Hubble’s view of faintest stars in ancient star cluster

These clusters formed early in the 13.7-thousand-million-year-old universe. The cluster observed by Hubble, called NGC 6397, is one of the closest globular star clusters to Earth.

Although astronomers have conducted similar observations since Hubble was launched, a team led by Harvey Richer of the University of British Columbia, Vancouver, is reporting that they have at last unequivocally reached the faintest stars. Richer’s team announced their findings on 17 August at the 2006 International Astronomical Union General Assembly in Prague, Czech Republic, and in the 18 August edition of the journal Science.

"We have run out of hydrogen-burning stars in this cluster. There are no fainter such stars waiting to be discovered,” said Richer. “We have discovered the lowest-mass stars capable of supporting stable nuclear reactions in this cluster. Any less massive ones faded early in the cluster’s history and by now are too faint to be observed."

Hubble’s Advanced Camera for Surveys completed a census of two distinct stellar populations in NGC 6397. Hubble surveyed the faintest red dwarf stars which fuse hydrogen in their cores like our Sun, and the dimmest white dwarfs, which are the burned-out relics of normal stars.

The light from these faint stars is as dim as the light produced by a birthday candle on the Moon seen from Earth. NGC 6397 is 8 500 light- years away from Earth. Analysing the burned-out remnants of stars that died long ago, Hubble showed that the dimmest white dwarfs have such low temperatures that they are undergoing a chemical change in their atmospheres which makes them appear bluer rather than redder as they cool down. This phenomenon had been predicted before, but never observed so far.

These white dwarfs are the relics of stars, up to eight times as massive as our Sun, which have exhausted the fuel capable of supporting nuclear reactions in their cores. Stars that were initially even more massive died as supernovae very early in the cluster’s life, leaving behind neutron stars, black holes, or no debris at all.

Astronomers have used white dwarfs in globular clusters as a measure of the Universe’s age. The Universe must be at least as old as the oldest stars. White dwarfs cool down at a predictable rate — the older the dwarf, the cooler it is, making it a perfect 'clock' that has been ticking for almost as long as the Universe has existed. Richer and his team are using the same age-dating technique to calculate the cluster’s age. NGC 6397 is currently estimated to be nearly 12 thousand million years old.

A globular cluster’s dimmest stars have eluded astronomers because their light is too feeble. Richer’s team used Hubble’s Advanced Camera to probe deep within the cluster for nearly five days to capture the faint stars. The camera’s resolution is so sharp that it is capable of isolating cluster stars in this crowded cluster field, enabling cluster members to be distinguished from foreground and background stars.

The cluster stars move together as the cluster orbits the Milky Way Galaxy, and Hubble was able to pinpoint which stars were moving with the cluster. The Hubble team used this technique together with archival Hubble images taken as much as a decade earlier to make sure they had a pure sample of cluster stars.  
 
Notes for editors
 
The Hubble Space Telescope is a project of international cooperation between NASA and ESA.

For more information

Harvey Richer, University of British Columbia, Vancouver, BC, Canada
E-mail: richer @ astro.ubc.ca

Lars Lindberg Christensen, Hubble/ESA, Garching, Germany
E-mail: lars @ eso.org

Donna Weaver, Space Telescope Science Institute, Baltimore, Md., USA
E-mail: dweaver @ stsci.edu