WEBVTT FILE 1 00:00:00.010 --> 00:00:04.010 [Music] 2 00:00:04.030 --> 00:00:08.050 [Music] 3 00:00:08.070 --> 00:00:12.070 [Music] 4 00:00:12.090 --> 00:00:16.110 [Music] 5 00:00:16.130 --> 00:00:20.190 Narrator: The large Magellanic Cloud is among the closest galaxies to our own Milky Way, 6 00:00:20.210 --> 00:00:24.210 offering astronomers a detailed look at what makes a galaxy tick. 7 00:00:24.230 --> 00:00:28.230 One of its most striking features is the Tarantula Nebula, 8 00:00:28.250 --> 00:00:32.320 a star-forming region than any in ours or other 9 00:00:32.340 --> 00:00:36.350 neighboring galaxies. This is the source of most of the gamma rays 10 00:00:36.370 --> 00:00:40.410 we see from the LMC. Astronomers had thought the emission was a byproduct of 11 00:00:40.430 --> 00:00:44.480 star formation, which includes short-lived massive stars whose explosions 12 00:00:44.500 --> 00:00:48.510 produce shockwaves that can accelerate particles. Interactions by these 13 00:00:48.530 --> 00:00:52.530 particles, called cosmic rays, can produce gamma rays, the highest-energy 14 00:00:52.550 --> 00:00:56.620 form of light. But a discovery by NASA's Fermi Gamma-ray 15 00:00:56.640 --> 00:01:00.640 Space Telescope has turned this thinking on its head. Most of the 16 00:01:00.660 --> 00:01:04.660 emission arises from a single gamma-ray pulsar--the first ever detected in 17 00:01:04.680 --> 00:01:08.710 another galaxy. Pulsar J0540-6919 18 00:01:08.730 --> 00:01:12.790 turns out to be the most luminous gamma-ray 19 00:01:12.810 --> 00:01:16.820 pulsar yet observed, beating the previous record holder, the famous Crab 20 00:01:16.840 --> 00:01:20.870 Neubula pulsar in the Milky Way by 20 times. 21 00:01:20.890 --> 00:01:24.940 Discovered in X-rays using NASA's Einstein satellite in 1984, 22 00:01:24.960 --> 00:01:28.950 J0540 looked like a twin of the Crab until Fermi's Large Area 23 00:01:28.970 --> 00:01:33.020 Telescope unveiled its gamma-ray power. While Fermi is the most 24 00:01:33.040 --> 00:01:37.100 sensitive gamma-ray telescope ever launched, its vision is not as sharp as 25 00:01:37.120 --> 00:01:41.120 telescopes using other wavelengths. In 1998, 26 00:01:41.140 --> 00:01:47.140 NASA's RXTE satellite detected X-ray pulses from J0537-6910, 27 00:01:47.160 --> 00:01:51.180 a pulsar located just 16 arcminutes from J0540, 28 00:01:51.200 --> 00:01:55.240 or about half the apparent width of the Moon. In the early years of Fermi's 29 00:01:55.260 --> 00:01:59.280 mission, the two pulsars were seen only as a single steady gamma-ray source. 30 00:01:59.300 --> 00:02:03.360 But the vision of Fermi's Large Area Telescope 31 00:02:03.380 --> 00:02:07.400 improves over time for two reasons. First, it collects more 32 00:02:07.420 --> 00:02:11.460 gamma rays, and each one adds to the story of cosmic sources. 33 00:02:11.480 --> 00:02:15.550 Second, Fermi scientists improve their knowledge of the instrument, allowing them to 34 00:02:15.570 --> 00:02:19.560 reanalyze existing data to tease out more detail. 35 00:02:19.580 --> 00:02:23.630 Thanks to new data, and a reprocessing of old, Fermi scientists 36 00:02:23.650 --> 00:02:27.720 were finally able to detect gamma-ray pulses from J0540, 37 00:02:27.740 --> 00:02:31.760 revealing its incredible luminosity. The object is responsible for 38 00:02:31.780 --> 00:02:35.820 perhaps 60 percent of the gamma rays from the Tarantula Nebula. 39 00:02:35.840 --> 00:02:39.910 The surprise that it's the pulsar, not the nebula, suggests astronomers need to 40 00:02:39.930 --> 00:02:43.910 revisit their understanding of how cosmic rays are produced and move through 41 00:02:43.930 --> 00:02:47.980 star-forming regions. And the best way to do that, of course, is to 42 00:02:48.000 --> 00:02:52.000 keep watching the sky. 43 00:02:52.020 --> 00:02:56.040 [Beeping] 44 00:02:56.060 --> 00:03:05.899 [Beeping]