WEBVTT FILE 1 00:00:00.634 --> 00:00:03.470 For the first time ever, astronomers might have witnessed 2 00:00:03.470 --> 00:00:07.908 a star actually become a black hole right before our eyes... or 3 00:00:07.908 --> 00:00:11.078 telescopes. In this visible light image from the Hubble 4 00:00:11.078 --> 00:00:14.882 Space Telescope, we can see a large star about 25 times the 5 00:00:14.882 --> 00:00:18.151 mass of our Sun around 22 million light years away in the 6 00:00:18.151 --> 00:00:24.424 galaxy NGC 6946. This was in 2007. But in a Hubble image from 7 00:00:24.424 --> 00:00:27.961 2015. looking with the same filters at the same wavelengths, 8 00:00:27.961 --> 00:00:33.233 the star appears to be gone. One possible explanation - the star 9 00:00:33.233 --> 00:00:38.071 died and became a black hole. But it gets weirder. The most 10 00:00:38.071 --> 00:00:40.540 prevalent theory for how a black hole forms is through a 11 00:00:40.540 --> 00:00:44.278 supernova - if a star is big enough, at the end of its life 12 00:00:44.278 --> 00:00:47.381 it will eject its outer layers at high velocity in a massive 13 00:00:47.381 --> 00:00:50.851 explosion while the inner core collapses into a very tiny 14 00:00:50.851 --> 00:00:54.454 space, creating a gravity well so great that light can’t 15 00:00:54.454 --> 00:00:58.992 escape. Literally, a black hole. So did we see this star go 16 00:00:58.992 --> 00:01:02.996 supernova? No, not really. A team of astronomers was 17 00:01:02.996 --> 00:01:05.499 monitoring this star with the Large Binocular Telescope in 18 00:01:05.499 --> 00:01:10.037 Arizona and saw the star get brighter in 2009, but not nearly 19 00:01:10.037 --> 00:01:14.574 as bright as a supernova. They call it a failed supernova. The 20 00:01:14.574 --> 00:01:18.245 star does expel its outer-most layer, but relatively gently and 21 00:01:18.245 --> 00:01:22.115 not in a big explosion. Ok, so this star got brighter in 22 00:01:22.115 --> 00:01:26.420 visible light in 2009, and then disappeared in visible light. 23 00:01:26.420 --> 00:01:29.022 How do we know it’s not just hidden behind a cloud of dust or 24 00:01:29.022 --> 00:01:32.859 something? The team checked for that; they looked at infrared 25 00:01:32.859 --> 00:01:35.862 observations from the Spitzer Space Telescope, which would be 26 00:01:35.862 --> 00:01:39.733 able to see the heat of dust warmed by the star. What we see 27 00:01:39.733 --> 00:01:42.869 with Spitzer is there is some emission in the mid-infrared, 28 00:01:42.869 --> 00:01:46.540 but it’s fading and fainter than what you’d expect to see with a 29 00:01:46.540 --> 00:01:49.476 hidden star. The team thinks instead that this infrared light 30 00:01:49.476 --> 00:01:52.813 is from the heat of gas falling back onto the newly formed black 31 00:01:52.813 --> 00:01:56.850 hole. To help confirm that this star is now a black hole, the 32 00:01:56.850 --> 00:01:59.519 team plans to analyze observations taken with the 33 00:01:59.519 --> 00:02:03.390 Chandra X-Ray Observatory, which would be able to reveal X-rays 34 00:02:03.390 --> 00:02:06.860 being emitted by the gas falling into the black hole. The team 35 00:02:06.860 --> 00:02:09.529 also wants to continue monitoring the star’s location 36 00:02:09.529 --> 00:02:13.667 in visible light with Hubble, in case the star is still there and re-appears, and 37 00:02:13.667 --> 00:02:15.936 they’ll want to look at the location with the upcoming James 38 00:02:15.936 --> 00:02:19.006 Webb Space Telescope to check if there’s a surviving star hidden 39 00:02:19.006 --> 00:02:22.576 by cooler dust than can be observed with Spitzer. So if 40 00:02:22.576 --> 00:02:25.645 this really is a black hole birth, what does that mean for 41 00:02:25.645 --> 00:02:29.416 astronomy? First of all, this would show that a star doesn’t 42 00:02:29.416 --> 00:02:33.353 need to go supernova to form a black hole. Astronomers actually 43 00:02:33.353 --> 00:02:36.390 haven’t seen as many supernovas occur with the largest stars as 44 00:02:36.390 --> 00:02:39.559 they would expect to see, and they’ve been wondering why this 45 00:02:39.559 --> 00:02:44.264 is. Perhaps 10 to 30 percent of massive stars don’t go supernova 46 00:02:44.264 --> 00:02:47.801 and are still able to simply form a black hole. If future 47 00:02:47.801 --> 00:02:50.937 observations confirm this team’s findings, this would be the 48 00:02:50.937 --> 00:02:54.441 first birth of a black hole ever witnessed and the first failed 49 00:02:54.441 --> 00:02:57.344 supernova ever discovered, both of which would usher in an 50 00:02:57.344 --> 00:03:00.814 exciting era of astronomy research. 51 00:03:00.814 --> 00:03:07.087 www.nasa.gov/hubble @NASAHubble