WEBVTT FILE 1 00:00:00.300 --> 00:00:03.704 NASA’s Hubble Space Telescope has been watching a large, dark 2 00:00:03.704 --> 00:00:07.474 storm on the planet Neptune disappear before our very eyes – 3 00:00:07.474 --> 00:00:11.812 or, telescope mirror. The first and only spacecraft to visit 4 00:00:11.812 --> 00:00:17.518 Neptune was NASA’s Voyager 2 in 1989. It discovered two immense. 5 00:00:17.518 --> 00:00:20.187 dark storms churning through Neptune’s thick, blue 6 00:00:20.187 --> 00:00:24.124 atmosphere. Voyager 2 then headed out of the solar system, 7 00:00:24.124 --> 00:00:27.995 and since then our primary means of watching Neptune’s storms has 8 00:00:27.995 --> 00:00:32.466 been the Hubble Space Telescope. Our atmosphere on Earth makes it 9 00:00:32.466 --> 00:00:35.836 hard to look at blue light in high resolution, so Hubble is 10 00:00:35.836 --> 00:00:38.739 currently the only telescope that is able to see these 11 00:00:38.739 --> 00:00:43.076 storms. The larger of the two storms Voyager 2 discovered on 12 00:00:43.076 --> 00:00:46.113 Neptune was called the Great Dark Spot, because it looked 13 00:00:46.113 --> 00:00:49.049 very similar to the Great Red Spot on Jupiter. Jupiter’s Great 14 00:00:49.049 --> 00:00:52.619 Red Spot has existed for hundreds of years, but when 15 00:00:52.619 --> 00:00:56.857 Hubble looked at Neptune in 1994. the Great Dark Spot was 16 00:00:56.857 --> 00:01:00.027 already gone. Instead there was a new storm on the northern 17 00:01:00.027 --> 00:01:04.097 hemisphere, which was named the Northern Great Dark Spot. Since 18 00:01:04.097 --> 00:01:07.100 then, that spot has also disappeared, and now in total 19 00:01:07.100 --> 00:01:10.837 we’ve observed five different dark spots on Neptune. We can 20 00:01:10.837 --> 00:01:14.007 see that large storms on Neptune form and dissipate much more 21 00:01:14.007 --> 00:01:17.477 rapidly than storms on Jupiter, and there’s a lot of diversity 22 00:01:17.477 --> 00:01:20.247 in what Neptune’s storms look like and how they move. These 23 00:01:20.247 --> 00:01:23.951 dark vortices on Neptune present atmospheric scientists with an 24 00:01:23.951 --> 00:01:27.220 amazing opportunity to learn about how storms work on a 25 00:01:27.220 --> 00:01:30.324 different world. But because there is so much in the universe 26 00:01:30.324 --> 00:01:32.659 that Hubble looks at, the telescope had only been 27 00:01:32.659 --> 00:01:36.296 observing Neptune once every few years, which wasn’t frequent 28 00:01:36.296 --> 00:01:40.067 enough to watch the formation or demise of any one particular 29 00:01:40.067 --> 00:01:43.503 storm. Since 2014 however, Hubble has begun a project 30 00:01:43.503 --> 00:01:46.807 called the Outer Planet Atmospheres Legacy program, or 31 00:01:46.807 --> 00:01:50.744 OPAL, to gather global maps of our gas giant planets every year 32 00:01:50.744 --> 00:01:54.548 for the remainder of Hubble’s operation. Now for the first 33 00:01:54.548 --> 00:01:58.618 time, using data from OPAL and additional Hubble observations, 34 00:01:58.618 --> 00:02:02.255 Hubble has captured time-lapse images showing the gradual death 35 00:02:02.255 --> 00:02:06.093 of a storm on Neptune. The vortex pictured here is dredging 36 00:02:06.093 --> 00:02:09.329 up material from deep inside Neptune’s atmosphere, possibly 37 00:02:09.329 --> 00:02:13.166 such as hydrogen sulfide, which would make for a pretty smelly 38 00:02:13.166 --> 00:02:18.438 storm. In the first image from 2015. the storm is over 3000 39 00:02:18.438 --> 00:02:22.142 miles across – big enough to stretch across the entire 40 00:02:22.142 --> 00:02:25.612 Atlantic Ocean from Boston to Portugal. The storm is dark in 41 00:02:25.612 --> 00:02:28.382 blue wavelengths, but overshadowed at green and red 42 00:02:28.382 --> 00:02:32.285 wavelengths by nearby companion clouds. The contrast of the dark 43 00:02:32.285 --> 00:02:35.989 vortex faded quite a bit by late 2017. though the feature was 44 00:02:35.989 --> 00:02:40.360 still over 2000 miles wide. Seeing this storm unfold gives 45 00:02:40.360 --> 00:02:43.697 scientists a chance to test their models of how they 46 00:02:43.697 --> 00:02:47.067 predicted an anticyclone may interact with the wind jets on 47 00:02:47.067 --> 00:02:50.137 Neptune. This particular vortex is not behaving how some 48 00:02:50.137 --> 00:02:53.540 dynamical simulations predicted, which is great because that 49 00:02:53.540 --> 00:02:57.344 means there’s a lot left to learn on Neptune. The Hubble 50 00:02:57.344 --> 00:03:00.647 Space Telescope is up to that task of advancing scientists’ 51 00:03:00.647 --> 00:03:03.884 understanding of planetary atmospheres. 52 00:03:03.884 --> 00:00:00.000 www. nasa. gov/hubble @NASAHubble