1 00:00:00,000 --> 00:00:03,638 Astronomers using NASA’s Hubble Space Telescope 2 00:00:03,638 --> 00:00:06,763 have found a rare ultramassive white dwarf 3 00:00:06,763 --> 00:00:09,530 formed from merging stars. 4 00:00:09,530 --> 00:00:11,920 The discovery was made possible by Hubble’s  5 00:00:11,920 --> 00:00:14,229 sensitive ultraviolet observations 6 00:00:14,229 --> 00:00:16,542 and suggests these unusual white dwarfs 7 00:00:16,542 --> 00:00:19,411 may be more common than once thought. 8 00:00:19,411 --> 00:00:22,596 The white dwarf is 128 light-years away 9 00:00:22,596 --> 00:00:25,257 and 20 percent more massive than the Sun. 10 00:00:25,257 --> 00:00:28,320 In visible light it looked like a typical white dwarf, 11 00:00:28,320 --> 00:00:31,899 but Hubble’s ultraviolet data revealed something unusual: 12 00:00:31,899 --> 00:00:34,880 evidence of carbon in its atmosphere. 13 00:00:34,880 --> 00:00:37,816 A white dwarf is what stars like the Sun become 14 00:00:37,816 --> 00:00:40,399 after they exhaust their nuclear fuel. 15 00:00:40,399 --> 00:00:41,858 Near the end of its life, 16 00:00:41,858 --> 00:00:45,038 this type of star expels most  of its outer material, 17 00:00:45,038 --> 00:00:47,222 creating a planetary nebula, 18 00:00:47,222 --> 00:00:50,379 only the hot core of the star remains. 19 00:00:50,379 --> 00:00:53,360 White dwarfs that form from a single star usually 20 00:00:53,360 --> 00:00:56,583 have atmospheres made of hydrogen and helium. 21 00:00:56,583 --> 00:00:59,360 These thick layers cover its carbon and oxygen, 22 00:00:59,360 --> 00:01:01,620 or oxygen and neon surface, 23 00:01:01,620 --> 00:01:04,560 preventing their detection in the star’s spectrum. 24 00:01:04,560 --> 00:01:07,592 When carbon shows up in a white dwarf’s spectrum, 25 00:01:07,592 --> 00:01:10,000 it can point to a more violent origin, 26 00:01:10,000 --> 00:01:12,417 such as a collision between two white dwarfs 27 00:01:12,417 --> 00:01:15,520 or between a white dwarf and a subgiant star.  28 00:01:15,520 --> 00:01:17,314 These collisions can burn off 29 00:01:17,314 --> 00:01:19,315 most of the hydrogen and helium, 30 00:01:19,315 --> 00:01:21,520 leaving only a thin layer behind, 31 00:01:21,520 --> 00:01:23,838 allowing astronomers to detect carbon 32 00:01:23,838 --> 00:01:25,997 on the white dwarf’s surface. 33 00:01:25,997 --> 00:01:28,330 This white dwarf’s merger origin would be 34 00:01:28,330 --> 00:01:32,567 impossible to identify without Hubble’s  ultraviolet sensitivity. 35 00:01:32,567 --> 00:01:35,303 In hotter white dwarfs, spectral lines from 36 00:01:35,303 --> 00:01:38,223 elements heavier than  helium fade in visible light 37 00:01:38,223 --> 00:01:40,000 but stay bright in ultraviolet, 38 00:01:40,000 --> 00:01:42,227 where Hubble can detect them. 39 00:01:42,227 --> 00:01:44,800 Researchers discovered this white dwarf’s 40 00:01:44,800 --> 00:01:48,678 unusual origin by looking at its ultraviolet spectrum, 41 00:01:48,678 --> 00:01:50,720 suggesting that other white dwarfs 42 00:01:50,720 --> 00:01:52,932 with a typical visible light spectrum 43 00:01:52,932 --> 00:01:56,240 may also be the result of cosmic collisions. 44 00:01:56,240 --> 00:01:59,434 The team plans to explore this possibility further, 45 00:01:59,434 --> 00:02:01,680 and hopes to continue this research by 46 00:02:01,680 --> 00:02:04,116 studying how common carbon stars are 47 00:02:04,116 --> 00:02:05,928 among similar white dwarfs 48 00:02:05,928 --> 00:02:08,812 and how many stellar mergers might be hiding 49 00:02:08,812 --> 00:02:11,342 among the normal white dwarf family. 50 00:02:11,342 --> 00:02:14,160 This research will help improve our understanding of   51 00:02:14,160 --> 00:02:16,511 the environments in which stars evolve 52 00:02:16,511 --> 00:02:20,261 and the paths that lead to supernova explosions. 53 00:02:20,261 --> 00:02:31,418 Follow us on Social Media 54 00:02:31,418 --> 00:02:37,891 NASA Meatball!!!