Slashdot Mirror

← Back to Stories (view on slashdot.org)

Astronomer Discovers the Most Distant Stars Ever Observed From Earth

Posted by ScuttleMonkey on from the eagle-eye dept.

Cryolithic writes to tell us The Vancouver Sun is reporting that a University of B.C. astronomer recently used NASA's Hubble telescope to see a cluster of stars one billion light-years from Earth, the farthest stars ever observed from Earth. From the article: "That's interesting, he explains, because given that light travels at a finite speed -- 300,000 km a second -- the light emitted from the star cluster he and Kalirai saw was emitted one billion years ago. That means the cluster as it appeared to them two months ago was the way it looked one billion years ago. In other words, they were looking one billion years back in time."

4 of 291 comments (clear)

  1. Re:only 1 billion ly? by MindStalker · · Score: 4, Informative

    Yea the visible universe is some 46 billions light years. They are referring to detecting individual starts a billion light years away whereby normally you would only see a galaxy with non identifiable individuals stars at such a distance.

  2. A correction/explanation by minuteman · · Score: 5, Informative

    As an astronomy graduate student, I would like to offer a correction or an explanation of this statement:

    From the article:
    "That's because the older a star gets, the redder it gets, he says. Younger stars are bluer."

    Kinda true, but the point is something else. A young *cluster* of stars will look blue because brightest stars in a young cluster are blue, massive stars. These blue bright stars burn their fuel (Hydrogen) very fast and have short lives (~100 Million years). When blue bright stars go away, more numerous, but much fainter, red stars start to dominate the color of the cluster. Therefore, as the *cluster* gets older, it gets redder.

  3. Re:1 billion light years? by wanerious · · Score: 4, Informative

    For galaxies out to about 100 million light years, we can use a well-known relation between the pulsations of bright stars and their luminosities to get a pretty accurate distance. Beyond that, the simplest measure is the cosmological redshift of the light. If the redshift is, say, 10%, then we use the Hubble relation (speed / Hubble constant = distance), where (speed = redshift * speed of light) to get an estimate. We can then independently calibrate this with Type 1a supernovae, which all go off with roughly the same brightness. This is only really useful for smaller redshifts and distances, since asking for the distance of an object with a significant redshift is sort of ambiguous. Do you mean how far is it "now"? How far away was it when it emitted the radiation? But the above is the simplest answer to your question.

  4. Re:Looking back in time. by Abcd1234 · · Score: 4, Informative

    And you know what's really weird? If the Sun just winked out of existence right this minute, the Earth would continue in it's orbit for 8 minutes before flying off into space. Why? Because gravity also propagates at the speed of light.