Forwarded from sci.astro, courtesy of Andrew Yee Approved: JOINT ASTRONOMY CENTRE PRESS NOTICE FOR IMMEDIATE RELEASE Date: 10 April 2002 Issued by: Douglas Pierce-Price (Joint Astronomy Centre) Email: d.pierce-price@jach.hawaii.edu Website: http://www.jach.hawaii.edu Tel: +44 (0)117 954 5913 (until 12th April 2002) +1 808 969 6524 (after 12th April 2002) Fax: +1 808 961 6516 (after 12th April 2002) FULL CONTACT DETAILS AND INFORMATION ON ILLUSTRATIONS AT THE END ---------------------------------------------------------------- ASTRONOMERS DETECT STELLAR ASHES AT THE DAWN OF TIME Using a powerful instrument on a telescope in Hawaii, UK astronomers have found ashes from a generation of stars that died over 10 billion years ago. This is the first time that the tell-tale cosmic dust has been detected at such an early stage in the evolution of the universe. Dr. Kate Isaak of Cambridge University will be announcing these exciting new results at the National Astronomy Meeting in Bristol on 11th April 2002. Using the SCUBA (Submillimetre Common-User Bolometer Array) camera on the James Clerk Maxwell Telescope in Hawaii, the team of British astronomers observed a sample of the most distant quasars known, to detect their primeval 'host' galaxies. The submillimetre wavelength radiation detected by SCUBA comes from large amounts of cool dust, a substance formed in supernovae and/or the atmospheres of old stars. Team leader Dr. Robert Priddey (Imperial College) said "These quasars are the most distant submillimetre sources known. We're looking more than nine-tenths of the way back to the birth of the universe in the Big Bang." The quasars are extremely far from us, as measured by their very high redshifts of 5-6. These huge distances mean that their light was emitted when the universe was less than a tenth of its current age -- a mere billion years after the Big Bang. Consequently, the host galaxies are caught when they are extremely young, and when astronomers might expect to see a burst of star formation. Dr. Priddey explained "It's amazing enough that these quasars, powered by billion solar mass black holes, should already exist only a billion years after the Big Bang. That these quasars also appear to contain so much dust yields important clues to the formation of massive galaxies in the youthful cosmos." Although it is not yet known whether the dust in these quasars is heated by hot, young stars within the galaxy, or directly by the quasar itself, the very existence of the dust and its constituent elements such as silicon and carbon implies that a large mass of stars have already been born, grown old and expired, within only a billion years of the Big Bang. Dr. Isaak said "These observations of very distant quasars are part of a programme looking at the submillimetre emission of quasars from low to high redshift. If we hunt for ever higher redshift quasars, we might catch the epoch at which the first dust forms." Team member Dr. Richard McMahon (University of Cambridge) added "The stars that made the carbon and silicon in these quasars are probably like the stars that made the carbon in our own bodies. It is very exciting to be able to learn when the chemical elements in our bodies were made. These quasars seem to be forming stars at a rate of around 1000 stars like the Sun per year." Notes for editors: An image of the James Clerk Maxwell Telescope in Hawaii is available at http://www.jach.hawaii.edu/~douglas/quasars/ Quasars are incredibly bright and distant objects, thought to be examples of Active Galaxies, which shine hundreds of times brighter than normal galaxies like our own. They are powered by gas in the galactic core falling into a 'supermassive' black hole which can be as much as one billion times as massive as our own Sun. For a brief period, the compact nucleus shine brighter than all the stars in the galaxy. SCUBA (the Submillimetre Common-User Bolometer Array) is currently the world's most powerful "submillimetre-wave" camera. It has revolutionised our knowledge of many areas of astronomy. The instrument contains highly sensitive detectors called bolometers, which are cooled to 0.06 degrees above absolute zero (-273 degrees Centigrade) to make them super-sensitive to the incoming submillimetre waves. It has been in operation on the James Clerk Maxwell Telescope (JCMT) in Hawaii for about five years. The host galaxies detected by SCUBA contain dust with a mass about 100 million times that of our Sun. The black holes in their cores are at least one billion times as massive as our Sun, and are swallowing about 10-100 solar masses of material per year. 'Redshift' measures the factor by which the light we observe from distant sources has been stretched, as the Universe expands during the course of its journey. The higher the redshift, the further away the source. The most distant of the quasars has a redshift of six, meaning that it emitted the light we detect when the radius of the Universe was one seventh of its current value. At this time, the universe was about a billion years old, compared to its current age of over 10 billion years. Contact details: Dr. Robert Priddey Astrophysics Group Blackett Laboratory Imperial College London SW7 2BW, UK Email: r.priddey@ic.ac.uk Tel: +44 (0)20 7594 7543 Fax: +44 (0)20 7594 7541 Dr. Kate Isaak Astrophysics Group Cavendish Laboratory Madingley Road Cambridge CB3 0HE, UK Email: isaak@mrao.cam.ac.uk Tel: +44 (0)1223 339242 Fax: +44 (0)1223 354599 Dr. Richard McMahon Institute of Astronomy University of Cambridge Madingley Road Cambridge CB3 OHA, UK Email: rgm@ast.cam.ac.uk Tel: +44 (0)1223 337548/19 Mobile: 07885 409019 Fax: +44 (0)1223 337523 Douglas Pierce-Price Joint Astronomy Centre 660 North A`ohoku Place Hilo, Hawaii 96720, USA Email: d.pierce-price@jach.hawaii.edu Website: http://www.jach.hawaii.edu Tel: +44 (0)117 954 5913 (until 12th April 2002) +1 808 969 6524 (after 12th April 2002) Fax: +1 808 961 6516 (after 12th April 2002) IMAGE CAPTION: [http://www.jach.hawaii.edu/~douglas/quasars/jcmt.jpg (105KB)] The James Clerk Maxwell Telescope in Hawaii, which observed the quasars. Photograph by Robin Phillips of JAC.
Hmm, I seem to have heard this before, is this the same cloud as this one that I heard about from hubble last year or something different? Which one is further back in time? <A HREF="http://hubble.stsci.edu/news_.and._views/pr.cgi.2002+02" target=new><FONT COLOR=Lime size=+1> deepest views of the cosmos </FONT></A>
My will was overcome by a random quantum fluctuation for an instant. These happen to me only every nine years or so.
THE 2ND GENESIS… For 100 million years after the birth of the universe, space was dark and mostly formless. That’s 100 million years. No stars. It was not interesting in the least. It was mostly hydrogen and helium, with faint traces of lithium and beryllium. It was an abysmally black “void”; darkness was upon the face of the deep. Who would have bet on this dark horse running through a 100 million year night? Then hydrogen caught fire and so the stars were born. In these blast furnaces, atomic nuclei were crushed, burned, and transmuted into more complex elements. That was the second creation, the one that really mattered. We contain those elements. Parts of those stars are in our blood, bones, and skin. We are those stars.