1 00:00:06,715 --> 00:00:11,136 This is an ultraviolet image of the planet Saturn. 2 00:00:11,219 --> 00:00:13,221 Saturn looks a little different in the ultraviolet. 3 00:00:13,221 --> 00:00:16,057 You can still see the edges of the rings here. 4 00:00:16,057 --> 00:00:20,437 But the reason we use the ultraviolet with the Hubble Space Telescope 5 00:00:20,520 --> 00:00:23,398 is because of what you see in the poles here. 6 00:00:23,523 --> 00:00:26,276 Those are the aurorae of Saturn. 7 00:00:26,651 --> 00:00:29,738 They glow really beautifully in the ultraviolet. 8 00:00:29,738 --> 00:00:33,700 So the Hubble Space Telescope is one of the key tools 9 00:00:33,825 --> 00:00:37,078 that we have had to study these beautiful 10 00:00:37,078 --> 00:00:38,705 aurorae of Saturn. 11 00:00:40,290 --> 00:00:42,751 This is a sequence of ultraviolet images 12 00:00:42,751 --> 00:00:46,254 with the Hubble Space Telescope, and what you can see is how dynamic they are. 13 00:00:46,337 --> 00:00:47,630 They don't just sit there glowing. 14 00:00:47,630 --> 00:00:50,884 The glowing part is changing all the time. 15 00:00:53,303 --> 00:00:56,222 And it's changing because our sun is changing 16 00:00:56,222 --> 00:00:59,893 and our sun is spewing out particles all the time. 17 00:01:00,060 --> 00:01:05,065 And when these particles hit this planet, they get sucked into the magnetic field 18 00:01:05,065 --> 00:01:08,068 and then they get deposited at higher altitudes. 19 00:01:08,068 --> 00:01:12,989 So what you're seeing here is really a combination of Saturn changing, but also 20 00:01:12,989 --> 00:01:13,823 our sun. 21 00:01:17,160 --> 00:01:20,914 What’s particularly special about this Hubble image is 22 00:01:20,914 --> 00:01:25,668 it was taken at a time close to what we call the ring-plane crossing. 23 00:01:25,752 --> 00:01:29,172 So the rings are almost in a straight line relative to us. 24 00:01:29,172 --> 00:01:30,381 They almost disappear. 25 00:01:31,466 --> 00:01:36,054 Saturn takes 30 years to make a trip around the sun. 26 00:01:36,054 --> 00:01:39,974 So the Saturn year is 30 Earth years long. 27 00:01:39,974 --> 00:01:45,105 We only get this particular orientation twice in that 30 year orbit. 28 00:01:45,105 --> 00:01:48,191 So every 15 years we have an opportunity 29 00:01:48,233 --> 00:01:51,694 to see this sideways view of Saturn. 30 00:01:51,903 --> 00:01:53,905 Most of the time Saturn is tilted 31 00:01:53,905 --> 00:01:57,033 one way or the other relative to the sun and to us. 32 00:01:57,992 --> 00:02:00,995 And what's great about that is that it allows us to see 33 00:02:00,995 --> 00:02:05,708 both the northern and the southern pole together at the same time. 34 00:02:06,793 --> 00:02:10,213 By using the Hubble ultraviolet observations 35 00:02:10,380 --> 00:02:12,090 we can see the aurorae. 36 00:02:12,090 --> 00:02:13,341 That's the first thing. 37 00:02:13,341 --> 00:02:15,552 And we can actually see variations 38 00:02:15,552 --> 00:02:19,222 in the aurorae around what we call the auroral oval. 39 00:02:19,639 --> 00:02:23,893 And that allows us to track out the strength of the magnetic field, 40 00:02:23,893 --> 00:02:26,604 depending on how bright these aurorae are. 41 00:02:28,148 --> 00:02:31,901 One of the things you can tell from an image like this from Hubble 42 00:02:32,110 --> 00:02:36,739 is that the aurorae in the north and south are pretty comparable in brightness. 43 00:02:37,198 --> 00:02:39,951 And that means that the magnetic field strength here 44 00:02:39,951 --> 00:02:42,078 is pretty similar in these two poles.