WEBVTT FILE 1 00:00:00.010 --> 00:00:04.010 [Music] Rachel Osten: When I got the 2 00:00:04.030 --> 00:00:08.050 news on April 23rd, earlier this year, 3 00:00:08.070 --> 00:00:12.060 that a flare had been detected by Swift and it 4 00:00:12.080 --> 00:00:16.080 was coming from a nearby flare star called 5 00:00:16.100 --> 00:00:20.120 DG CVn, I was initially very surprised. 6 00:00:20.140 --> 00:00:24.160 Swift doesn't normally detect flares 7 00:00:24.180 --> 00:00:28.180 from nearby flare stars, and DG CVn 8 00:00:28.200 --> 00:00:32.210 is a relatively unknown star. 9 00:00:32.230 --> 00:00:36.220 Narrator: There are a few things we know about DG CVn. It is an 10 00:00:36.240 --> 00:00:40.250 M-class star, also called a red dwarf, and is located only about 11 00:00:40.270 --> 00:00:44.310 60 light years away. Rachel: It's a dim little red star. it has 12 00:00:44.330 --> 00:00:48.330 a luminosity that's about one-thousandth the luminosity of the sun. 13 00:00:48.350 --> 00:00:52.360 It has a mass that's about one-third the mass of the sun, 14 00:00:52.380 --> 00:00:56.430 and a radius that's about one-third 15 00:00:56.450 --> 00:01:00.440 the radius of the sun. Narrator: The largest solar flare 16 00:01:00.460 --> 00:01:04.500 ever recorded happened on November 4th, 2003. 17 00:01:04.520 --> 00:01:08.580 It was so powerful that it overloaded the sensors measuring it, but 18 00:01:08.600 --> 00:01:12.600 later calculations put it at an an X45. 19 00:01:12.620 --> 00:01:16.620 Flares are classified according to their strength. The smallest ones are 20 00:01:16.640 --> 00:01:20.640 B-class, followed by C, M, and X, the largest. 21 00:01:20.660 --> 00:01:24.660 An X45 flare is a very powerful flare. 22 00:01:24.680 --> 00:01:28.670 DG CVn's flare, however, was much 23 00:01:28.690 --> 00:01:32.700 larger. Rachel: We can estimate 24 00:01:32.720 --> 00:01:36.730 how big the flare on DG CVn was with respect to 25 00:01:36.750 --> 00:01:40.800 the solar scale; it would have been an 26 00:01:40.820 --> 00:01:44.810 X100,000. So this is several orders of 27 00:01:44.830 --> 00:01:48.830 magnitude larger than the biggest solar flare we've ever seen. 28 00:01:48.850 --> 00:01:52.850 The flare that Swift triggered on from DG CVn 29 00:01:52.870 --> 00:01:56.890 was only the beginning of what turned out to be 30 00:01:56.910 --> 00:02:00.910 a fairly extended series of flares, 31 00:02:00.930 --> 00:02:04.950 a flare "event" if you will, that lasted 32 00:02:04.970 --> 00:02:09.010 almost 20 days. Steven Drake: This was a 33 00:02:09.030 --> 00:02:13.040 very different star than the sun, so we don't really have to worry about this happening 34 00:02:13.060 --> 00:02:17.050 in the present-day sun. The young sun, such large events may have 35 00:02:17.070 --> 00:02:21.060 occurred. In the present-day sun the activity levels are much 36 00:02:21.080 --> 00:02:25.110 lower. The fundamental reason that DG CVn is more active than the sun 37 00:02:25.130 --> 00:02:29.160 is it's a very young star--30 million years--it's rapidly rotating, 38 00:02:29.180 --> 00:02:33.170 young stars are born that way, and rapid rotation 39 00:02:33.190 --> 00:02:37.190 is one of the key ingredients which powers activity. The faster the rotation, 40 00:02:37.210 --> 00:02:41.330 the greater the activity. Narrator: While not a threat to us, 41 00:02:41.350 --> 00:02:45.350 the massive flares of red dwarf stars can help us better understand the flares produced 42 00:02:45.370 --> 00:02:49.380 by our own sun. They are also of interest because red dwarf stars 43 00:02:49.400 --> 00:02:53.430 a often orbited by planets. Some data suggest 44 00:02:53.450 --> 00:02:57.460 that 40 percent of red dwarfs have "super-Earth" type planets orbiting 45 00:02:57.480 --> 00:03:01.490 in a habitable zone, where liquid water is possible. 46 00:03:01.510 --> 00:03:05.520 If this is true, then they are good candidates for supporting life. 47 00:03:05.540 --> 00:03:09.570 However, the habitable zone around a cool, dim star like 48 00:03:09.590 --> 00:03:13.580 DG CVn is much closer to the star than the Earth is to the sun. 49 00:03:13.600 --> 00:03:17.600 Rachel: When planets are closer to their star, 50 00:03:17.620 --> 00:03:21.630 they're more susceptible to anything the star does. For instance, 51 00:03:21.650 --> 00:03:25.650 if the star flares, the planet is much closer to the 52 00:03:25.670 --> 00:03:29.660 star, and it can be hit by 53 00:03:29.680 --> 00:03:33.700 the radiation or the particles that get ejected 54 00:03:33.720 --> 00:03:37.700 from the star when this flare process happens. If you happened 55 00:03:37.720 --> 00:03:41.750 to be on a planet around an M dwarf, 56 00:03:41.770 --> 00:03:45.790 when one of these large flares went off, you'd be 57 00:03:45.810 --> 00:03:49.800 having a very bad day. [Beeping] 58 00:03:49.820 --> 00:03:53.840 [Beeping] 59 00:03:53.860 --> 00:04:01.388 [Beeping]