Early Galaxies UDFy-38135539
and UDFj-39546284
Early Galaxies UDFy-38135539 |
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Garth
D. Illingworth,
HUDF09 Team,
ESA,
NASA
Larger and
jumbo composite
images.
Located around 13.1 billion light-years
away, UDFy-38135539 may be the
second earliest galaxy identified as
such, as of January 26, 2011
(more).
Breaking News
On September 19, 2012, astronomers revealed that they had detected another ancient galaxy with the assistance of gravitational lensing, as part of the Cluster Lensing And Supernova Survey with Hubble CLASH) program. With a cosmological redshift "z" of 9.6, MACS 1149-JD was observed as it was 490 million years after the Big Bang. The galaxy's color indicates that its stars formed up to 200 million years earlier, which suggests that the object existed "in a primitive form when the universe was only 300 million years old." The galaxy was observed to be small and compact, containing only around 1 percent of the Milky Way's mass (Hubble news release; and Maggie McKee, New Scientist, September 19, 2012).
Zoltan G. Levay,
STScI,
ESA,
NASA
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jumbo composite
images.
Located around 13.2 billion light-years away,
MACS1149-JD is one of the earliest galaxies
identified, as of September 19, 2012
(more).
In an article published in the journal Nature on January 26, 2011, astronomers using the Hubble Space Telescope from 2009 to 2010 revealed the detection of old known galaxy at at a cosmological redshift of Z~10, around 13.2 billion years away. Designated UDFj-39546284, the compact proto-galaxy of young and massive, blue stars is imaged at around 480 million years after the Big Bang (four percent of the universe's current age). The astronomers believe that their observations provide supporting evidence that the universe was forming stars at a very fast rate grew during a 200-million-year time span, when "the rate of star birth increased by about a factor of ten going from 480 million years to 650 million years after the Big Bang," possibly "from gas trapped in a pocket of "dark matter." Located in Constellation Fornax like proto-galaxy UDFy-38135539 (the previous record holder), UDFj-39546284 is visible only at the farthest infrared wavelengths detectable by Hubble, and so even farther objects are thought by the astronomers to require the James Webb space telescope, which is optimized for infrared light observation and planned for deployment later this decade (Hubble new release with more images and videos; and Bouwens et al, 2011).
Bouwens et al, 2011;
HUDF09 Team,
ESA,
NASA
Larger and
jumbo composite
images.
Located around 13.2 billion light-years away,
UDFj-39546284 may be the earliest galaxy identified
as such, as of January 26, 2011
(more).
Candidate Galaxy UDFy-38135539
Located in Constellation Fornax, candidate galaxy UDFy-38135539 is the earliest object identified as a potential galaxy, as of October 20, 2010. Its light was emitted less than 600 million years after the Big Bang (at a cosmological redshift of z=8.55), a few hundred million years into the period of the reionization of hydrogen gas that began during the Cosmic Dark Ages. This Epoch of Reionization lasted from as early as 150 million to as late as a billion years after the Big Bang and after neutral hydrogen had formed and began to coalesce to form quasars, stars, and the first galaxies. The period was identified by characteristic hydrogen signatures which became more and more prominent from the scattering of photons created by ionized gas clouds. During this period, the cosmos was not fully transparent because the opaque "fog" of neutual hydrogen gas had to be "re-ionized" by the intense ultraviolet (UV) light from the first stars and galaxies (ESO press release and videos; Lehnert et al, 2010; and David Shiga, New Scientist, October 20, 2010).
Djorgovski
et al, 2006;
Digital Media Center,
CalTech
Larger and
jumbo illustrationa.
The
Epoch
of Reionization
began during the
Cosmic
Dark Ages, when neutral
hydrogen clouds made the
cosmos opaque to light.
In August and September 2009, astronomers using the new Wide Field Camera 3 on the Hubble Space Telescope discovered several objects in near-infrared light, which appeared to be part of a primordial population of compact, ultra-blue galaxies that had never been detected before, shining through the fog of reionisation (NASA news release). The apparent galaxies were so blue that they appeared to be extremely deficient in elements heavier than hydrogen and helium ("metals"). Confirming the distances to those faint, remote objects required reliable spectroscopy from very large ground-based telescopes and measurement of the redshift of each galaxy’s light. After the announcement of its discovery, UDFy-38135539 was observed with the enormous collecting power of an 8.2-meter telescope in the European Southern Observatory's Very Large Telescope (VLT) array and the extreme sensitivity of the infrared spectroscopic instrument, SINFONI, which allowed a team of astronomers to more precisely estimate UDFy-38135539's distance.
Marcelo
Alvarez, Ralf Kaehler, and
Tom
Abel;
and Alvarez
et al, 2009
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jumbo composite
images.
UDFy-38135539 was found in the
Reionization
Epoch, just around
a few hundred million years after
the
Big
Bang during the
Cosmic
Dark Ages
(more).
The astronomers evaluating UDFy-38135539 concluded that its UV radiation was not powerful enough on its own to clear out the hydrogen fog within its local region. They believe that there must have been other galaxies, probably fainter and less massive nearby companions of UDFy-38135539, which were helping make the space around the galaxy transparent. Without the the additional UV radiation, the light from UDFy-38135539 would not have been able to penetrate the surrounding hydrogen fog and arrive at Earth some 13.1 billion years later.
WMAP,
GSFC,
NASA --
more animation images.
While small, UDFy-38135539 may have had a greater
proportionate population of massive stars that brighter,
hotter, and more massive than even today's luminous
blue variable stars, such as Eta Carinae
and the
Pistol Star, that were born with as much as 200 Solar-
masses, or even R136a1 with 265 Solar-masses.
UDFy-38135539 is quite small compared to a modern spiral galaxy. As observed 13.1 billion years ago, it probably only had only a tenth to a hundredth of the stars in the Milky Way today. On the other hand, it probably burned relatively bright for its size with a greater proportionate population of very massive, hot blue stars possible when gas metallicity is low.
Other Information
Up-to-date technical summaries on this object may soon become available at: NASA's ADS Abstract Service for the Astrophysics Data System; the SIMBAD Astronomical Database mirrored from CDS, which may require an account to access; and the NSF-funded, arXiv.org Physics e-Print archive's search interface.
Fornax is another of those constellations created by the Abbé [Abbot] Nicholas Louis de La Caille (1713-1762), who had the great honor of naming 15 of the 88 constellations by becoming the first astronomer to systematically observe the entire night sky by traveling to the Cape of Good Hope at the southern tip of Africa from 1750-54. Lacaille took several dozen fairly bright stars away from the middle of Eridanus to create Fornax Chemica, the Chemical Furnace. For more information and an illustration about the stars and objects in this constellation, go to Christine Kronberg's Fornax. For another illustration, see David Haworth's Fornax.
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