allowed the authors to conclude that the most intense star formation may have ended some 15 million years ago, in Earth’s time frame.
From Wikipedia:
The Chandra X-ray Observatory is a satellite launched on STS-93 by NASA on July 23, 1999. It was named in honor of Indian-American physicist Subrahmanyan Chandrasekhar who is known for determining the maximum mass for white dwarfs. "Chandra" also means "moon" or "luminous" in Sanskrit.
Chandra Observatory is the third of NASA's four Great Observatories. The first was Hubble Space Telescope; second the Compton Gamma Ray Observatory, launched in 1991; and last is the Spitzer Space Telescope. Prior to successful launch, the Chandra Observatory was known as AXAF, the Advanced X-ray Astrophysics Facility. AXAF was assembled and tested by TRW (now Northrop GrummanRedondo Beach, California. Chandra is sensitive to X-ray sources 100 times fainter than any previous X-ray telescope, due primarily to the high angular resolution of the Chandra mirrors. Space Technology) in
Since the Earth's atmosphere absorbs the vast majority of X-rays, they are not detectable from Earth-based telescopes, requiring a space-based telescope to make these observations.
Chandra X-ray Observatory
Chandra X-ray Observatory and Inertial Upper Stage sit inside the payload bay
on Space Shuttle Columbia mission STS-93
General Information
Organization
Major contractors
Launch date
Launched from
Launch vehicle
Mission length
Mass
Orbit height
Orbit period
Diameter
Collecting area
Instruments
History
In 1976 the Chandra X-ray Observatory (called AXAF at the time) was proposed to NASA by Riccardo Giacconi and Harvey Tananbaum. Preliminary work began the following year at Marshall Space Flight Center (MSFC) and the Smithsonian Astrophysical Observatory (SAO). In the meantime, in 1978, NASA launched the first imaging X-ray telescope, Einstein (HEAO-2), into orbit. Work continued on the Chandra project through 1980s and 1990s. In 1992, to reduce costs, the spacecraft was redesigned. Four of the twelve planned mirrors were eliminated, as were two of the six scientific instruments. Chandra's planned orbit was changed to an elliptical one, reaching one third of the way to the Moon's at its farthest point. This eliminated the possibility of improvement or repair by the space shuttle but put the observatory above the Earth's radiation belts for most of its orbit.
AXAF was renamed Chandra in 1998 and launched in 1999 by the shuttle Columbia (STS-93). At 22753 kg, it was the heaviest payload ever launched by the shuttle, a consequence of the two-stage Inertial Upper Stage booster rocket system needed to transport the spacecraft to its high orbit.
Chandra has been returning data since the month after it launched. It is operated by the SAO at the Chandra X-ray Center in Cambridge, Massachusetts, with assistance from MIT and Northrop Grumman Space Technology. The ACIS CCDs suffered particle damage during early radiation belt passages. To prevent further damage, the instrument is now removed from the telescope's focal plane during passages.
Although Chandra was initially given an expected lifetime of 5 years, on 4 September 2001 NASA extended its lifetime to 10 years "based on the observatory's outstanding results."[2] Physically Chandra could last much longer. A study performed at the Chandra X-ray Center indicated that the observatory could last at least 15 years.[3] On 24 July 2008 the International X-Ray Observatory (IXO), a joint project between ESA, NASA and JAXA, was proposed as the next major X-ray observatory. Its expected launch date is 2020.[4]
Discoveries
In this image of PSR B1509-58, the lowest energy X-rays that Chandra detects are red, the medium range is green, and the most energetic ones are colored blue.
The data gathered by Chandra have greatly advanced the field of X-ray astronomy.
The first light image, of supernova remnant Cassiopeia A, gave astronomers their first glimpse of the compact object at the center of the remnant, probably a neutron star or black hole. (Pavlov, et al., 2000)
In the Crab Nebula, another supernova remnant, Chandra showed a never-before-seen ring around the central pulsar and jets that had only been partially seen by earlier telescopes. (Weisskopf, et al., 2000)
The first X-ray emission was seen from the supermassive black hole, Sagittarius A*, at the center of the Milky Way. (Baganoff, et al., 2001)
Chandra found much more cool gas than expected spiralling into the center of the Andromeda Galaxy.
Pressure fronts were observed in detail for the first time in Abell 2142, where clusters of galaxies are merging.
The earliest images in X-rays of the shock wave of a supernova were taken of SN 1987A.
Chandra showed for the first time the shadow of a small galaxy as it is being cannibalized by a larger one, in an image of Perseus A.
A new type of black hole was discovered in galaxy M82, mid-mass objects purported to be the missing link between stellar-sized black holes and supermassive black holes. (Griffiths, et al., 2000)
X-ray emission lines were associated for the first time with a gamma-ray burst, Beethoven Burst GRB 991216. (Piro, et al., 2000)
High school students, using Chandra data, discovered a neutron star in supernova remnant IC 443.
Observations by Chandra and BeppoSAX suggest that gamma-ray bursts occur in star-forming regions.
Chandra data suggested that RX J1856.5-3754 and 3C58, previously thought to be pulsars, might be even denser objects: quark stars. These results are still debated.
Sound waves from violent activity around a supermassive black hole were observed in the Perseus Cluster (2003).
TWA 5B, a brown dwarf, was seen orbiting a binary system of Sun-like stars.
Nearly all stars on the main sequence are X-ray emitters. (Schmitt & Liefke, 2004)
The X-ray shadow of Titan was seen when it transitted the Crab Nebula.
X-ray emissions from materials falling from a protoplanetary disc into a star. (Kastner, et al., 2004)
Hubble constant measured to be 76.9 km/s/Mpc using Sunyaev-Zel'dovich effect.
2006 Chandra found strong evidence that dark matter exists by observing supercluster collision
2006 X-ray emitting loops, rings and filaments discovered around a supermassive black hole within Messier 87 imply the presence of pressure waves, shock waves and sound waves. The evolution of Messier 87 may have been dramatically affected.[5]
Observations of the Bullet cluster put limits on the cross-section of the self-interaction of dark matter.[6]
"The Hand of God" photograph of PSR B1509-58.
Technical Description
Unlike optical telescopes which possess simple aluminized parabolic surfaces (mirrors), X-ray telescopes generally use a Wolter telescope consisting of nested cylindrical paraboloid and hyperboloid surfaces coated with iridium or gold. X-ray photons would be absorbed by normal mirror surfaces, so mirrors with a low grazing angle are necessary to reflect them. Chandra uses four pairs of nested mirrors, together with their support structure, called the High Resolution Mirror Assembly (HRMA); the mirror substrate is 2 cm-thick glass, with the reflecting surface a 33 nm iridium coating, and the diameters are 65 cm, 87 cm, 99 cm and 123 cm.[7] The thick substrate and particularly careful polishing allowed a very precise optical surface, which is responsible for Chandra's unmatched resolution: between 80% and 95% of the incoming X-ray energy is focused into a one-arcsecond circle. However, the thickness of the substrates limit the proportion of the aperture which is filled, leading to the low collecting area compared to XMM-Newton.
Chandra's highly elliptical orbit allows it to observe continuously for up to 55 hours of its 65 hour orbital period. At its furthest orbital point from earth, Chandra is one of the furthest from earth earth-orbiting satellites. This orbit takes it beyond the geostationary satellites and beyond the outer Van Allen belt.[8]
With an angular resolution of 0.5 arcsecond (2.4 µrad), Chandra possesses a resolution over one thousand times better than that of the first orbiting X-ray telescope.
Instruments
The Science Instrument Module (SIM) holds the two focal plane instruments, the Advanced CCD Imaging Spectrometer (ACIS) and the High Resolution Camera (HRC), moving whichever is called for into position during an observation.
ACIS consists of 10 CCD chips and provides images as well as spectral information of the object observed. It operates in the range of 0.2 - 10 keV. HRC has two micro-channel plate components and images over the range of 0.1 - 10 keV. It also has a time resolution of 16 microseconds. Both of these instruments can be used on their own or in conjunction with one of the observatory's two transmission gratings.
The transmission gratings, which swing into the optical path behind the mirrors, provide Chandra with high resolution spectroscopy. The High Energy Transmission Grating Spectrometer (HETGS) works over 0.4 - 10 keV and has a spectral resolution of 60-1000. The Low Energy Transmission Grating Spectrometer (LETGS) has a range of 0.09 - 3 keV and a resolution of 40-2000.
See also
XMM-Newton, an X-ray telescope with greater collecting area but less resolution.
References
Further Reading
Pavlov GG, Zavlin VE, Aschenbach B, Trumper J, Sanwal D (2000). "The Compact Central Object in Cassiopeia A: A Neutron Star with Hot Polar Caps or a Black Hole?". Astrophysical Journal 531 (1): L53–L56. doi:10.1086/312521. PMID 10673413.
Weisskopf MC, Hester JJ, Tennant AF, Elsner RF, Schulz NS, Marshall HL, Karovska M, Nichols JS, Swartz DA, Kolodziejczak JJ, O'Dell SL (2000). "Discovery of Spatial and Spectral Structure in the X-Ray Emission from the Crab Nebula". Astrophysical Journal 536 (2): L81–L84. doi:10.1086/312733. PMID 10859123.
Baganoff FK, Bautz MW, Brandt WN, Chartas G, Feigelson ED, Garmire GP, Maeda Y, Morris M, Ricker GR, Townsley LK, Walter F (2001). "Rapid X-ray flaring from the direction of the supermassive black hole at the Galactic Centre". Nature 413 (6851): 45–8. doi:10.1038/35092510. PMID 11544519.
Griffiths RE, Ptak A, Feigelson ED, Garmire G, Townsley L, Brandt WN, Sambruna R, Bregman JN (2000). "Hot plasma and black hole binaries in starburst galaxy M82". Science 290 (5495): 1325–8. doi:10.1126/science.290.5495.1325. PMID 11082054.
Piro L, Garmire G, Garcia M, Stratta G, Costa E, Feroci M, Meszaros P, Vietri M, Bradt H, Frail D, Frontera F, Halpern J, Heise J, Hurley K, Kawai N, Kippen RM, Marshall F, Murakami T, Sokolov VV, Takeshima T, Yoshida A (2000). "Observation of X-ray lines from a gamma-ray burst (GRB991216): evidence of moving ejecta from the progenitor". Science 290 (5493): 955–8. doi:10.1126/science.290.5493.955. PMID 11062121.
Kastner JH, Richmond M, Grosso N, Weintraub DA, Simon T, Frank A, Hamaguchi K, Ozawa H, Henden A (2004). "An X-ray outburst from the rapidly accreting young star that illuminates McNeil's nebula". Nature 430 (6998): 429–31. doi:10.1038/nature02747. PMID 15269761.
External Links
Audio - Cain/Gay (2010) Astronomy Cast Chandra X-Ray Observatory
Retrieved from "http://en.wikipedia.org/wiki/Chandra_X-ray_Observatory"
Categories: Space telescopes | X-ray telescopes | Artificial satellites orbiting Earth | Chandra X-ray Observatory | 1999 in spaceflight
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