WEBVTT FILE 1 00:00:00.030 --> 00:00:04.080 [Music] 2 00:00:04.100 --> 00:00:08.150 [Music] 3 00:00:08.170 --> 00:00:12.180 Narrator: About 4 00:00:12.200 --> 00:00:16.240 4.400 light-years away. in the constellation Sextans. 5 00:00:16.260 --> 00:00:20.270 there is an extraordinary binary system that pairs a rapidly spinning neutron 6 00:00:20.290 --> 00:00:24.290 star, or pulsar, with a star about one-fifth the mass of the 7 00:00:24.310 --> 00:00:28.360 sun. Thanks to its rapid rotation and intense magnetic field, 8 00:00:28.380 --> 00:00:32.430 the pulsar produces a strong radio signal, which is how astronomers first 9 00:00:32.450 --> 00:00:36.500 discovered it. Many similar binaries are known, what's strange 10 00:00:36.520 --> 00:00:40.520 about this one is that sometimes the radio beacon just disappears. 11 00:00:40.540 --> 00:00:44.560 Then the system lights up in X-rays and gamma rays. 12 00:00:44.580 --> 00:00:48.580 Here's what researchers think may be happening. The two 13 00:00:48.600 --> 00:00:52.600 stars orbit so closely that gas from the sun-like star overflows and 14 00:00:52.620 --> 00:00:56.630 a stream falls toward the pulsar. But the pulsar produces an outflow of its own, 15 00:00:56.650 --> 00:01:00.650 Its spin and magnetic field accelerate charged particles to near 16 00:01:00.670 --> 00:01:04.710 the speed of light, creating a high-energy wind. During the radio 17 00:01:04.730 --> 00:01:08.740 phase, this pulsar wind easily holds back the gas stream. 18 00:01:08.760 --> 00:01:12.770 Now and then, and for reasons as yet unknown, the companion's 19 00:01:12.790 --> 00:01:16.800 stream surges, pushing close enough to the pulsar that it collects into a disk. 20 00:01:16.820 --> 00:01:20.890 Once in the disk, the gas gradually spirals toward the neutron star. 21 00:01:20.910 --> 00:01:24.910 At an altitude of about 50 miles, the gas chokes off the pulsar 22 00:01:24.930 --> 00:01:29.000 wind, unleashing the full torrent of the companion's gas stream. 23 00:01:29.020 --> 00:01:33.030 Gas reaching closest to the neutron star becomes transformed into dual 24 00:01:33.050 --> 00:01:37.060 particle jets, which fire out of the disk in opposite directions at nearly light-speed. 25 00:01:37.080 --> 00:01:41.100 Gamma rays observed by NASA's Fermi satellite may arise along the edge 26 00:01:41.120 --> 00:01:45.120 of the jet, while enhanced X-ray emission observed by other spacecraft 27 00:01:45.140 --> 00:01:49.160 may come from shock waves rocking the inner accretion disk. 28 00:01:49.180 --> 00:01:53.190 Eventually, and for reasons not understood, the companion's flow ebbs. 29 00:01:53.210 --> 00:01:57.230 The pulsar wind again becomes dominant, choking off the flow and blowing 30 00:01:57.250 --> 00:02:01.270 away the accretion disk. The pulsar flips back to its radio-emitting 31 00:02:01.290 --> 00:02:05.310 mode. Astronomers think this system represents a rare 32 00:02:05.330 --> 00:02:09.350 glimpse of a relatively brief phase. Mass transfer from a companion can 33 00:02:09.370 --> 00:02:13.400 rejuvenate an old, slow pulsar, spinning it up to tens of thousands of rpm. 34 00:02:13.420 --> 00:02:17.450 We may be seeing a system where this phase is on the verge of ending. 35 00:02:17.470 --> 00:02:21.490 When it does, the pulsar's wind will erode what's left of its companion 36 00:02:21.510 --> 00:02:25.550 until only the pulsar remains. Although astronomers have 37 00:02:25.570 --> 00:02:29.600 studied the system in both low- and high-energy states, they haven't yet observed 38 00:02:29.620 --> 00:02:33.610 this transformation in progress. Now, they are watching 39 00:02:33.630 --> 00:02:37.660 closely, waiting to document the next dramatic change of this exceptional 40 00:02:37.680 --> 00:02:41.720 binary. [Beeping] 41 00:02:41.740 --> 00:02:45.770 [Beeping] 42 00:02:45.790 --> 00:02:53.220 [Beeping]