Like a photographer clicking random snapshots of a crowd of people, NASA's Hubble Space Telescope has taken a view of an eclectic mix of galaxies. In taking this picture, Hubble's Advanced Camera for Surveys was not looking at any particular target. The camera was taking a picture of a typical patch of sky, while Hubble's infrared camera was viewing a target in an adjacent galaxy-rich region.
The jumble of galaxies in this image, taken in September 2003, includes a yellow spiral whose arms have been stretched by a possible collision [lower right]; a young, blue galaxy [top] bursting with star birth; and several smaller, red galaxies.
But the most peculiar-looking galaxy of the bunch - the dramatic blue arc in the center of the photo - is actually an optical illusion. The blue arc is an image of a distant galaxy that has been smeared into the odd shape by a phenomenon called gravitational lensing. This "funhouse- mirror effect" occurs when light from a distant object is bent and stretched by the mass of an intervening object. In this case the gravitational lens, or intervening object, is a red elliptical galaxy nearly 6 billion light-years from Earth. The red color suggests that the galaxy contains older, cooler stars.
The distant object whose image is smeared into the long blue arc is about 10 billion light-years away. This ancient galaxy existed just a few billion years after the Big Bang, when the universe was about a quarter of its present age. The blue color indicates that the galaxy contains hot, young stars.
Gravitational lenses can be seen throughout the sky because the cosmos is crowded with galaxies. Light from distant galaxies, therefore, cannot always travel through space without another galaxy getting in the way. It is like walking through a crowded airport. In space, a faraway galaxy's light will travel through a galaxy that is in the way. But if the galaxy is massive enough, its gravity will bend and distort the light.
Long arcs, such as the one in this image, are commonly seen in large clusters of galaxies because of their huge concentrations of mass. But they are not as common in isolated galaxies such as this one. For the gravitational lens to occur, the galaxies must be almost perfectly aligned with each other.
Gravitational lenses yield important information about galaxies. They are a unique and extremely useful way of directly determining the amount of mass, including dark matter, in a galaxy. Galaxies are not just made up of stars, gas, and dust. An invisible form of matter, called dark matter, makes up most of a galaxy's mass. A study of this newly discovered system, dubbed J033238-275653, was published in the Astrophysical Journal Letters. This study, together with similar observations, may allow astronomers to make the first direct measurements of the masses of bright, nearby galaxies.
Credits
NASA, ESA, J. Blakeslee and H. Ford (Johns Hopkins University)| About The Object | |
|---|---|
| Object Name | J033238-275653 |
| Object Description | Gravitational Lens |
| R.A. Position | 03h 32m 37.99s |
| Dec. Position | -27° 56' 52.99" |
| Constellation | Fornax |
| Distance | The distance to the gravitational lens is roughly 6 billion light-years (1.8Gpc). The distance to the object being lensed is over 10 billion light-years (3Gpc). |
| Dimensions | This image is 53 arcseconds across. |
| About The Data | |
| Data Description | This image was created from HST parallel observations of the HUDF from proposal : R. Thompson (U. Arizona), R. Bouwens (UCSC), M. Dickinson (NOAO), D. Eisenstein and X. Fan (U. Arizona), M. Franx (U. Leiden), G. Illingworth (UCSC) , M. Rieke (U. Arizona), and A. Riess (STScI). The science team for this image release includes: J.P. Blakeslee (JHU), K.C. Zekser, and N. Benitez (JHU), M. Franx (STScI), R. L. White (JHU/STScI), H.C. Ford (JHU), R.J. Bouwens (Lick Obs./UCSC), L. Infante (U. Catolica de Chile), N.J. Cross (JHU), G.Hertling (U. Catolica de Chile), B.P. Holden and G.D. Illingworth (Lick Obs./UCSC), V. Motta (U. Catolica de Chile), F. Menanteau and G.R. Meurer (JHU), M. Postman (JHU/STScI), P. Rosati (ESO), and W. Zheng (JHU). |
| Instrument | HST>ACS/WFC |
| Exposure Dates | September 2003 |
| Filters | F435W (B), F606W (V), F775W (i), and F850LP (z) |
| About The Image | |
| Color Info | Blue: F435W (B) Green: F606W (V) Red: F775W (i) + F850LP (z) |
| Compass Image |  |
| About The Object | |
|---|---|
| Object Name | A name or catalog number that astronomers use to identify an astronomical object. |
| Object Description | The type of astronomical object. |
| R.A. Position | Right ascension – analogous to longitude – is one component of an object's position. |
| Dec. Position | Declination – analogous to latitude – is one component of an object's position. |
| Constellation | One of 88 recognized regions of the celestial sphere in which the object appears. |
| Distance | The physical distance from Earth to the astronomical object. Distances within our solar system are usually measured in Astronomical Units (AU). Distances between stars are usually measured in light-years. Interstellar distances can also be measured in parsecs. |
| Dimensions | The physical size of the object or the apparent angle it subtends on the sky. |
| About The Data | |
| Data Description |
|
| Instrument | The science instrument used to produce the data. |
| Exposure Dates | The date(s) that the telescope made its observations and the total exposure time. |
| Filters | The camera filters that were used in the science observations. |
| About The Image | |
| Image Credit | The primary individuals and institutions responsible for the content. |
| Publication Date | The date and time the release content became public. |
| Color Info | A brief description of the methods used to convert telescope data into the color image being presented. |
| Orientation | The rotation of the image on the sky with respect to the north pole of the celestial sphere. |
