About the Image
Current observations suggest that the Universe is about 13.7 billion years old. We know that light takes time to travel, so that if we observe an object that is 13 billion light years away, then that light has been traveling towards us for 13 billion years. Essentially, we are seeing that object as it appeared 13 billion years ago.
With every year that passes, our newest technology enables us to see further and further back.
UDF, Credit: NASA, ESA, S. Beckwith (STScI) and the HUDF Team
The UDF looks back approximately 13 billion years (approximately between 400 and 800 million years after the Big Bang). Galaxies that existed in that time period would be very young and very different in structure and appearance than the grand spirals we see nearby today.
Image Credits: UDF - NASA/ESA/S. Beckwith(STScI) and The HUDF Team.
What is the Farthest Known Object From Earth?
In December of 2012, astronomers announced a Hubble Space Telescope discovery of seven primitive galaxies located over 13 billion light years away from us. The results are from survey of the same patch of sky known as the Ultra Deep Field (UDF). This survey, called UDF12, used Hubble's Wide Field Camera 3 to peer deeper into space in near-infrared light than any previous Hubble observation.
Why infrared? Because the Universe is expanding; therefore the farther back we look, the faster objects are moving away from us, which shifts their light towards the red. Redshift means that light that is emitted as ultraviolet or visible light is shifted more and more to redder wavelengths.
The extreme distance of these newly discovered galaxies means their light has been traveling to us for more than 13 billion years, from a time when the Universe was less than 4% of its current age.
Their discovery, which you can read more about in the NASA feature is exciting because it might give us an idea of how abundant galaxies were close to the era when astronomers think galaxies first started forming. (Phil Plait has a good column about this discovery too.)
Credit: NASA, ESA, R. Ellis (Caltech), and the UDF 2012 Team
As of this writing it seems that one of the galaxies in this recent Hubble discovery may be a distance record breaker - it was observed 380 million years after the Big Bang, with a redshift of 11.9. This means the light from this galaxy (pictured below) left 13.3+ billion light years ago.
Credit: NASA, ESA, R. Ellis (Caltech), and the UDF 2012 Team
Just under a month ago, the current candidate was this object: a young galaxy called MACS0647-JD. It's only a tiny fraction of the size of our Milky Way - and was observed at 420 million years after the Big Bang, when the universe was 3 percent of its present age of 13.7 billion years. To spot this galaxy, astronomers used the powerful gravity from the massive galaxy cluster MACS J0647+7015 to magnify the light from the distant galaxy; this effect is called gravitational lensing.
Credit: NASA, ESA, M. Postman and D. Coe (STScI), and the CLASH Team
Earlier in 2012, with the combined power of NASA's Spitzer and Hubble Space Telescopes, as well as the use of gravitational lensing, a team of astronomers spotted what might then have been the most distant galaxy ever seen. Light from this young galaxy, MACS1149-JD, was emitted when our 13.7-billion-year-old universe was just 500 million years old.
Credit: NASA, ESA, W. Zheng (JHU), M. Postman (STScI), and the CLASH Team
In 2010, a candidate for most distant galaxy was found in the Hubble Ultra Deep Field. UDFy-38135539 is thought to be 13.1 billion light years away. There is more information in this article on Phil Plait's blog. I've used his labeled images:
The objects in the Hubble Ultra Deep Field may well be the farthest known objects, but there are other contenders.
They include a galaxy called Abell 1835 IR1916, which was discovered in 2004, by astronomers from the European Southern Observatory using a near-infrared instrument on the Very Large Telescope. The object is visible to us because of gravitational lensing by the galaxy cluster Abell 1835, which is between this object and us. This galaxy is thought to be about 13.2 billion light years away, which means it would date to about 500 million years after the Big Bang. Note though, that this find has not been verified by other instruments - the Spitzer Space Telescope tried in 2006 without success.
Abell 1835 by the Hubble, Credit: NASA
Also in 2004, a team using both the Hubble Space Telescope and the Keck Observatory discovered a galaxy that is believed to be about 13 billion years away from us. It was found when observing the galaxy cluster Abell 2218. The light from the distant galaxy was visible because of gravitational lensing. The very distant object is the one circled. For more information, check out this press release.
Credit: European Space Agency, NASA, J.-P. Kneib (Observatoire Midi-Pyrénées) and R. Ellis (Caltech)
Then there's the infrared James Webb Space Telescope. If you recall, Hubble has near infrared capability, but not mid-infrared, and for objects with very high redshifts, to see these most distant of objects would require a powerful telescope with mid-infrared capability. JWST will be able to see farther and deeper than was ever possible before.
In fact, one of JWST objectives is to look even further back, to just 200 million years after the Big Bang. One model of galaxy evolution has the first galaxies forming then and we need JWST to test this theoretical prediction!
Top panels: Hubble UDF. Bottom: Simulation of what a JWST Deep Field might look like. Credit: STScI
(Note: JWST will be able to see these first galaxies without the aid of gravitational lensing; gravitational lensing might allow us to see them better, but would not necessarily let us see further back in time.)
Some of the most newly detected objects may be over 13 billion light years away, as derived from a standard model of the Universe. However, a powerful new generation of telescopes, like the James Webb Space Telescope, will be needed to confirm the suspected distances of these objects.
When 13 billion light years is translated into kilometers, there are a staggering number of zeros - it comes out to approximately 123,000,000,000,000,000,000,000 km.
As time progresses, so will our ability to see futher and further away - giving us insight on the very beginnings of the Universe's existence!
How do We Calculate Distances of This Magnitude?
For more information on Hubble's Law, please read the section on finding distances to the Nearest Superclusters.
Why Are These Distances Important To Astronomers?