Andrew Yee[_1_]
January 20th 08, 01:45 AM
Joint Astronomy Centre
Hilo, Hawaii
Contact:
Inge Heyer, Science Outreach Specialist
Tel: +1 808 969 6524 Fax: +1 808 961 6516
Images, notes, and contact details appear below.
EMBARGOED UNTIL 9AM (CST) JANUARY 9, 2008
Heat from the Heavens -- Opening up the Infrared Sky
The infrared sky is expanding significantly for the world astronomical
community with the first world release of data (DR1) from the UKIRT Infrared
Deep Sky Survey (UKIDSS).
UKIDSS DR1 has mapped a larger volume of the sky than any previous infrared
survey. As the UKIDSS project progresses, it will gradually become the
dominant source of information about the infrared sky, expanding its volume
by a factor of 15 beyond DR1.
For the past two years, the United Kingdom Infrared Telescope (UKIRT) in
Hawaii has been systematically scanning the heavens for five different
"colours" of faint infrared light. This allows astronomers to penetrate dark
clouds where stars are currently forming, and to locate stars much less
massive and much cooler than the Sun. Furthermore, our own Galaxy (the Milky
Way) is transparent to the infrared, making it possible to see all the way
to its centre and beyond. And finally, the expansion of the Universe
stretches visible light from the most distant (and youngest) galaxies and
quasars into the infrared part of the spectrum, and by observing this
infrared light we can trace the evolution of galaxies from their youngest
members. The first world release of these data makes all this information
available to researchers everywhere.
Andy Lawrence from the University of Edinburgh, the UKIDSS Principal
Investigator, said: "We are moving into new territory. This survey probes
huge volumes of space, so that we can locate rare but important objects like
the very coolest and least luminous stars and the most distant galaxies.
Astronomers in Europe have started getting the science out, but this world
release should really unleash the scientific potential of the dataset."
The present release, large though it is, however, is just the beginning.
Andy Adamson, Associate Director of UKIRT, says: "WFCAM has recently taken
its one millionth observation, and the UKIDSS survey is progressing
strongly. UKIDSS will have surveyed a volume 15 times larger than the
current release, DR1, by the time it is completed in 2012."
Results from this world-leading effort are released in two stages -- first
to the member nations of the European Southern Observatory (ESO), and 18
months later to the world astronomical community. The data now being
released worldwide were obtained in the first, intensive and exciting, WFCAM
observing periods on the UKIRT telescope, up to January 2006. There will be
new data releases approximately every six months over the coming five years.
Astronomers from the ESO nations have been busily following up on the early
UKIDSS data for the past year. The survey has proved itself a rich source of
exotic objects, exactly as expected. Steve Warren, the UKIDSS Survey
Scientist, highlights the discovery of the coolest known brown dwarf in the
Galaxy -- ULAS J0034 for short -- which, at an absolute temperature only
just over twice that of the Earth, is fully 100 degrees cooler than any
other known brown dwarf. This is likely one of the closest astronomical
objects outside the Solar System, and was discovered in the shallow UKIDSS
Large Area Survey (LAS).
UKIDSS is also expected to discover some of the most distant objects known,
and it appears to be well on the way to this goal. DR1 includes early data
from the Ultra-Deep Survey (UDS), which aims to study the evolution of
galaxies when the Universe was a fraction of its current age.
This project is extraordinarily ambitious, requiring the telescope to
revisit the same square-degree area of sky on hundreds of nights. "A hundred
thousand very distant galaxies are detected even in the earliest UDS data,
and there is also a 'needle in a haystack' object -- a quasar at a redshift
just in excess of 6, meaning 12.7 billion light years from Earth," says
co-discoverer Ross McLure. "The light we now see from this object is very,
very old, having set off on its journey to the telescope only a billion
years after the big bang."
The first world release also contains large amounts of data on the Milky
Way, with millions of stars, young stars and other objects seen clearly
through the thick veils of dust which block the Milky Way to visible light,
as illustrated in the accompanying images. Phil Lucas, head of the Galactic
Plane Survey (GPS), notes that "in terms of detected objects, the GPS
dominates UKIDSS, with hundreds of millions of infrared stars in DR1 and
many times that still to come. And with the science archive now hosting a
large-scale image of the GPS so far, we're able to visualize the infrared
Milky Way better than ever before."
These results are among the motivations for carrying out surveys of the
infrared sky. Comprising five separate surveys, some of which are
highlighted here, UKIDSS has now scoured a larger volume of the Universe
than any previous sky survey, and only slightly less than the largest
visible light surveys. When the observations are completed in 2012, UKIDSS
will have probed some 70 times deeper on average than the previous largest
survey.
"The UKIDSS survey programme was expressly designed to capitalise on the
unique technical capabilities of the UKIRT Wide-Field Camera" said Gary
Davis, Director of the Joint Astronomy Centre in Hawaii, which operates the
UKIRT. WFCAM was developed at the UK Astronomy Technology Centre in
Edinburgh at a cost of 5M Sterling Pound, and it is now the world's leading
infrared panoramic camera. "It is rewarding to see the effort and dedication
of a large team of scientists and engineers over many years coming to
fruition. The release of DR1 presages the huge impact that UKIRT will make
on world astronomy over the next several years by probing deeper into the
infrared universe than ever before."
Images from the Wide Field Camera undergo processing at the Cambridge
Astronomical Survey Unit (CASU), Cambridge, UK, and the science products are
transferred to the WFCAM Science Archive operated by the Wide Field
Astronomy Unit in the Institute for Astronomy at the University of
Edinburgh. Astronomers from around the world will access the UKIDSS data
from the Science Archive, which is bracing for the influx of new users. A
small preliminary release, of about 1/4 the size of DR1, has been
scrutinized from all over the world since it was opened up in August 2007.
Nigel Hambly, the scientist responsible for operation of the Science
Archive, says that interest is likely to be intense. "Followup of objects
discovered in this data release within the ESO nations has already revealed
the power of the UKIDSS survey to turn up unique objects and we expect the
world community will want to quickly make the most of the data now becoming
available."
IMAGE CAPTION:
[http://outreach.jach.hawaii.edu/pressroom/2008_ukidss_dr1/ukidss_dr1_gc.png
(1.54 MB)
http://outreach.jach.hawaii.edu/pressroom/2008_ukidss_dr1/ukidss_dr1_gc.jpg
(1.01 MB)]
A globular cluster observed as part of the UKIDSS DR1 release. The image
shows a globular cluster in the constellation of Aquila, about 9,000 light
years from Earth.
Hilo, Hawaii
Contact:
Inge Heyer, Science Outreach Specialist
Tel: +1 808 969 6524 Fax: +1 808 961 6516
Images, notes, and contact details appear below.
EMBARGOED UNTIL 9AM (CST) JANUARY 9, 2008
Heat from the Heavens -- Opening up the Infrared Sky
The infrared sky is expanding significantly for the world astronomical
community with the first world release of data (DR1) from the UKIRT Infrared
Deep Sky Survey (UKIDSS).
UKIDSS DR1 has mapped a larger volume of the sky than any previous infrared
survey. As the UKIDSS project progresses, it will gradually become the
dominant source of information about the infrared sky, expanding its volume
by a factor of 15 beyond DR1.
For the past two years, the United Kingdom Infrared Telescope (UKIRT) in
Hawaii has been systematically scanning the heavens for five different
"colours" of faint infrared light. This allows astronomers to penetrate dark
clouds where stars are currently forming, and to locate stars much less
massive and much cooler than the Sun. Furthermore, our own Galaxy (the Milky
Way) is transparent to the infrared, making it possible to see all the way
to its centre and beyond. And finally, the expansion of the Universe
stretches visible light from the most distant (and youngest) galaxies and
quasars into the infrared part of the spectrum, and by observing this
infrared light we can trace the evolution of galaxies from their youngest
members. The first world release of these data makes all this information
available to researchers everywhere.
Andy Lawrence from the University of Edinburgh, the UKIDSS Principal
Investigator, said: "We are moving into new territory. This survey probes
huge volumes of space, so that we can locate rare but important objects like
the very coolest and least luminous stars and the most distant galaxies.
Astronomers in Europe have started getting the science out, but this world
release should really unleash the scientific potential of the dataset."
The present release, large though it is, however, is just the beginning.
Andy Adamson, Associate Director of UKIRT, says: "WFCAM has recently taken
its one millionth observation, and the UKIDSS survey is progressing
strongly. UKIDSS will have surveyed a volume 15 times larger than the
current release, DR1, by the time it is completed in 2012."
Results from this world-leading effort are released in two stages -- first
to the member nations of the European Southern Observatory (ESO), and 18
months later to the world astronomical community. The data now being
released worldwide were obtained in the first, intensive and exciting, WFCAM
observing periods on the UKIRT telescope, up to January 2006. There will be
new data releases approximately every six months over the coming five years.
Astronomers from the ESO nations have been busily following up on the early
UKIDSS data for the past year. The survey has proved itself a rich source of
exotic objects, exactly as expected. Steve Warren, the UKIDSS Survey
Scientist, highlights the discovery of the coolest known brown dwarf in the
Galaxy -- ULAS J0034 for short -- which, at an absolute temperature only
just over twice that of the Earth, is fully 100 degrees cooler than any
other known brown dwarf. This is likely one of the closest astronomical
objects outside the Solar System, and was discovered in the shallow UKIDSS
Large Area Survey (LAS).
UKIDSS is also expected to discover some of the most distant objects known,
and it appears to be well on the way to this goal. DR1 includes early data
from the Ultra-Deep Survey (UDS), which aims to study the evolution of
galaxies when the Universe was a fraction of its current age.
This project is extraordinarily ambitious, requiring the telescope to
revisit the same square-degree area of sky on hundreds of nights. "A hundred
thousand very distant galaxies are detected even in the earliest UDS data,
and there is also a 'needle in a haystack' object -- a quasar at a redshift
just in excess of 6, meaning 12.7 billion light years from Earth," says
co-discoverer Ross McLure. "The light we now see from this object is very,
very old, having set off on its journey to the telescope only a billion
years after the big bang."
The first world release also contains large amounts of data on the Milky
Way, with millions of stars, young stars and other objects seen clearly
through the thick veils of dust which block the Milky Way to visible light,
as illustrated in the accompanying images. Phil Lucas, head of the Galactic
Plane Survey (GPS), notes that "in terms of detected objects, the GPS
dominates UKIDSS, with hundreds of millions of infrared stars in DR1 and
many times that still to come. And with the science archive now hosting a
large-scale image of the GPS so far, we're able to visualize the infrared
Milky Way better than ever before."
These results are among the motivations for carrying out surveys of the
infrared sky. Comprising five separate surveys, some of which are
highlighted here, UKIDSS has now scoured a larger volume of the Universe
than any previous sky survey, and only slightly less than the largest
visible light surveys. When the observations are completed in 2012, UKIDSS
will have probed some 70 times deeper on average than the previous largest
survey.
"The UKIDSS survey programme was expressly designed to capitalise on the
unique technical capabilities of the UKIRT Wide-Field Camera" said Gary
Davis, Director of the Joint Astronomy Centre in Hawaii, which operates the
UKIRT. WFCAM was developed at the UK Astronomy Technology Centre in
Edinburgh at a cost of 5M Sterling Pound, and it is now the world's leading
infrared panoramic camera. "It is rewarding to see the effort and dedication
of a large team of scientists and engineers over many years coming to
fruition. The release of DR1 presages the huge impact that UKIRT will make
on world astronomy over the next several years by probing deeper into the
infrared universe than ever before."
Images from the Wide Field Camera undergo processing at the Cambridge
Astronomical Survey Unit (CASU), Cambridge, UK, and the science products are
transferred to the WFCAM Science Archive operated by the Wide Field
Astronomy Unit in the Institute for Astronomy at the University of
Edinburgh. Astronomers from around the world will access the UKIDSS data
from the Science Archive, which is bracing for the influx of new users. A
small preliminary release, of about 1/4 the size of DR1, has been
scrutinized from all over the world since it was opened up in August 2007.
Nigel Hambly, the scientist responsible for operation of the Science
Archive, says that interest is likely to be intense. "Followup of objects
discovered in this data release within the ESO nations has already revealed
the power of the UKIDSS survey to turn up unique objects and we expect the
world community will want to quickly make the most of the data now becoming
available."
IMAGE CAPTION:
[http://outreach.jach.hawaii.edu/pressroom/2008_ukidss_dr1/ukidss_dr1_gc.png
(1.54 MB)
http://outreach.jach.hawaii.edu/pressroom/2008_ukidss_dr1/ukidss_dr1_gc.jpg
(1.01 MB)]
A globular cluster observed as part of the UKIDSS DR1 release. The image
shows a globular cluster in the constellation of Aquila, about 9,000 light
years from Earth.