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These are the user uploaded subtitles that are being translated: 1 00:00:04,100 --> 00:00:06,934 - [Narrator] The search for planets beyond our solar system 2 00:00:06,934 --> 00:00:11,000 has brought a discovery of historic significance: 3 00:00:12,433 --> 00:00:15,367 a planet slightly larger than Earth 4 00:00:15,367 --> 00:00:19,533 orbiting a red dwarf star called Proxima Centauri. 5 00:00:21,367 --> 00:00:25,700 At just over 40 trillion kilometers from the sun, 6 00:00:25,700 --> 00:00:29,767 Proxima Centauri is our closest stellar neighbor. 7 00:00:33,800 --> 00:00:37,867 In the coming years, astronomers will probe its dim light 8 00:00:37,867 --> 00:00:41,600 to understand the tiny world that circles it. 9 00:00:44,834 --> 00:00:47,600 Does this planet have a climate, 10 00:00:47,600 --> 00:00:49,667 flowing water, even life? 11 00:00:54,900 --> 00:00:58,166 What will it take to get a closer look, 12 00:00:58,166 --> 00:01:01,633 to launch our first interstellar journey 13 00:01:01,633 --> 00:01:03,300 to the pale red dot? 14 00:01:25,500 --> 00:01:28,734 (light dramatic music) 15 00:01:36,200 --> 00:01:39,333 On a clear night, far from city lights, 16 00:01:39,333 --> 00:01:42,834 you can see around 4,500 individual stars. 17 00:01:49,266 --> 00:01:52,233 These bright stars are spread throughout our region 18 00:01:52,233 --> 00:01:54,233 of the galaxy to distances 19 00:01:54,233 --> 00:01:58,066 many thousands of light years away from Earth. 20 00:02:02,133 --> 00:02:06,066 134 of them lie within 50 light years of Earth, 21 00:02:07,266 --> 00:02:10,166 within the neighborhood of our sun. 22 00:02:11,800 --> 00:02:13,967 Nestled among those bright stars 23 00:02:13,967 --> 00:02:16,700 are some 2,000 others that are so dim, 24 00:02:16,700 --> 00:02:20,533 you need a high-powered telescope to see them. 25 00:02:24,500 --> 00:02:28,066 They all sit within the local bubble, 26 00:02:28,066 --> 00:02:32,233 a region probably cleared of gas by an ancient supernova. 27 00:02:38,166 --> 00:02:40,133 Our little corner of this bubble 28 00:02:40,133 --> 00:02:43,900 is occupied by a handful of well-known stars. 29 00:02:45,600 --> 00:02:49,767 They include 61 Cygmi, 11.4 light years from the sun, 30 00:02:53,567 --> 00:02:56,834 Epsilon Eridani, 10.5 light years away, 31 00:03:00,200 --> 00:03:04,033 Sirius, the dog star, at 8.6 light years away, 32 00:03:06,033 --> 00:03:09,767 then there's our nearest neighbor, the triple star system 33 00:03:09,767 --> 00:03:12,867 Alpha Centauri, 4.4 light years away. 34 00:03:14,667 --> 00:03:18,834 Alpha Centauri A and B are a pair of sun-like stars. 35 00:03:21,333 --> 00:03:25,567 Proxima Centauri is gravitationally bound to this pair. 36 00:03:25,567 --> 00:03:29,700 At 4.2 light years away, this red dwarf star 37 00:03:29,700 --> 00:03:32,300 is the closest star to our sun. 38 00:03:34,767 --> 00:03:36,800 Astronomers have been carefully monitoring 39 00:03:36,800 --> 00:03:41,001 the Alpha Centauri system as part of an intensive campaign 40 00:03:41,001 --> 00:03:44,500 to find planets in the solar neighborhood. 41 00:03:45,433 --> 00:03:48,633 The study began at the European Southern Observatory 42 00:03:48,633 --> 00:03:51,867 in the mountains of Chile in 1996, 43 00:03:51,867 --> 00:03:53,166 when astronomers began looking 44 00:03:53,166 --> 00:03:57,233 for a slight change in the color of nearby stars. 45 00:03:58,367 --> 00:04:01,333 Called a doppler shift, it's similar to the way 46 00:04:01,333 --> 00:04:04,467 the sound of a train whistle distorts as it races past us. 47 00:04:04,467 --> 00:04:07,800 (train whistle blowing) 48 00:04:14,300 --> 00:04:15,700 The same effect can be seen 49 00:04:15,700 --> 00:04:18,300 in the wavelength of a star's light 50 00:04:18,300 --> 00:04:22,467 if a planet tugs it slightly toward or away from us. 51 00:04:25,600 --> 00:04:28,433 This wobbling motion causes the star's light 52 00:04:28,433 --> 00:04:32,333 to stretch towards the blue part of the spectrum, 53 00:04:32,333 --> 00:04:33,433 then the red. 54 00:04:34,367 --> 00:04:36,400 The instruments that measure this wobble 55 00:04:36,400 --> 00:04:39,266 are so sensitive that they can detect a star's movement 56 00:04:39,266 --> 00:04:43,166 down to speeds of just a few meters per second. 57 00:04:44,033 --> 00:04:47,133 (light dramatic music) 58 00:04:47,133 --> 00:04:50,600 The search seemed to bear fruit in 2012, 59 00:04:50,600 --> 00:04:53,300 when astronomers reported tantalizing hints 60 00:04:53,300 --> 00:04:57,467 of an Earth-sized planet circling Alpha Centauri B. 61 00:05:01,734 --> 00:05:03,233 Excitement spread. 62 00:05:06,266 --> 00:05:08,934 Unfortunately, the data did not hold up 63 00:05:08,934 --> 00:05:10,834 to further observation. 64 00:05:13,066 --> 00:05:16,066 Still, it fed the hope that we'll one day 65 00:05:16,066 --> 00:05:20,233 stumble upon a world like Earth in our own backyard 66 00:05:22,467 --> 00:05:27,400 with oceans, a robust magnetic field to shelter it 67 00:05:27,400 --> 00:05:31,400 from solar winds, a moon to stabilize its orbit, 68 00:05:37,400 --> 00:05:40,066 and even creatures who reveal their presence 69 00:05:40,066 --> 00:05:43,500 by beaming electronic signals into space. 70 00:05:50,200 --> 00:05:53,934 In 2016, Alpha Centauri was back in the news. 71 00:05:56,867 --> 00:06:00,266 Astronomers announced they had found evidence of a planet 72 00:06:00,266 --> 00:06:02,433 orbiting Proxima Centauri. 73 00:06:05,000 --> 00:06:07,033 They confirmed this discovery with data 74 00:06:07,033 --> 00:06:10,867 from a network of telescopes around the world. 75 00:06:16,300 --> 00:06:18,734 The newly discovered planet, they said, 76 00:06:18,734 --> 00:06:22,066 is at least 1.3 times the mass of Earth. 77 00:06:24,633 --> 00:06:26,700 It occupies a close orbit, 78 00:06:26,700 --> 00:06:30,700 swinging around its parent star every 11.2 days. 79 00:06:32,633 --> 00:06:36,800 Surprisingly, that puts it within the star's habitable zone. 80 00:06:39,367 --> 00:06:40,867 That's the region around a star, 81 00:06:40,867 --> 00:06:43,166 in which temperatures are in the right range 82 00:06:43,166 --> 00:06:47,333 for liquid water to exist on the planet's surface. 83 00:06:50,001 --> 00:06:53,433 If the planet is much closer, the heat from the star 84 00:06:53,433 --> 00:06:55,600 would boil the water away. 85 00:06:57,900 --> 00:07:02,066 If further out, the planet's water would freeze solid. 86 00:07:06,900 --> 00:07:09,567 In our solar system, Earth sits squarely 87 00:07:09,567 --> 00:07:12,667 within the habitable zone, which extends out 88 00:07:12,667 --> 00:07:16,400 toward the orbit of Mars and in toward Venus. 89 00:07:18,300 --> 00:07:22,467 Our star is roughly 10 times the radius of Proxima Centauri. 90 00:07:23,567 --> 00:07:28,033 Because Proxima has only 2% the luminosity of the sun, 91 00:07:28,033 --> 00:07:32,200 its habitable zone sits well inside the orbit of Mercury. 92 00:07:34,533 --> 00:07:38,333 While our sun's light spans the electromagnetic spectrum, 93 00:07:38,333 --> 00:07:40,266 Proxima's light is concentrated 94 00:07:40,266 --> 00:07:43,600 in the long wavelength infrared portion. 95 00:07:47,133 --> 00:07:49,533 That means that if you were to visit the planet, 96 00:07:49,533 --> 00:07:53,700 your eyes would see a world draped in green and red. 97 00:07:56,467 --> 00:07:58,867 There is enough solar heat striking the planet 98 00:07:58,867 --> 00:08:01,367 to allow liquid water to flow. 99 00:08:06,066 --> 00:08:08,266 However, it's still a matter of debate 100 00:08:08,266 --> 00:08:11,567 whether Proxima B and other planets like it 101 00:08:11,567 --> 00:08:15,300 could ever support a climate, much less life. 102 00:08:20,600 --> 00:08:24,567 And yet, small dim stars like Proxima Centauri 103 00:08:24,567 --> 00:08:28,166 may offer our best chances of finding a habitable planet 104 00:08:28,166 --> 00:08:30,333 in the solar neighborhood. 105 00:08:34,900 --> 00:08:38,166 (light dramatic music) 106 00:08:44,200 --> 00:08:48,000 The Kepler Space Telescope was launched in the year 2009 107 00:08:48,000 --> 00:08:51,500 with a major goal of finding small rocky planets 108 00:08:51,500 --> 00:08:53,667 that could resemble Earth. 109 00:08:58,133 --> 00:09:00,300 Pointed at a patch of sky in the direction 110 00:09:00,300 --> 00:09:03,001 of the Cygnus constellation, 111 00:09:03,001 --> 00:09:05,266 the telescope was used to measure the brightness 112 00:09:05,266 --> 00:09:08,100 of 150,000 stars every 30 minutes. 113 00:09:15,300 --> 00:09:19,700 Kepler uses what's known as the transit method. 114 00:09:19,700 --> 00:09:22,500 When a planet passes in front of a star, 115 00:09:22,500 --> 00:09:26,066 it causes the star's light to dip slightly. 116 00:09:31,567 --> 00:09:33,533 The initial survey picked up planets 117 00:09:33,533 --> 00:09:37,700 that had the most pronounced effect on the star's light, 118 00:09:38,600 --> 00:09:42,700 large, heavy worlds that whip around their parent stars 119 00:09:42,700 --> 00:09:44,533 every five to 50 days. 120 00:09:47,800 --> 00:09:51,800 Some are large rocky worlds called super-Earths. 121 00:09:54,100 --> 00:09:56,900 They most likely formed within warm dust clouds 122 00:09:56,900 --> 00:10:01,066 left over from the formation of their parent stars. 123 00:10:02,700 --> 00:10:05,300 Some of these are so close to their parent stars 124 00:10:05,300 --> 00:10:09,133 that they're most likely emblazoned with lava. 125 00:10:16,500 --> 00:10:19,333 Others are gas giants that migrated in 126 00:10:19,333 --> 00:10:21,500 from the outer solar systems, 127 00:10:21,500 --> 00:10:24,433 drawn by the gravity of their star. 128 00:10:26,467 --> 00:10:29,934 In the closest orbits, solar heat and particle winds 129 00:10:29,934 --> 00:10:34,100 are slowly stripping them of their thick atmospheres. 130 00:10:38,867 --> 00:10:42,266 In a more recent survey, scientists used Kepler 131 00:10:42,266 --> 00:10:45,100 to focus on 42,000 sun-like stars. 132 00:10:47,533 --> 00:10:50,533 In a statistical study based on this sample, 133 00:10:50,533 --> 00:10:53,633 they found that 22% of these stars 134 00:10:53,633 --> 00:10:56,200 have planets about the size of Earth, 135 00:10:56,200 --> 00:11:00,367 with an orbit in the right range to support liquid water. 136 00:11:04,333 --> 00:11:06,700 If this estimate is right, then our galaxy 137 00:11:06,700 --> 00:11:10,867 potentially harbors around nine billion such planets. 138 00:11:14,900 --> 00:11:18,166 Statistically speaking, we can expect to find 139 00:11:18,166 --> 00:11:21,834 at least one within 12 light years of Earth. 140 00:11:23,700 --> 00:11:26,967 That doesn't mean it will support life. 141 00:11:29,767 --> 00:11:34,166 Venus sits in the inner edge of our habitable zone. 142 00:11:34,166 --> 00:11:36,333 It's enshrouded in a thick atmosphere 143 00:11:36,333 --> 00:11:39,767 dominated by a runaway greenhouse effect. 144 00:11:41,000 --> 00:11:45,000 There is no liquid water or life on its surface. 145 00:11:50,867 --> 00:11:52,633 Mars, at the outer edge, 146 00:11:52,633 --> 00:11:55,700 has lost nearly its entire atmosphere 147 00:11:58,800 --> 00:12:02,734 and today, the planet is cold, dry, and barren. 148 00:12:08,066 --> 00:12:12,900 To improve their chances of turning up an Earth 2.0, 149 00:12:12,900 --> 00:12:14,900 scientists are intensely monitoring 150 00:12:14,900 --> 00:12:18,133 a much larger population of dim stars, 151 00:12:18,133 --> 00:12:21,233 like Proxima Centauri, that are nestled 152 00:12:21,233 --> 00:12:23,667 among their brighter cousins. 153 00:12:26,100 --> 00:12:29,834 These so-called M stars, or red dwarfs, 154 00:12:29,834 --> 00:12:34,100 range from 1/2 to 1/20th the mass of our sun 155 00:12:34,100 --> 00:12:38,266 and make up 76% of all the stars in our galaxy. 156 00:12:41,300 --> 00:12:43,600 Interest in these stars was spurred, in part, 157 00:12:43,600 --> 00:12:47,767 by studies of the star Gliese 581, 20 light years away, 158 00:12:49,100 --> 00:12:52,333 in the southern constellation of Libra. 159 00:13:00,734 --> 00:13:03,867 The planet hunters of the European Southern Observatory 160 00:13:03,867 --> 00:13:07,633 first deduced the presence of Gliese 581 b, 161 00:13:07,633 --> 00:13:10,633 a planet 16 times the mass of Earth. 162 00:13:15,300 --> 00:13:19,567 At a distance of only six million kilometers from its sun, 163 00:13:19,567 --> 00:13:23,233 it's well inside the habitable zone. 164 00:13:23,233 --> 00:13:26,800 It's flanked by two others, planet c and e. 165 00:13:30,033 --> 00:13:32,533 Planet d, still unconfirmed, 166 00:13:32,533 --> 00:13:35,567 is at the outer edge of the habitable zone, 167 00:13:35,567 --> 00:13:39,001 about 33 million kilometers from its sun. 168 00:13:41,767 --> 00:13:44,001 It receives only 30% of the light 169 00:13:44,001 --> 00:13:46,400 that Earth gets from our sun. 170 00:13:49,233 --> 00:13:51,934 It may be an icy world that migrated in 171 00:13:51,934 --> 00:13:54,266 from the outer solar system. 172 00:13:58,967 --> 00:14:01,567 Gliese 581 g, also unconfirmed, 173 00:14:02,633 --> 00:14:06,800 is thought to lie at the inner edge of the habitable zone. 174 00:14:08,633 --> 00:14:11,633 At twice the mass of Earth, it might have a chance 175 00:14:11,633 --> 00:14:13,800 of supporting liquid water 176 00:14:16,367 --> 00:14:19,533 but this planet is nothing like Earth. 177 00:14:23,200 --> 00:14:26,967 Our Earth spins on its axis, 366.25 rotations 178 00:14:28,533 --> 00:14:31,033 for every turn around the sun. 179 00:14:32,133 --> 00:14:35,867 With the exception of polar areas in opposing seasons, 180 00:14:35,867 --> 00:14:39,800 every part of the Earth sees the sun every day. 181 00:14:41,033 --> 00:14:43,433 That helps distribute solar heating, 182 00:14:43,433 --> 00:14:45,900 while generating the winds and ocean currents 183 00:14:45,900 --> 00:14:48,500 that define our global climate. 184 00:14:50,533 --> 00:14:52,333 Earth is far enough from the sun 185 00:14:52,333 --> 00:14:55,600 that the gravity of the star doesn't exert much influence 186 00:14:55,600 --> 00:14:57,533 on its spinning motion. 187 00:14:59,867 --> 00:15:04,033 In much closer orbits, Gliese 581 g, like its cousin, 188 00:15:05,033 --> 00:15:07,500 Proxima b, will likely have fallen 189 00:15:07,500 --> 00:15:10,834 into what's known as gravitational lock. 190 00:15:15,100 --> 00:15:18,867 That means that only one side ever faces the sun, 191 00:15:18,867 --> 00:15:23,033 while the other side faces out into the darkness of space. 192 00:15:25,333 --> 00:15:27,467 The traditional thinking is that 193 00:15:27,467 --> 00:15:29,934 if there is water on this planet, 194 00:15:29,934 --> 00:15:32,967 it has most likely evaporated from the light side 195 00:15:32,967 --> 00:15:36,734 and become impounded as ice on the dark side. 196 00:15:42,934 --> 00:15:46,300 That view began to change in the late 1990s, 197 00:15:46,300 --> 00:15:49,500 when NASA scientists simulated the atmosphere 198 00:15:49,500 --> 00:15:51,734 of a locked planet. 199 00:15:51,734 --> 00:15:53,700 They found that global wind patterns 200 00:15:53,700 --> 00:15:57,867 could develop and transport heat to the dark side. 201 00:16:09,000 --> 00:16:12,133 Scientists at the California Institute of Technology 202 00:16:12,133 --> 00:16:16,266 sought to test this finding on our planet. 203 00:16:16,266 --> 00:16:18,333 Working with a supercomputer program 204 00:16:18,333 --> 00:16:21,133 normally used to predict our climate, 205 00:16:21,133 --> 00:16:24,467 they simply turned off Earth's rotation. 206 00:16:26,066 --> 00:16:28,900 The team placed the sub-solar point, 207 00:16:28,900 --> 00:16:30,834 the region facing the sun, 208 00:16:30,834 --> 00:16:33,834 just off the coast of South America. 209 00:16:36,400 --> 00:16:38,700 Evaporation on the sunny side 210 00:16:38,700 --> 00:16:41,033 sent air rising up in storms 211 00:16:43,100 --> 00:16:47,166 and pushing back over the poles to the dark side. 212 00:16:54,834 --> 00:16:57,533 As a result of this poleward flow, 213 00:16:57,533 --> 00:17:00,934 Alaska experienced summer all year round. 214 00:17:09,200 --> 00:17:11,200 Land masses on the dark side, 215 00:17:11,200 --> 00:17:15,033 including Europe, Asia, and Africa, went cold. 216 00:17:18,667 --> 00:17:22,433 Remarkably, over the five decades of the simulation, 217 00:17:22,433 --> 00:17:26,600 the oceans retained enough heat to stay clear of ice. 218 00:17:27,800 --> 00:17:31,367 On the light side, large parts of the Western Hemisphere 219 00:17:31,367 --> 00:17:33,767 dried out, turning to desert. 220 00:17:38,967 --> 00:17:42,300 But if you pitched your tent at the sub-solar point, 221 00:17:42,300 --> 00:17:44,266 you'd find a hot and rainy climate 222 00:17:44,266 --> 00:17:48,433 that resembles this place, the island of Kauai in Hawaii. 223 00:17:52,467 --> 00:17:55,533 Its highest point is Mount Waialeale, 224 00:17:56,367 --> 00:18:00,533 that's Hawaiian for rippling or overflowing water. 225 00:18:01,400 --> 00:18:03,767 Known as the wettest place on Earth, 226 00:18:03,767 --> 00:18:07,700 the summit averages 11 meters of rain per year. 227 00:18:15,400 --> 00:18:19,233 How would life adapt to sunlight all the time? 228 00:18:21,433 --> 00:18:25,834 Plants depend on light to drive photosynthesis, 229 00:18:25,834 --> 00:18:29,100 a process that combines CO2 with water 230 00:18:29,100 --> 00:18:32,100 to produce sugars needed for growth. 231 00:18:33,834 --> 00:18:38,033 They use the day/night cycle to maximize this process, 232 00:18:38,033 --> 00:18:40,033 to tune their growth rates, 233 00:18:40,033 --> 00:18:42,967 and to take in more carbon dioxide. 234 00:18:43,800 --> 00:18:46,734 In polar regions, some plants are known to thrive 235 00:18:46,734 --> 00:18:50,233 in periods of extended sunlight in summer. 236 00:18:52,734 --> 00:18:55,200 So, if you take away the night, 237 00:18:55,200 --> 00:18:58,533 there is a chance that life could adapt. 238 00:19:03,133 --> 00:19:05,400 On Earth, its ability to do so 239 00:19:05,400 --> 00:19:09,367 draws upon hundreds of millions of years of evolution 240 00:19:09,367 --> 00:19:13,533 in a diverse global biosphere, dependable day/night cycles, 241 00:19:16,033 --> 00:19:18,200 and moderate temperatures. 242 00:19:24,633 --> 00:19:26,100 The question is whether a climate 243 00:19:26,100 --> 00:19:30,266 could develop in the first place on a locked planet. 244 00:19:33,100 --> 00:19:35,166 A team from the University of Chicago 245 00:19:35,166 --> 00:19:37,266 sought to answer this question 246 00:19:37,266 --> 00:19:41,433 by simulating the different states such a planet could take. 247 00:19:48,100 --> 00:19:50,133 The most promising scenario, 248 00:19:50,133 --> 00:19:53,233 assuming abundant water and carbon dioxide, 249 00:19:53,233 --> 00:19:56,900 is a planetary type called an eyeball Earth. 250 00:19:58,900 --> 00:20:01,600 This planet is gravitationally locked 251 00:20:01,600 --> 00:20:05,367 with an icy dark side and a sunny light side. 252 00:20:11,567 --> 00:20:14,000 In between is a transition zone, 253 00:20:14,000 --> 00:20:17,266 where the sun is always low in the sky. 254 00:20:19,100 --> 00:20:21,400 Here, the ice gradually fades 255 00:20:21,400 --> 00:20:24,100 into a warmer, sun-filled realm. 256 00:20:26,467 --> 00:20:29,400 In this representation, the sub-solar point 257 00:20:29,400 --> 00:20:33,567 is flanked by a continent and areas of open ocean. 258 00:20:38,166 --> 00:20:41,166 What could tip the balance toward habitability, 259 00:20:41,166 --> 00:20:43,233 according to one recent study, 260 00:20:43,233 --> 00:20:47,633 is the planet's ability to maintain a cloud cover. 261 00:20:47,633 --> 00:20:51,266 If warmth from the light side flows to the dark side, 262 00:20:51,266 --> 00:20:52,934 it can moderate temperatures 263 00:20:52,934 --> 00:20:56,934 and allow ice to melt along the transition zone. 264 00:21:01,300 --> 00:21:04,100 As water flows back to the light side, 265 00:21:04,100 --> 00:21:07,033 it evaporates, fueling more clouds. 266 00:21:10,133 --> 00:21:12,100 Clouds further moderate temperatures 267 00:21:12,100 --> 00:21:15,734 by reflecting solar radiation back to space, 268 00:21:15,734 --> 00:21:18,467 while also contributing to a greenhouse effect 269 00:21:18,467 --> 00:21:20,066 that holds heat in. 270 00:21:21,834 --> 00:21:25,500 But even if Proxima b has all the right characteristics, 271 00:21:25,500 --> 00:21:29,667 it would still face formidable obstacles to nurturing life. 272 00:21:34,166 --> 00:21:36,233 Proxima Centauri, for example, 273 00:21:36,233 --> 00:21:38,867 is known as an active M5 star 274 00:21:38,867 --> 00:21:43,033 that currently emits intense flares every 10 to 30 hours. 275 00:21:47,066 --> 00:21:51,200 For a planet in such a close orbit, blasts of radiation 276 00:21:51,200 --> 00:21:54,867 can split water molecules in the atmosphere. 277 00:21:59,367 --> 00:22:02,500 That allows hydrogen to waft into space 278 00:22:02,500 --> 00:22:06,066 and oxygen to bind to rocks on the surface. 279 00:22:06,066 --> 00:22:09,633 This process can strip the planet of water. 280 00:22:11,467 --> 00:22:14,700 (light dramatic music) 281 00:22:19,567 --> 00:22:21,667 To find out what state Proxima b 282 00:22:21,667 --> 00:22:25,433 and other nearby planets are in, astronomers will turn 283 00:22:25,433 --> 00:22:28,233 to a series of powerful new telescopes 284 00:22:28,233 --> 00:22:31,133 coming online over the next decade. 285 00:22:33,867 --> 00:22:36,667 The long awaited James Webb Space Telescope, 286 00:22:36,667 --> 00:22:41,200 slated for launch in 2018, represents the next generation 287 00:22:41,200 --> 00:22:43,600 of great space observatories. 288 00:22:49,200 --> 00:22:51,266 With a segmented primary mirror 289 00:22:51,266 --> 00:22:55,333 that is almost three times larger than that of Hubble, 290 00:22:55,333 --> 00:22:58,433 the James Webb will capture the trickle of photons 291 00:22:58,433 --> 00:23:00,934 coming from the early universe 292 00:23:02,233 --> 00:23:03,467 and allow scientists 293 00:23:03,467 --> 00:23:07,033 to finally parse the light of nearby stars. 294 00:23:16,333 --> 00:23:20,500 The WFIRST Telescope is slated to launch in the mid-2020s. 295 00:23:22,700 --> 00:23:26,500 With the resolution of Hubble, WFIRST will take in light 296 00:23:26,500 --> 00:23:29,066 from a region 100 times larger. 297 00:23:32,734 --> 00:23:37,400 Its main targets include distant exploding stars 298 00:23:37,400 --> 00:23:41,600 used to measure the expansion of the universe, 299 00:23:41,600 --> 00:23:44,400 along with planets interacting with stars 300 00:23:44,400 --> 00:23:46,400 in nearby solar systems. 301 00:23:47,834 --> 00:23:50,533 WFIRST will bring a powerful new technique 302 00:23:50,533 --> 00:23:52,033 to planet hunting. 303 00:23:53,200 --> 00:23:56,066 If a star passes in front of another star, 304 00:23:56,066 --> 00:23:59,500 it acts as a lens, brightening and dimming 305 00:23:59,500 --> 00:24:03,500 in ways that can betray the presence of planets. 306 00:24:05,367 --> 00:24:08,667 These new instruments promise an unprecedented view 307 00:24:08,667 --> 00:24:11,266 into the light of nearby stars. 308 00:24:17,033 --> 00:24:18,800 By deploying coronagraphs 309 00:24:18,800 --> 00:24:21,467 to block the light of parent stars, 310 00:24:21,467 --> 00:24:25,633 they'll be able to pick up light reflected by planets. 311 00:24:27,567 --> 00:24:29,100 This technique will allow scientists 312 00:24:29,100 --> 00:24:33,266 to measure surface temperatures, as well as distinguish 313 00:24:33,266 --> 00:24:36,600 between a planet's light and dark sides. 314 00:24:38,934 --> 00:24:42,533 They can also use a spectrograph to detect atmospheres 315 00:24:42,533 --> 00:24:46,200 and to look for chemical signatures of life. 316 00:24:48,467 --> 00:24:51,533 There will be no shortage of targets. 317 00:24:52,934 --> 00:24:54,867 The Belgian Trappist Telescope 318 00:24:54,867 --> 00:24:57,400 turned up a surprising cache of planets 319 00:24:57,400 --> 00:25:00,834 circling what may seem an unlikely place. 320 00:25:07,133 --> 00:25:09,834 At 40 light years away, TRAPPIST-1 321 00:25:09,834 --> 00:25:14,834 is a cross between a large Jupiter-like planet and a star. 322 00:25:14,834 --> 00:25:18,367 This ultra cool dwarf emits only a tiny fraction 323 00:25:18,367 --> 00:25:20,367 of the light of our sun. 324 00:25:23,433 --> 00:25:26,367 Astronomers use the transit method, 325 00:25:27,500 --> 00:25:30,001 using their telescope to detect slight dips 326 00:25:30,001 --> 00:25:34,166 in the light of the star as planets passed in front. 327 00:25:36,367 --> 00:25:39,500 Then, they followed up with an intensive program 328 00:25:39,500 --> 00:25:42,400 of observations from telescopes on the ground 329 00:25:42,400 --> 00:25:46,567 and in space, including NASA's Spitzer Infrared Observatory. 330 00:25:51,667 --> 00:25:54,033 They found seven planets bunched together 331 00:25:54,033 --> 00:25:58,233 in orbits close enough to be tidally locked. 332 00:25:58,233 --> 00:26:00,800 At least three of them are at the right distance 333 00:26:00,800 --> 00:26:03,567 and temperature for liquid water. 334 00:26:07,000 --> 00:26:11,066 Planet F is the most likely to harbor life. 335 00:26:11,066 --> 00:26:14,166 It's 1.3 times the mass of Earth 336 00:26:14,166 --> 00:26:17,333 with an orbit lasting 9.21 Earth days. 337 00:26:20,734 --> 00:26:23,000 Gracing its salmon-colored skies 338 00:26:23,000 --> 00:26:25,900 are at least six sister planets, 339 00:26:25,900 --> 00:26:29,400 all as large or larger than our full moon. 340 00:26:33,066 --> 00:26:37,233 Here, you get 200 times less visible light than on Earth. 341 00:26:41,233 --> 00:26:45,400 Instead, the star bathes the planet in infrared light. 342 00:26:46,500 --> 00:26:50,667 It delivers enough energy to potentially power a climate. 343 00:26:56,867 --> 00:26:59,133 A broad initiative has begun to follow up 344 00:26:59,133 --> 00:27:00,800 on the flood of discoveries 345 00:27:00,800 --> 00:27:03,867 in this golden age of planet finding. 346 00:27:07,367 --> 00:27:09,867 Ground-based telescopes are now being outfitted 347 00:27:09,867 --> 00:27:13,266 with a new generation of imaging devices. 348 00:27:14,967 --> 00:27:19,700 At the European Very Large Telescope in Chile, for example, 349 00:27:19,700 --> 00:27:21,567 scientists are installing 350 00:27:21,567 --> 00:27:24,700 a new infrared imager inspectograph 351 00:27:24,700 --> 00:27:28,266 specifically with Proxima Centauri in mind. 352 00:27:29,600 --> 00:27:31,567 This effort is being done in collaboration 353 00:27:31,567 --> 00:27:35,400 with a whole new player in the space sciences. 354 00:27:38,300 --> 00:27:40,934 Breakthrough Initiatives is a privately funded, 355 00:27:40,934 --> 00:27:43,900 10 year, 100 million dollar plan 356 00:27:43,900 --> 00:27:47,567 to search for extraterrestrial intelligence. 357 00:27:51,200 --> 00:27:54,367 It hopes to lay the foundation for spacecraft missions 358 00:27:54,367 --> 00:27:57,033 out into our solar neighborhood. 359 00:27:59,367 --> 00:28:01,600 Any interstellar mission must confront 360 00:28:01,600 --> 00:28:05,266 the ultimate obstacles to space exploration, 361 00:28:06,266 --> 00:28:07,767 distance and time. 362 00:28:21,834 --> 00:28:23,867 The New Horizons Probe recently made 363 00:28:23,867 --> 00:28:27,433 the 4.8 billion kilometer journey to Pluto, 364 00:28:28,567 --> 00:28:30,400 arriving in 9.5 years. 365 00:28:33,233 --> 00:28:36,967 At its top speed, 84,000 kilometers per hour, 366 00:28:38,100 --> 00:28:40,266 it would take 54,400 years 367 00:28:41,767 --> 00:28:45,967 to travel the 40 trillion kilometers to Proxima Centauri. 368 00:28:49,767 --> 00:28:54,734 The spacecraft, Voyager II, would take even longer, 369 00:28:54,734 --> 00:28:58,900 70,000 years, traveling at 69,000 kilometers per hour. 370 00:29:02,967 --> 00:29:05,500 In a sense, though, Voyager paves the way 371 00:29:05,500 --> 00:29:08,001 for future interstellar treks. 372 00:29:12,633 --> 00:29:15,934 Voyager's designers imagined these twin spacecraft 373 00:29:15,934 --> 00:29:19,033 would far outlast human civilization. 374 00:29:20,100 --> 00:29:22,867 With their current momentum, they could wander the galaxy 375 00:29:22,867 --> 00:29:26,600 for millions, even tens of millions of years. 376 00:29:29,433 --> 00:29:30,633 What if intelligent beings 377 00:29:30,633 --> 00:29:33,467 detected and captured one of them? 378 00:29:37,433 --> 00:29:40,834 Its handlers famously placed a trove of information aboard 379 00:29:40,834 --> 00:29:43,433 to educate these alien captors. 380 00:29:48,066 --> 00:29:51,233 That includes information about Planet Earth, 381 00:29:51,233 --> 00:29:53,233 its people and culture, 382 00:29:53,233 --> 00:29:56,400 including images and sound recordings. 383 00:29:57,400 --> 00:29:59,967 It also offers a way to find us 384 00:29:59,967 --> 00:30:03,633 in case anyone decides to follow up. 385 00:30:03,633 --> 00:30:08,200 This symbol is a system of celestial GPS coordinates. 386 00:30:08,200 --> 00:30:11,533 It places Earth at the junction of radio beacons 387 00:30:11,533 --> 00:30:15,500 emitted in this part of the galaxy by pulsars. 388 00:30:15,500 --> 00:30:17,667 They are a type of ultra-dense star 389 00:30:17,667 --> 00:30:21,834 that spins rapidly, giving off pulses of radio energy. 390 00:30:24,133 --> 00:30:26,166 Like sailors who once used a sexton 391 00:30:26,166 --> 00:30:29,967 to navigate by the stars, a future spacecraft 392 00:30:29,967 --> 00:30:32,333 could use pulsars to orient itself 393 00:30:32,333 --> 00:30:36,333 in the featureless expanse of interstellar space 394 00:30:39,001 --> 00:30:41,734 and navigate to a distant target. 395 00:30:43,700 --> 00:30:47,200 NASA engineers are now designing a prototype space sexton 396 00:30:47,200 --> 00:30:51,367 to be tested aboard the International Space Station. 397 00:30:52,934 --> 00:30:55,367 As the station orbits the Earth, 398 00:30:55,367 --> 00:30:59,533 the instrument locks on to the light of distant pulsars. 399 00:31:04,700 --> 00:31:08,066 In 1990, as it sped toward the outer regions 400 00:31:08,066 --> 00:31:11,500 of our solar system, the Voyager I spacecraft 401 00:31:11,500 --> 00:31:14,500 turned its camera back toward Earth. 402 00:31:19,100 --> 00:31:22,800 From six billion kilometers away, it sent back an image 403 00:31:22,800 --> 00:31:25,734 of the pale blue dot we call Earth. 404 00:31:29,066 --> 00:31:32,367 It was a humbling reminder of the rare and precious world 405 00:31:32,367 --> 00:31:34,100 that has nurtured us. 406 00:31:37,100 --> 00:31:40,834 Today, we're looking out beyond our solar system 407 00:31:40,834 --> 00:31:44,433 to a planetary destination illuminated by the dim light 408 00:31:44,433 --> 00:31:47,433 of its parent star, Proxima Centauri 409 00:31:52,100 --> 00:31:54,066 but can we realistically get anywhere near 410 00:31:54,066 --> 00:31:57,834 this pale red dot over four light years away? 411 00:32:05,934 --> 00:32:08,333 Interstellar flight has long been a staple 412 00:32:08,333 --> 00:32:09,934 of science fiction. 413 00:32:14,467 --> 00:32:17,767 Humans from technologically advanced future civilizations 414 00:32:17,767 --> 00:32:21,934 routinely board starships for remote corners of the galaxy. 415 00:32:24,633 --> 00:32:26,834 For some real-world scientists, 416 00:32:26,834 --> 00:32:29,633 the challenge of crossing the immense voids of time 417 00:32:29,633 --> 00:32:33,800 and space has led to whole new lines of investigation. 418 00:32:42,266 --> 00:32:44,767 Propulsion engineers have submitted proposals 419 00:32:44,767 --> 00:32:48,367 for the development of advanced spacecraft, 420 00:32:49,967 --> 00:32:53,233 powered by nuclear fusion, anti-matter, 421 00:32:58,066 --> 00:33:01,734 the gravity of tiny, artificial black holes, 422 00:33:04,100 --> 00:33:06,934 the strange physics of warp drive, 423 00:33:10,200 --> 00:33:12,266 and specially designed sails 424 00:33:12,266 --> 00:33:15,100 to be pushed along by solar winds, 425 00:33:21,033 --> 00:33:22,633 or by giant lasers. 426 00:33:25,834 --> 00:33:27,433 (light dramatic music) 427 00:33:27,433 --> 00:33:30,100 This is a surprisingly old idea. 428 00:33:32,333 --> 00:33:35,633 The 17th century astronomer, Johannes Kepler, 429 00:33:35,633 --> 00:33:37,633 observed comet tails being blown 430 00:33:37,633 --> 00:33:41,133 by what he thought must be a solar breeze. 431 00:33:42,166 --> 00:33:45,834 He served up an imaginary scene to his friend, Galileo, 432 00:33:45,834 --> 00:33:50,001 of ships powered by sails adapted to the heavenly breezes. 433 00:33:53,400 --> 00:33:57,066 In 1873, James Clerk Maxwell showed 434 00:33:57,066 --> 00:33:59,333 that light exerts pressure, 435 00:34:00,200 --> 00:34:04,266 an idea that motivated modern space sail designs. 436 00:34:06,700 --> 00:34:09,567 NASA engineers were able to put this idea to the test 437 00:34:09,567 --> 00:34:13,667 during the Mariner 10 mission to Mercury in 1974. 438 00:34:14,700 --> 00:34:17,967 They used the pressure of sunlight on its solar panels 439 00:34:17,967 --> 00:34:21,467 to stabilize its flight around the planet. 440 00:34:25,700 --> 00:34:28,200 Modern mission designers have warmed to sails 441 00:34:28,200 --> 00:34:32,367 because they don't require enormous amounts of fuel. 442 00:34:33,767 --> 00:34:37,800 Recent advances in the miniaturization of electronics 443 00:34:37,800 --> 00:34:40,467 and strong, light, new materials 444 00:34:41,767 --> 00:34:44,700 are giving the idea a new currency. 445 00:34:50,834 --> 00:34:54,700 And now, the discovery of planets in our solar neighborhood 446 00:34:54,700 --> 00:34:58,800 offers a range of potential interstellar targets. 447 00:35:03,467 --> 00:35:06,500 A new plan announced by Breakthrough Initiatives, 448 00:35:06,500 --> 00:35:10,367 called Operation Starshot, will use sails 449 00:35:10,367 --> 00:35:14,533 to target the closest of these targets, Alpha Centauri. 450 00:35:31,800 --> 00:35:35,266 The breakthrough plan calls for an array of powerful lasers 451 00:35:35,266 --> 00:35:39,433 installed on a high plain or desert in South America. 452 00:35:41,533 --> 00:35:44,600 In these dry, high altitude locations, 453 00:35:44,600 --> 00:35:47,667 the laser light is less likely to be distorted 454 00:35:47,667 --> 00:35:50,166 by moisture in the atmosphere. 455 00:35:55,400 --> 00:35:57,233 The lasers would draw power 456 00:35:57,233 --> 00:36:00,667 from a large, dedicated generating plant. 457 00:36:10,767 --> 00:36:14,300 The idea is to deploy a fleet of ultra-thin sails 458 00:36:14,300 --> 00:36:17,033 in Earth orbit, ready for launch. 459 00:36:23,800 --> 00:36:27,367 Each one is outfitted with a miniature command center, 460 00:36:27,367 --> 00:36:31,200 two centimeters wide and weighing only a gram. 461 00:36:32,700 --> 00:36:35,934 This tiny chip contains sensors, 462 00:36:35,934 --> 00:36:39,266 shielding against cosmic radiation, 463 00:36:39,266 --> 00:36:41,834 and a radioactive power supply. 464 00:36:42,700 --> 00:36:44,967 Add to that mini-thrusters, 465 00:36:46,033 --> 00:36:49,100 a communication system, and a camera. 466 00:36:58,567 --> 00:37:02,734 This light sail is relatively small, four meters wide, 467 00:37:05,266 --> 00:37:09,600 and perhaps only a few hundred atoms thick. 468 00:37:09,600 --> 00:37:10,834 It would have to be tough enough 469 00:37:10,834 --> 00:37:14,834 to withstand the impact of a high-powered laser. 470 00:37:23,834 --> 00:37:27,000 The launch array locks on to its target 471 00:37:27,000 --> 00:37:30,066 on a line of sight to Alpha Centauri. 472 00:37:36,467 --> 00:37:37,300 Ignition, 473 00:37:43,100 --> 00:37:44,100 and liftoff. 474 00:37:47,100 --> 00:37:50,367 The next day, with the charge restored, 475 00:37:50,367 --> 00:37:53,133 the array is ready to fire again. 476 00:38:10,467 --> 00:38:15,100 The spacecraft quickly reaches 20% the speed of light, 477 00:38:15,100 --> 00:38:17,367 passing Saturn within hours 478 00:38:18,834 --> 00:38:21,433 and Pluto in just a day or two. 479 00:38:32,033 --> 00:38:33,100 For most of the journey, 480 00:38:33,100 --> 00:38:36,767 the spacecraft go dormant to preserve power. 481 00:38:41,033 --> 00:38:43,500 Periodically, the lead craft wakes 482 00:38:43,500 --> 00:38:46,300 to perform guidance maneuvers 483 00:38:46,300 --> 00:38:50,133 or to send information back to the next spacecraft in line 484 00:38:50,133 --> 00:38:52,133 for relay back to Earth. 485 00:38:57,633 --> 00:39:00,133 Finally, in two decades time, 486 00:39:00,133 --> 00:39:04,300 the fleet approaches its target, Proxima Centauri. 487 00:39:06,734 --> 00:39:09,600 The craft may be able to use the wind of particles 488 00:39:09,600 --> 00:39:12,433 coming from the star to slow down. 489 00:39:14,967 --> 00:39:19,133 As each flies by, they turn to face the planet, Proxima b. 490 00:39:24,533 --> 00:39:27,033 The camera captures the scene. 491 00:39:33,567 --> 00:39:35,834 Perhaps as it turns around, 492 00:39:37,934 --> 00:39:42,033 we'll see our sun, a brilliant white dot 493 00:39:42,033 --> 00:39:44,767 framed by the galactic landscape. 494 00:39:51,200 --> 00:39:55,600 As for the pale red dot and its planetary companion, 495 00:39:55,600 --> 00:39:58,100 what will we learn from the morsels of information 496 00:39:58,100 --> 00:40:00,333 that make it back to Earth? 497 00:40:05,333 --> 00:40:09,533 With luck, we'll find that Proxima b is having its day 498 00:40:09,533 --> 00:40:13,367 in the sun, with the development of a global climate 499 00:40:13,367 --> 00:40:15,934 that perhaps has nurtured life. 500 00:40:21,734 --> 00:40:24,400 For some on our own planet, 501 00:40:24,400 --> 00:40:28,567 the news that a spacecraft has arrived at an alien world 502 00:40:28,567 --> 00:40:30,834 will no doubt pass overhead 503 00:40:33,834 --> 00:40:37,166 in the ongoing daily rush of technology, 504 00:40:40,166 --> 00:40:41,166 crisis, war, 505 00:40:50,633 --> 00:40:52,467 consuming, and escape. 506 00:41:00,967 --> 00:41:04,166 For others, that day will be filled 507 00:41:06,133 --> 00:41:09,300 with a sense of humility, fascination, 508 00:41:13,900 --> 00:41:18,800 and wonder. 41360