WEBVTT FILE 1 00:00:00.000 --> 00:00:04.590 It’s August 1972 and Ian Richardson 2 00:00:04.590 --> 00:00:08.840 — a future NASA scientist -- is watching TV when the BBC announces: 3 00:00:08.840 --> 00:00:12.490 “The interference is caused by solar activity.” 4 00:00:12.490 --> 00:00:15.590 He didn’t know then, but the Sun had just erupted 5 00:00:15.590 --> 00:00:18.760 in one of the most powerful solar events ever recorded. 6 00:00:18.760 --> 00:00:22.170 There was no threat to humans because Earth’s magnetic field 7 00:00:22.170 --> 00:00:24.180 deflects much of the Sun’s radiation. 8 00:00:24.180 --> 00:00:28.070 But the explosions were so powerful that intense radiation 9 00:00:28.070 --> 00:00:31.620 disrupted TV signals and caused radio blackouts. 10 00:00:31.620 --> 00:00:35.050 So what if you were outside Earth’s magnetic field? 11 00:00:35.050 --> 00:00:40.500 On the Moon and beyond, astronauts face the risk of extreme radiation exposure. 12 00:00:40.500 --> 00:00:44.580 Luckily, the intense radiation in 1972 occurred right between 13 00:00:44.580 --> 00:00:49.340 Apollo 16 and 17 missions when no astronauts were in their path. 14 00:00:49.340 --> 00:00:53.090 As NASA plans missions to go back to the Moon and then on to Mars, 15 00:00:53.090 --> 00:00:56.910 predicting the Sun’s activity to protect astronauts from space radiation 16 00:00:56.910 --> 00:00:59.660 is one of our biggest priorities. 17 00:00:59.660 --> 00:01:02.480 One of the biggest unknown factors about going to space 18 00:01:02.480 --> 00:01:04.150 is the radiation hazard from the Sun. 19 00:01:04.150 --> 00:01:10.110 This is Ian today — studying the effects of the Sun, also known as the field of heliophysics. 20 00:01:10.110 --> 00:01:13.430 The Sun is always emitting radiation like the light we see. 21 00:01:13.430 --> 00:01:19.600 But solar energetic particles, like from the August 1972 events, can be far more harmful. 22 00:01:19.600 --> 00:01:25.290 To be able to forecast solar energetic particles, we need to know how the Sun energizes them. 23 00:01:25.290 --> 00:01:28.410 The Sun is made up of electrically charged particles called plasma. 24 00:01:28.410 --> 00:01:33.870 As this plasma moves, it builds up energy inside its massive magnetic field. 25 00:01:33.870 --> 00:01:37.800 This energy is usually released in two types of explosions. 26 00:01:37.800 --> 00:01:40.470 Flares are intense flashes of light. 27 00:01:40.470 --> 00:01:44.070 Coronal mass ejections are giant eruptions of solar material. 28 00:01:44.070 --> 00:01:49.830 These solar eruptions send shock waves across the solar system accelerating particles as they go. 29 00:01:49.830 --> 00:01:53.790 These are solar energetic particles, or SEPs. 30 00:01:53.790 --> 00:01:57.120 They consist mainly of protons and possess a lot of energy 31 00:01:57.120 --> 00:01:59.690 that can affect satellite measurements 32 00:01:59.690 --> 00:02:00.880 and humans. 33 00:02:00.880 --> 00:02:04.460 SEPs can bombard you with a lot of radiation in a short period of time. 34 00:02:04.460 --> 00:02:11.160 They can penetrate your skin, damage your DNA, and increase your chances of getting cancer and radiation sickness. 35 00:02:11.160 --> 00:02:14.480 But they don’t occur with every solar eruption. 36 00:02:14.480 --> 00:02:19.310 Only a small number of flares and coronal mass ejections create SEPs. 37 00:02:19.310 --> 00:02:23.390 So we’re trying to predict when SEPs form and how they travel through space. 38 00:02:23.390 --> 00:02:26.050 At NASA’s Goddard Space Flight Center, 39 00:02:26.050 --> 00:02:32.500 the Community Coordinated Modeling Center, or CCMC, is dedicated to testing prediction models. 40 00:02:32.500 --> 00:02:38.060 Working with global partners, they use data from NASA satellites at different vantage points 41 00:02:38.060 --> 00:02:41.250 and models to figure out how solar explosions behave 42 00:02:41.250 --> 00:02:44.530 including how shock waves energize SEPs. 43 00:02:44.530 --> 00:02:49.110 And as we get better at predicting, we get more time to prepare. 44 00:02:49.110 --> 00:02:53.630 Preparation for an SEP event -- of which you may know that is already coming 45 00:02:53.630 --> 00:02:55.510 and perhaps the magnitude as well -- 46 00:02:55.510 --> 00:02:58.490 the technique that you would want is to use 47 00:02:58.490 --> 00:03:01.980 is to put as much mass between you and the source. 48 00:03:01.980 --> 00:03:08.220 On the surface of the Moon or Mars, astronauts can go underground or build shelter with local materials. 49 00:03:08.220 --> 00:03:13.640 But in transit, astronauts can only be protected with what’s on the spacecraft. 50 00:03:13.640 --> 00:03:18.790 which means that you might have elements on a spacecraft that have multiple purposes. 51 00:03:18.790 --> 00:03:23.090 NASA’s space radiation specialists are testing different ways to do this. 52 00:03:23.090 --> 00:03:27.470 One strategy they tested on the Orion spacecraft involves crew members 53 00:03:27.470 --> 00:03:31.750 barricading themselves with as much mass as possible in the center of the spacecraft. 54 00:03:31.750 --> 00:03:36.330 Other possible techniques in development include vests that add mass 55 00:03:36.330 --> 00:03:40.620 and electrically-charged surfaces that deflect particles. 56 00:03:40.620 --> 00:03:48.200 In terms of radiation protection and radiation mitigation, the factor of time is extraordinarily important. 57 00:03:48.200 --> 00:03:53.200 The Sun has a natural 11-year cycle that transitions through low and high activity, 58 00:03:53.200 --> 00:03:56.790  which is indicated by the number of sunspots on the surface. 59 00:03:56.790 --> 00:04:03.530 More sunspots mean more eruptions resulting in a higher risk for SEPs. 60 00:04:03.530 --> 00:04:06.470 But during this increased solar activity, 61 00:04:06.470 --> 00:04:08.550 the Sun’s magnetic field strengthens, 62 00:04:08.550 --> 00:04:12.200 enhancing its shield against another important source of radiation -- 63 00:04:12.200 --> 00:04:15.040 galactic cosmic rays. 64 00:04:15.040 --> 00:04:18.570 These are charged particles traveling at nearly the speed of light 65 00:04:18.570 --> 00:04:22.050 that are thought to come from supernova explosions from within our galaxy 66 00:04:22.050 --> 00:04:24.840 and possibly further out in the universe.  67 00:04:24.840 --> 00:04:31.490 If solar energetic particles are intense, sporadic storms, then galactic cosmic rays are a constant drizzle. 68 00:04:31.490 --> 00:04:36.090 Galactic cosmic rays are more sparse, but also much more energetic. 69 00:04:36.090 --> 00:04:40.870 They include heavier elements that can penetrate through vast amounts of materials. 70 00:04:40.870 --> 00:04:44.390 Understanding the rate of galactic cosmic rays 71 00:04:44.390 --> 00:04:48.760 helps us determine how much time astronauts can spend in space safely.  72 00:04:48.760 --> 00:04:54.170 To date, humans have only been on the lunar surface for a cumulative total of about 12 days. 73 00:04:54.170 --> 00:04:57.600 A trip to Mars will take 6-10 months each way. 74 00:04:57.600 --> 00:05:03.280 That means even more radiation exposure, and so NASA is doing the work to prepare for that. 75 00:05:03.280 --> 00:05:07.470 The Moon is going to be a testbed for us in order to be to prepare for Mars. 76 00:05:07.470 --> 00:05:13.240 The more that we understand the impact and the duration of radiation on the Moon, 77 00:05:13.240 --> 00:05:20.780 the more we can extrapolate that to the length of time that we will be spending in transit and on the surface of Mars. 78 00:05:20.780 --> 00:05:31.477