WEBVTT FILE 1 00:00:00.020 --> 00:00:02.050 [music] Coming soon to the 2 00:00:02.050 --> 00:00:04.110 International Space Station, 3 00:00:04.110 --> 00:00:06.140 a multipurpose mission leveraging 4 00:00:06.140 --> 00:00:08.180 X-ray technology to uncover 5 00:00:08.180 --> 00:00:10.210 mysteries of the universe. 6 00:00:10.210 --> 00:00:12.230 It's 7 00:00:12.230 --> 00:00:14.280 nearly impossible to measure the 8 00:00:14.280 --> 00:00:16.330 sizes of neutron stars directly. 9 00:00:16.330 --> 00:00:18.390 They're only about the size of a city 10 00:00:18.390 --> 00:00:20.410 and very far away. 11 00:00:20.410 --> 00:00:22.450 They're very interesting in the sky to 12 00:00:22.450 --> 00:00:24.470 to study. 13 00:00:24.470 --> 00:00:26.500 It's matter at the cusp of 14 00:00:26.500 --> 00:00:28.530 becoming a black hole. 15 00:00:28.530 --> 00:00:30.540 NICER's 56 telescopes will 16 00:00:30.540 --> 00:00:32.580 make observations, enabling scientists 17 00:00:32.580 --> 00:00:34.610 to determine how rotating neutron 18 00:00:34.610 --> 00:00:36.630 stars - also called 19 00:00:36.630 --> 00:00:38.650 pulsars - are put together. 20 00:00:38.650 --> 00:00:40.690 What we're really interested in doing with NICER 21 00:00:40.690 --> 00:00:42.710 is understanding - um - 22 00:00:42.710 --> 00:00:44.750 really what the size of a neutron 23 00:00:44.750 --> 00:00:46.780 star is. Cause once we know the size of the 24 00:00:46.780 --> 00:00:48.800 radius of a neutron star very precisely, 25 00:00:48.800 --> 00:00:50.840 then we can put constraints on 26 00:00:50.840 --> 00:00:52.870 the density at the core. 27 00:00:52.870 --> 00:00:54.920 And once you have an idea of what the density is 28 00:00:54.920 --> 00:00:56.950 at the core you can constrain nuclear theories that 29 00:00:56.950 --> 00:00:58.970 describe how the particles at 30 00:00:58.970 --> 00:01:01.020 the core of neutron stars interact with each other. 31 00:01:01.020 --> 00:01:03.060 In addition to 32 00:01:03.060 --> 00:01:05.090 probing neutron stars, the 33 00:01:05.090 --> 00:01:07.130 two-in-one mission will advance GPS like 34 00:01:07.130 --> 00:01:09.160 navigation of spacecraft 35 00:01:09.160 --> 00:01:11.200 throughout the solar system and beyond. 36 00:01:11.200 --> 00:01:13.250 The embedded Station 37 00:01:13.250 --> 00:01:15.280 Explorer for X-ray Timing and 38 00:01:15.280 --> 00:01:17.330 Navigation Technology, or SEXTANT, 39 00:01:17.330 --> 00:01:19.400 uses NICER's observations 40 00:01:19.400 --> 00:01:21.410 of pulsars to demonstrate this 41 00:01:21.410 --> 00:01:23.440 potentially game-changing technology. 42 00:01:23.440 --> 00:01:25.460 It's goal as a technology demonstration 43 00:01:25.460 --> 00:01:27.490 as part of the NICER mission, 44 00:01:27.490 --> 00:01:29.520 is to try to turn the "G" in GPS 45 00:01:29.520 --> 00:01:31.570 into "Galactic." 46 00:01:31.570 --> 00:01:33.610 We want to use pulsars - this particular 47 00:01:33.610 --> 00:01:35.660 type of neutron star that spins 48 00:01:35.660 --> 00:01:37.700 hundreds of times a second that emits this 49 00:01:37.700 --> 00:01:39.720 atomic-like clock signal for us 50 00:01:39.720 --> 00:01:41.750 to receive. And so we observe 51 00:01:41.750 --> 00:01:43.780 multiple pulsars and stitch together a solution 52 00:01:43.780 --> 00:01:45.810 by looking at those precision timing 53 00:01:45.810 --> 00:01:47.850 signals from those pulsars to construct a 54 00:01:47.850 --> 00:01:49.900 spacecraft orbit determination solution. 55 00:01:49.900 --> 00:01:51.920 Both NICER and SEXTANT 56 00:01:51.920 --> 00:01:53.970 benefit existing and future NASA 57 00:01:53.970 --> 00:01:56.000 missions and will further 58 00:01:56.000 --> 00:01:58.060 expand humankind's understanding and 59 00:01:58.060 --> 00:02:02.130 exploration of the universe. 60 00:02:02.130 --> 00:02:05.933 nasa.gov/nicer