WEBVTT FILE 1 00:00:00.000 --> 00:00:04.295 ♪ NASA’s TESS and Spitzer missions just discovered a strange sight — 2 00:00:04.295 --> 00:00:10.093 maybe the first example of a giant world orbiting extremely close to a small, dead star. 3 00:00:10.093 --> 00:00:18.435 The object, called WD 1856 b, is roughly the same size as Jupiter, with possibly up to 14 times its mass. 4 00:00:18.435 --> 00:00:21.354 About every day and a half, it orbits a white dwarf, 5 00:00:21.354 --> 00:00:26.735 a star containing half the Sun’s mass in a space only slightly larger than Earth. 6 00:00:26.735 --> 00:00:33.408 TESS hunts for regular dips in starlight caused when planets pass in front of, or transit, their stars. 7 00:00:33.408 --> 00:00:39.164 TESS discovered WD 1856 b’s transits, which were then confirmed by Spitzer. 8 00:00:39.164 --> 00:00:42.751 Finding a potential planet so close to a white dwarf is surprising. 9 00:00:42.751 --> 00:00:47.881 Stars like WD 1856 often start out looking much like our Sun. 10 00:00:47.881 --> 00:00:53.136 But as they age, they transform into red giants, engulfing any nearby planets. 11 00:00:53.136 --> 00:00:57.932 Then their atmospheres blow away, revealing their dead white dwarf cores. 12 00:00:57.932 --> 00:01:03.646 So, WD 1856 b likely formed much farther away from its star. 13 00:01:03.646 --> 00:01:08.902 Scientists think there are several ways it may have moved inward, closer to where we find it today. 14 00:01:08.902 --> 00:01:13.364 Then the effects of the star’s gravity would have nudged it into its current orbit. 15 00:01:13.364 --> 00:01:17.202 For example, it’s possible the system had additional massive planets. 16 00:01:17.202 --> 00:01:20.038 As the star evolved and disrupted the planets’ orbits, 17 00:01:20.038 --> 00:01:25.001 their gravitational interactions could have kicked WD 1856 b closer inward. 18 00:01:25.001 --> 00:01:30.632 Although the possible planet orbits the white dwarf, there are two other small, distant stars in the system. 19 00:01:30.632 --> 00:01:35.136 Perhaps their combined gravitational influence could have altered its orbit over time. 20 00:01:35.136 --> 00:01:42.227 Or, perhaps a massive object from deep space, such as another star, could have thrown the entire system into disarray. 21 00:01:42.227 --> 00:01:47.440 No matter the cause, the system then settled into its current state over billions of years. 22 00:01:47.440 --> 00:01:53.696 Scientists think this finding could help us understand how other star systems, including our own, may evolve. 23 00:01:53.696 --> 00:01:59.619 In the meantime, though, TESS will continue its search for more potential worlds like WD 1856 b … 24 00:01:59.619 --> 00:02:02.455 … and possibly find even stranger ones. 25 00:02:02.455 --> 00:02:05.834 ♪ ON-SCREEN: EXPLORE SOLAR SYSTEM & BEYOND 26 00:02:05.834 --> 00:02:10.380 ON-SCREEN: NASA logo