Gravitational lensing in action

Loading player...

This video shows a phenomenon known as gravitational lensing, which is used by astronomers to study very distant and very faint galaxies.

Lensing clusters are clusters of elliptical galaxies whose gravity is so strong that they bend the light from the galaxies behind them. This produces distorted, and often multiple images of the background galaxy. But despite this distortion, gravitational lenses allow for greatly improved observations as the gravity bends the light’s path towards Hubble, amplifying the light and making otherwise invisible objects observable.

In this animation, a distant galaxy is shown first with very little of its light travelling towards Earth. However, if we add a galaxy cluster between the galaxy and Earth, we see how the path of the light is altered and the light seen from Earth is amplified.

Note that in order to clearly show the gravitational lens bending light, the scale has been greatly exaggerated in this animation. In reality, the distant galaxy is much further away and much smaller, which is why it only appears as small points of light in the final image.

A team of astronomers has used Abell 383, one such gravitational lens, to observe a distant galaxy whose light is resolved into two images by the cluster. The gravitational lensing effect means that they have been able to determine fascinating insights about the galaxy that would not normally be visible even with Hubble. Among their discoveries is that the distant galaxy’s stars are very old, meaning that galaxies probably formed earlier in cosmic history than we first thought.

Credit:

NASA, ESA & L. Calçada

About the Video

Id:heic1106a
Release date:12 April 2011, 15:00
Related releases:heic1106
Related announcements:ann1313
Duration:36s

About the Object

Name:Abell 383
Type:• X - Hubble Images Videos
• X - Cosmology Images/Videos
• X - HD Videos

HD

HD & Apple TV
14.5 MB
Full HD 1080p
30.3 MB

Large

Large QT
6.0 MB

Medium

Video Podcast
4.2 MB
Medium MPEG-1
15.2 MB
Medium Flash
5.5 MB

Small

Small Flash
2.4 MB
Small QT
1.3 MB

For Broadcasters

Broadcast SD
183.8 MB

Also see our