1 00:00:06,923 --> 00:00:07,924 This is an image of 2 00:00:07,924 --> 00:00:10,635 Eta Carinae taken with the Hubble Space Telescope. 3 00:00:10,927 --> 00:00:13,096 And there's a lot going on in this image. 4 00:00:13,847 --> 00:00:16,641 If you go down into the very center of this image, 5 00:00:16,641 --> 00:00:20,395 you can see this bright spot here that's actually two stars, much, 6 00:00:20,395 --> 00:00:24,190 much more massive than the sun that are in orbit around one another. 7 00:00:24,357 --> 00:00:28,403 So what you see here are these two lobes of material, 8 00:00:28,403 --> 00:00:33,908 and they are from a giant eruption that the star had about 200 years ago. 9 00:00:34,159 --> 00:00:37,328 And when these massive stars are near the end of their life, 10 00:00:37,328 --> 00:00:38,705 they become quite unstable. 11 00:00:38,705 --> 00:00:43,001 And there was this tremendous eruption that blew off about 20 times 12 00:00:43,001 --> 00:00:44,210 the mass of the sun. 13 00:00:46,546 --> 00:00:49,507 And there was a massive brightening of the star, became 14 00:00:49,507 --> 00:00:52,719 one of the brightest stars in the sky in the 1840s. 15 00:00:53,053 --> 00:00:55,889 And what we see here is the result of that 16 00:00:55,889 --> 00:00:58,558 massive eruption and these lobes of material 17 00:00:58,892 --> 00:01:02,604 that are slowly making their way out into interstellar space. 18 00:01:02,896 --> 00:01:06,816 Mariners at the time used it as a navigation aid, but this brightening 19 00:01:06,816 --> 00:01:10,779 only lasted a number of years and it since faded. 20 00:01:11,071 --> 00:01:13,990 But Eta Carinae is still a relatively bright star. 21 00:01:15,158 --> 00:01:17,285 The dust in this 22 00:01:17,285 --> 00:01:21,706 homunculus nebula, which is what it's called, is going to continue to expand. 23 00:01:21,915 --> 00:01:25,502 It's being illuminated by the stars that are interior to it. 24 00:01:27,712 --> 00:01:30,215 Here's another image of Eta Carinae taken with Hubble. 25 00:01:30,298 --> 00:01:31,716 It looks a little different. 26 00:01:31,716 --> 00:01:35,804 Hubble is outfitted with very specialized filters that can see 27 00:01:35,804 --> 00:01:40,016 the light emitted from specific atoms at specific wavelengths. 28 00:01:40,266 --> 00:01:44,270 The blue shows you where the magnesium is emitting light. 29 00:01:44,312 --> 00:01:48,233 The red shows regions where nitrogen is emitting light. 30 00:01:48,691 --> 00:01:50,860 They have different ionization states. 31 00:01:50,860 --> 00:01:53,738 They respond to this ultraviolet light in different ways. 32 00:01:54,489 --> 00:01:55,698 One of the things that happens 33 00:01:55,698 --> 00:01:59,619 in these massive stars is they're factories for heavier elements, 34 00:01:59,619 --> 00:02:03,540 and that's where the heavy elements in our bodies on the earth all come from. 35 00:02:03,873 --> 00:02:07,001 Stars like this supernova and massive stars 36 00:02:07,001 --> 00:02:10,213 that process them and eject the material back out into space. 37 00:02:10,213 --> 00:02:13,842 And that's sort of the hard work that astronomers want to do because we 38 00:02:13,842 --> 00:02:18,054 want to understand all the details of what's happening in this nebula. 39 00:02:18,096 --> 00:02:23,476 That's what these extraordinary eyes that Hubble has allow us to do. 40 00:02:24,519 --> 00:02:26,980 This is a very complex and volatile object. 41 00:02:26,980 --> 00:02:29,983 And in fact, one of the reasons for being interested 42 00:02:30,358 --> 00:02:34,445 is that on the list of stars that we know about in the Milky Way, 43 00:02:34,821 --> 00:02:37,782 that may soon become supernovae, this is one of them. 44 00:02:38,116 --> 00:02:42,662 It takes about 8000 years for the light from Eta Carinae to reach us. 45 00:02:42,662 --> 00:02:45,373 And so it could already have gone supernova 46 00:02:45,373 --> 00:02:47,792 8000 years ago and we wouldn't know it.