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These are the user uploaded subtitles that are being translated: 0 00:00:00,010 --> 00:00:07,777 1 00:00:02,136 --> 00:00:06,071 Earth. 2 00:00:07,274 --> 00:00:10,342 The cradle of humanity throughout our existence. 3 00:00:16,751 --> 00:00:18,484 But it won't be forever. 4 00:00:21,655 --> 00:00:23,956 All it would take would be one giant meteorite 5 00:00:23,958 --> 00:00:26,358 to wipe us off the face of the earth. 6 00:00:33,067 --> 00:00:35,601 It's not just meteors. 7 00:00:35,603 --> 00:00:38,437 Our planet will change. 8 00:00:38,439 --> 00:00:43,108 Our planet could freeze over or it could heat up. 9 00:00:43,110 --> 00:00:46,512 And our sun will eventually die. 10 00:00:46,514 --> 00:00:51,850 We are actually near the end of habitability of earth. 11 00:00:51,852 --> 00:00:56,555 To survive in this universe, we need an insurance policy... 12 00:01:00,461 --> 00:01:03,829 To colonize other worlds. 13 00:01:03,831 --> 00:01:06,265 Having multiple planets which are colonized 14 00:01:06,267 --> 00:01:09,601 is really in our interest for our own survival. 15 00:01:10,905 --> 00:01:14,873 So can we find a new home in the galaxy? 16 00:01:16,477 --> 00:01:19,945 Can we find earth 2.0? 17 00:01:25,653 --> 00:01:28,687 Captions paid for by discovery communications 18 00:01:38,966 --> 00:01:42,367 for centuries, we only knew of the handful of planets 19 00:01:42,369 --> 00:01:44,036 in our own solar system. 20 00:01:49,110 --> 00:01:52,778 Now astronomers are finding thousands of new worlds 21 00:01:52,780 --> 00:01:57,049 around alien stars... exoplanets. 22 00:01:58,853 --> 00:02:04,423 We are discovering exoplanets by the bucketful. 23 00:02:07,595 --> 00:02:10,395 There are as many planets out there as there are stars, 24 00:02:10,397 --> 00:02:14,466 and there are hundreds of billions of stars in the galaxy. 25 00:02:16,737 --> 00:02:19,872 But out of billions of exoplanets, 26 00:02:19,874 --> 00:02:23,108 are there any that could offer new opportunities 27 00:02:23,110 --> 00:02:26,445 for humanity to thrive 28 00:02:26,447 --> 00:02:30,983 and provide sanctuary in a dangerous universe? 29 00:02:30,985 --> 00:02:34,019 Is there an earth 2.0? 30 00:02:36,590 --> 00:02:39,658 Is earth 2.0 out there? 31 00:02:39,660 --> 00:02:41,627 That would be truly amazing. 32 00:02:49,003 --> 00:02:52,571 August 2016. 33 00:02:52,573 --> 00:02:55,974 Astronomers announce that earth 2.0 34 00:02:55,976 --> 00:02:59,344 could be closer than anyone ever expected... 35 00:03:02,116 --> 00:03:07,186 A planet orbiting the sun's nearest stellar neighbor, 36 00:03:07,188 --> 00:03:10,689 the red dwarf proxima centauri. 37 00:03:13,627 --> 00:03:18,830 So it turns out that our nearest star neighbor has an exoplanet. 38 00:03:18,832 --> 00:03:20,699 It's only about 4 light-years away, 39 00:03:20,701 --> 00:03:23,969 so that means that it's actually potentially possible for us 40 00:03:23,971 --> 00:03:27,773 to get there and to explore it. 41 00:03:27,775 --> 00:03:31,610 Scientists named the planet after the star, 42 00:03:31,612 --> 00:03:36,481 proxima centauri b, or proxima b for short... 43 00:03:38,652 --> 00:03:42,321 A world that appears to be a lot like earth. 44 00:03:45,092 --> 00:03:48,126 From the way it's tugging on the star, proxima centauri, 45 00:03:48,128 --> 00:03:51,396 we know that it has 1.3 times the earth's mass. 46 00:03:51,398 --> 00:03:53,865 It's roughly the same size as the earth. 47 00:03:57,605 --> 00:03:59,705 Of the exoplanets we know about, 48 00:03:59,707 --> 00:04:04,876 most are uninhabitable gas giants, like jupiter. 49 00:04:04,878 --> 00:04:10,649 Proxima b is a rare find, an earth-sized planet, 50 00:04:10,651 --> 00:04:15,721 but an earth-sized planet might not be earthlike. 51 00:04:15,723 --> 00:04:19,424 A true second earth must also be the right distance 52 00:04:19,426 --> 00:04:21,159 from its star. 53 00:04:24,131 --> 00:04:25,697 The habitable zone, or some people call it 54 00:04:25,699 --> 00:04:30,702 the goldilocks region, is a distance away from the star 55 00:04:30,704 --> 00:04:33,438 where you're not so close where you're going to burn up 56 00:04:33,440 --> 00:04:35,440 and evaporate all of your liquids, 57 00:04:35,442 --> 00:04:38,777 and you're not so far away where you're frigid and cold. 58 00:04:38,779 --> 00:04:42,581 So it's that special region where it's just, just right. 59 00:04:45,252 --> 00:04:48,420 Does proxima b lie in this region? 60 00:04:48,422 --> 00:04:52,491 Could it have liquid water? 61 00:04:52,493 --> 00:04:56,962 Proxima centauri b orbits its star once every 11.2 days, 62 00:04:56,964 --> 00:04:59,531 so compare that to the earth, which goes around the sun 63 00:04:59,533 --> 00:05:02,167 once every 365 days. 64 00:05:02,169 --> 00:05:05,804 That's because the planet is much, much closer to the star 65 00:05:05,806 --> 00:05:07,439 than the earth is to the sun. 66 00:05:11,612 --> 00:05:15,380 Earth orbits 93 million miles from the sun. 67 00:05:17,584 --> 00:05:20,819 Proxima b orbits 20 times closer, 68 00:05:20,821 --> 00:05:23,388 under 5 million miles from its star. 69 00:05:26,126 --> 00:05:29,628 You might think that proxima b should be, 70 00:05:29,630 --> 00:05:33,565 you know, really a fried world, a burnt-out husk, if you will. 71 00:05:35,869 --> 00:05:39,971 But proxima b's sun is very different than ours. 72 00:05:43,344 --> 00:05:47,045 At just over 5,000 degrees fahrenheit, 73 00:05:47,047 --> 00:05:52,150 it's half as hot and roughly 8 times smaller, 74 00:05:52,152 --> 00:05:55,954 an m-class red dwarf star. 75 00:05:55,956 --> 00:05:59,725 An m-dwarf that proxima b is around is much less bright, 76 00:05:59,727 --> 00:06:01,626 much less hot, 77 00:06:01,628 --> 00:06:03,862 so you can orbit much closer to that star 78 00:06:03,864 --> 00:06:06,398 and be at the same temperature that we are here on earth. 79 00:06:11,438 --> 00:06:14,172 Proxima b's tight orbit around the red dwarf 80 00:06:14,174 --> 00:06:18,143 could make the planet habitable, 81 00:06:18,145 --> 00:06:20,912 but it would be very different from earth. 82 00:06:23,851 --> 00:06:28,086 The star dominates the sky, 83 00:06:28,088 --> 00:06:30,522 lighting any oceans and mountains 84 00:06:30,524 --> 00:06:32,491 with an alien red glow. 85 00:06:34,762 --> 00:06:38,663 So proxima b may be the earth 2.0 86 00:06:38,665 --> 00:06:41,166 that we've been looking for. 87 00:06:41,168 --> 00:06:43,969 But in 2017, 88 00:06:43,971 --> 00:06:46,905 the dim red dwarf star erupts in a way 89 00:06:46,907 --> 00:06:50,675 that's unlike anything we've seen before... 90 00:06:54,314 --> 00:06:56,915 Blasting the planet with radiation... 91 00:07:00,254 --> 00:07:02,754 A megaflare. 92 00:07:02,756 --> 00:07:04,055 They're like solar flares, 93 00:07:04,057 --> 00:07:05,891 but they can be much more powerful. 94 00:07:05,893 --> 00:07:09,895 In fact, they can outshine the star itself. 95 00:07:09,897 --> 00:07:12,831 Our sun releases powerful solar flares 96 00:07:12,833 --> 00:07:16,902 when its magnetic field becomes tangled. 97 00:07:20,240 --> 00:07:23,208 But the megaflare is 10 times stronger 98 00:07:23,210 --> 00:07:25,777 than our sun's strongest flares. 99 00:07:29,149 --> 00:07:31,783 On an m dwarf star, that magnetic field 100 00:07:31,785 --> 00:07:34,820 can get a lot more tangled than on our own sun. 101 00:07:34,822 --> 00:07:36,254 That means that when a flare happens, 102 00:07:36,256 --> 00:07:38,657 it can release a lot more energy. 103 00:07:42,062 --> 00:07:44,262 Scientists believe that megaflares like this 104 00:07:44,264 --> 00:07:45,797 are planet killers. 105 00:07:50,170 --> 00:07:55,640 Radiation tears the atmosphere from the planet, 106 00:07:55,642 --> 00:08:00,879 and these megaflares hit proxima b roughly once every year. 107 00:08:02,950 --> 00:08:06,985 Red dwarf stars are incredibly temperamental. 108 00:08:06,987 --> 00:08:10,722 They are not good parents to their planets, 109 00:08:10,724 --> 00:08:15,093 so if proxima b did have an atmosphere at one point, 110 00:08:15,095 --> 00:08:16,928 it would've been stripped away 111 00:08:16,930 --> 00:08:19,731 by one of these violent outbursts. 112 00:08:21,568 --> 00:08:26,204 Leaving proxima b dangerously exposed to space. 113 00:08:29,142 --> 00:08:31,643 An atmosphere dampens the temperature gradients 114 00:08:31,645 --> 00:08:33,778 between light and shadow, 115 00:08:33,780 --> 00:08:38,083 so in sunlight, it is just burning hot, 116 00:08:38,085 --> 00:08:41,686 but right next door in a shadow, it is freezing cold. 117 00:08:44,091 --> 00:08:46,458 Without an atmosphere, 118 00:08:46,460 --> 00:08:49,160 proxima b would be a barren wasteland, 119 00:08:49,162 --> 00:08:53,031 blasted by intense radiation from its star... 120 00:08:53,033 --> 00:08:55,667 completely uninhabitable. 121 00:08:57,905 --> 00:09:03,775 Proxima b, our perhaps best shot at finding earth 2.0 so far, 122 00:09:03,777 --> 00:09:06,011 is actually a dried out husk of a world 123 00:09:06,013 --> 00:09:07,612 that has lost its atmosphere, 124 00:09:07,614 --> 00:09:10,882 maybe lost any water that it also harbored, 125 00:09:10,884 --> 00:09:14,986 simply by being that close to its parent star. 126 00:09:19,860 --> 00:09:22,260 Proxima b may be the nearest exoplanet, 127 00:09:22,262 --> 00:09:24,229 but it's not the only option. 128 00:09:27,968 --> 00:09:33,138 The future of humanity may lie in an incredible star system 129 00:09:33,140 --> 00:09:36,474 just 40 light-years away. 130 00:09:36,476 --> 00:09:38,443 We've just found a really exciting system 131 00:09:38,445 --> 00:09:40,912 where there's not just one chance to have a new earth, 132 00:09:40,914 --> 00:09:42,614 but seven. 133 00:09:59,533 --> 00:10:01,466 In an unforgiving galaxy, 134 00:10:01,468 --> 00:10:05,070 finding earth 2.0 could be the difference 135 00:10:05,072 --> 00:10:08,239 between extinction and survival. 136 00:10:11,278 --> 00:10:15,513 It's a pretty wild place out there. 137 00:10:15,515 --> 00:10:17,115 Our planet is not going to be here forever, 138 00:10:17,117 --> 00:10:20,118 and it would be wonderful if we could find a place like it 139 00:10:20,120 --> 00:10:21,386 so that we could live. 140 00:10:25,926 --> 00:10:30,862 The future of humanity lies on an alien exoplanet. 141 00:10:30,864 --> 00:10:33,264 The question is, where? 142 00:10:37,571 --> 00:10:39,871 2016. 143 00:10:39,873 --> 00:10:42,774 Astronomers scan the skies with the new 144 00:10:42,776 --> 00:10:46,511 transiting planets and planetesimals small telescope, 145 00:10:46,513 --> 00:10:48,246 or trappist. 146 00:10:50,984 --> 00:10:53,652 They look for the flickering of a star 147 00:10:53,654 --> 00:10:59,057 caused by the silhouette of a planet. 148 00:10:59,059 --> 00:11:01,660 The planet can pass in front of the disk of its star 149 00:11:01,662 --> 00:11:04,029 once per orbit, causing a little mini eclipse, 150 00:11:04,031 --> 00:11:07,298 a little dimming temporarily in the light of the star. 151 00:11:08,769 --> 00:11:10,735 Scientists spot the dimming 152 00:11:10,737 --> 00:11:12,971 of a nearby red dwarf star 153 00:11:12,973 --> 00:11:16,508 just 40 light-years from earth, 154 00:11:16,510 --> 00:11:20,812 the first alien system detected by the telescope, 155 00:11:20,814 --> 00:11:23,782 the incredible trappist-1 system. 156 00:11:27,421 --> 00:11:28,887 The trappist-1 discovery 157 00:11:28,889 --> 00:11:33,925 was a really great bang for our buck in a sense... 158 00:11:33,927 --> 00:11:37,495 because we found seven exoplanets all at once. 159 00:11:39,132 --> 00:11:41,933 But are any of these seven planets 160 00:11:41,935 --> 00:11:44,135 actually habitable? 161 00:11:44,137 --> 00:11:45,603 With the worlds of the trappist system, 162 00:11:45,605 --> 00:11:47,772 there's probably a range of climates. 163 00:11:47,774 --> 00:11:50,475 The innermost ones are probably very hot. 164 00:11:50,477 --> 00:11:54,045 You might even be looking at lava worlds. 165 00:11:54,047 --> 00:11:57,482 Farther away, they're probably worlds of ice. 166 00:11:59,352 --> 00:12:03,121 But the middle planets... d, e, and f... 167 00:12:03,123 --> 00:12:04,789 are all prime candidates. 168 00:12:07,561 --> 00:12:10,061 It's exciting to think that three of the planets 169 00:12:10,063 --> 00:12:13,031 orbiting trappist-1 are in the "habitable zone," 170 00:12:13,033 --> 00:12:14,599 are at the right distance from that star 171 00:12:14,601 --> 00:12:16,801 to have liquid water on their surface. 172 00:12:21,274 --> 00:12:25,310 And one planet stands out as a new earth, 173 00:12:25,312 --> 00:12:29,447 orbiting just 2.7 million miles from the star... 174 00:12:29,449 --> 00:12:31,649 trappist-1e. 175 00:12:33,787 --> 00:12:36,955 The composition of trappist-1e suggests that it could have 176 00:12:36,957 --> 00:12:40,492 a pretty significant iron core, kind of like the earth does. 177 00:12:40,494 --> 00:12:43,695 There's a potential there for a very powerful magnetic field. 178 00:12:46,399 --> 00:12:48,399 Like earth, trappist-1e 179 00:12:48,401 --> 00:12:51,402 could host a protective magnetic field, 180 00:12:51,404 --> 00:12:54,072 deflecting the harsh solar winds 181 00:12:54,074 --> 00:12:57,542 and powerful outbursts that strip away atmospheres. 182 00:12:59,813 --> 00:13:01,479 So magnetic field is a good thing. 183 00:13:01,481 --> 00:13:05,383 It's a kind of a protection from the evil forces of the star 184 00:13:05,385 --> 00:13:07,952 that you're orbiting around. 185 00:13:07,954 --> 00:13:10,255 And unlike proxima centauri, 186 00:13:10,257 --> 00:13:15,493 the trappist-1 star appears unusually quiet. 187 00:13:15,495 --> 00:13:18,696 Trappist-1 is actually a very old, much calmer star 188 00:13:18,698 --> 00:13:21,232 and doesn't undergo a lot of these huge flares 189 00:13:21,234 --> 00:13:23,067 like proxima centauri does. 190 00:13:23,069 --> 00:13:25,837 And so it's a somewhat perhaps better system to look 191 00:13:25,839 --> 00:13:28,640 for an earthlike planet, an earth 2.0. 192 00:13:33,079 --> 00:13:36,047 The data suggests that trappist-1e 193 00:13:36,049 --> 00:13:37,782 could have vast oceans, 194 00:13:37,784 --> 00:13:41,653 a protective atmosphere, and habitable temperatures. 195 00:13:51,598 --> 00:13:56,935 But living here would be nothing like living on earth. 196 00:13:56,937 --> 00:13:59,070 The thing to keep in mind about the trappist system 197 00:13:59,072 --> 00:14:01,306 is that it's very unlike our own. 198 00:14:01,308 --> 00:14:05,443 The planets are much closer in, so because they're closer in, 199 00:14:05,445 --> 00:14:08,446 their orbits are faster and smaller. 200 00:14:08,448 --> 00:14:12,750 On trappist-1e, an entire year 201 00:14:12,752 --> 00:14:15,286 takes just 6 earth days. 202 00:14:15,288 --> 00:14:17,021 Can you imagine you're just basically tearing 203 00:14:17,023 --> 00:14:19,657 your calendar days off day after day after day really quickly? 204 00:14:19,659 --> 00:14:22,727 Your birthday would be today and then tomorrow. 205 00:14:22,729 --> 00:14:24,162 Happy birthday, again! 206 00:14:24,164 --> 00:14:26,097 Wedding anniversaries, you're constantly forgetting 207 00:14:26,099 --> 00:14:30,568 your wedding anniversary, and it would be hard. 208 00:14:30,570 --> 00:14:33,571 And on this strange and alien world, 209 00:14:33,573 --> 00:14:39,844 explorers would witness sights unlike anything seen before. 210 00:14:39,846 --> 00:14:43,147 In a lot of ways, it really is sort of a science fiction sky, 211 00:14:43,149 --> 00:14:45,917 the kind of things that are envisioned in movies. 212 00:14:45,919 --> 00:14:48,786 You could look up and see the other planets in your sky 213 00:14:48,788 --> 00:14:51,723 much like how we can see our own moon. 214 00:14:51,725 --> 00:14:54,459 You could physically resolve features on the surface 215 00:14:54,461 --> 00:14:58,596 such as continents with your own eyes. 216 00:14:58,598 --> 00:15:03,468 But could this planet be too good to be true? 217 00:15:03,470 --> 00:15:07,705 So we could have a potentially habitable planet 218 00:15:07,707 --> 00:15:09,641 that's really close to its star, 219 00:15:09,643 --> 00:15:12,410 but other issues arise when you have a solar system 220 00:15:12,412 --> 00:15:14,078 that's that compressed, 221 00:15:14,080 --> 00:15:17,715 and one of those is the potential for tidal locking. 222 00:15:20,887 --> 00:15:24,188 Orbiting just a few million miles from the star, 223 00:15:24,190 --> 00:15:30,795 trappist-1e is likely tidally locked with one side 224 00:15:30,797 --> 00:15:34,666 facing the star forever. 225 00:15:34,668 --> 00:15:38,236 So you could imagine a situation where, gosh, it's constant day 226 00:15:38,238 --> 00:15:39,904 and it might just produce something 227 00:15:39,906 --> 00:15:41,739 that's like a scorched earth, 228 00:15:41,741 --> 00:15:43,808 kind of like what we see behind me, 229 00:15:43,810 --> 00:15:46,544 but on the other side, it is constant night, 230 00:15:46,546 --> 00:15:48,246 and so in that case, it might just be, like, 231 00:15:48,248 --> 00:15:51,849 a frozen wasteland. 232 00:15:51,851 --> 00:15:56,854 And trappist-1e's problems get even more extreme. 233 00:15:56,856 --> 00:16:00,325 If you have a permanent day side and a permanent night side, 234 00:16:00,327 --> 00:16:03,261 the night side of the planet is going to get so cold 235 00:16:03,263 --> 00:16:06,764 that everything just freezes out, including the atmosphere. 236 00:16:10,737 --> 00:16:13,504 The gases of trappist-1e's atmosphere 237 00:16:13,506 --> 00:16:15,974 could freeze into solid ice 238 00:16:15,976 --> 00:16:19,877 on the frigid night side of the planet, 239 00:16:19,879 --> 00:16:24,816 and the gases on the day side burn away. 240 00:16:24,818 --> 00:16:31,055 The atmosphere thins and eventually disappears, 241 00:16:31,057 --> 00:16:38,162 and trappist-1e ends up completely inhospitable. 242 00:16:38,164 --> 00:16:41,899 So even though we found maybe a perfect planet around a star, 243 00:16:41,901 --> 00:16:43,634 the type of star and where it's orbiting 244 00:16:43,636 --> 00:16:45,470 could have a really important effect 245 00:16:45,472 --> 00:16:48,106 as to whether or not that planet might be habitable. 246 00:16:50,944 --> 00:16:53,444 Despite its apparent potential, 247 00:16:53,446 --> 00:16:58,549 our future is not in the trappist-1 system. 248 00:16:58,551 --> 00:17:03,621 The search for truly earthlike planets continues. 249 00:17:03,623 --> 00:17:08,126 In the trappist-1 system, we find a very earthlike world, 250 00:17:08,128 --> 00:17:11,362 but the star its orbiting is not very sunlike. 251 00:17:11,364 --> 00:17:14,332 So what we should be looking for, perhaps, 252 00:17:14,334 --> 00:17:17,468 is a earthlike planet around a sunlike star. 253 00:17:19,572 --> 00:17:25,810 To find earth 2.0, we need a sun 2.0. 254 00:17:44,964 --> 00:17:47,365 The milky way... 255 00:17:47,367 --> 00:17:50,701 home to hundreds of billions of stars... 256 00:17:53,006 --> 00:17:57,075 Ranging from dim, explosive red dwarves... 257 00:17:59,179 --> 00:18:02,046 To short-lived blazing giants. 258 00:18:08,088 --> 00:18:13,091 But in the middle are stars like our sun. 259 00:18:13,093 --> 00:18:16,260 Strictly speaking, if we really want earth 2.0, 260 00:18:16,262 --> 00:18:20,498 we need to look for planets around stars like our sun. 261 00:18:20,500 --> 00:18:22,533 Stars like our sun 262 00:18:22,535 --> 00:18:25,470 are calm and stable with long lives... 263 00:18:27,941 --> 00:18:31,175 And the habitable zone lies far enough away 264 00:18:31,177 --> 00:18:35,179 that planets avoid tidal locking. 265 00:18:35,181 --> 00:18:38,783 We stand a much better chance of colonizing a planet 266 00:18:38,785 --> 00:18:41,853 around a sunlike star. 267 00:18:41,855 --> 00:18:46,157 We're hunting for planets in the habitable zone of stars 268 00:18:46,159 --> 00:18:50,828 like our own sun, and we have found worlds there. 269 00:18:55,068 --> 00:19:00,304 Worlds like kepler-452b, 270 00:19:00,306 --> 00:19:04,408 an exoplanet 1,800 light-years away, 271 00:19:04,410 --> 00:19:08,446 orbiting the same type of star as our sun. 272 00:19:10,717 --> 00:19:13,017 You really couldn't ask for a more earthlike orbit 273 00:19:13,019 --> 00:19:14,352 around this star. 274 00:19:14,354 --> 00:19:18,089 The year is about 385 days. We're 365 days. 275 00:19:18,091 --> 00:19:21,792 This really is very much like the earth. 276 00:19:21,794 --> 00:19:25,429 The planet orbits its star at roughly the same distance 277 00:19:25,431 --> 00:19:28,966 as the earth orbits the sun, 278 00:19:28,968 --> 00:19:31,769 and could be very much like home. 279 00:19:33,740 --> 00:19:38,609 Kepler-452b is in the habitable zone of its star, 280 00:19:38,611 --> 00:19:40,745 so if there is liquid water there, 281 00:19:40,747 --> 00:19:45,483 there could be oceans and lakes and rivers and streams 282 00:19:45,485 --> 00:19:48,219 and blue skies and cloudy days. 283 00:19:51,124 --> 00:19:54,692 Sounds nice, but kepler-452b 284 00:19:54,694 --> 00:19:56,727 is a lot larger than earth. 285 00:19:59,866 --> 00:20:04,035 Kepler-452b is a great earth 2.0 candidate, 286 00:20:04,037 --> 00:20:09,207 but it's sort of like earth on steroids. 287 00:20:09,209 --> 00:20:14,111 This world is about 5 times more massive than our own planet 288 00:20:14,113 --> 00:20:17,915 and about 60% wider. 289 00:20:17,917 --> 00:20:22,220 Scientists call large worlds like kepler-452b 290 00:20:22,222 --> 00:20:23,621 super-earths. 291 00:20:27,694 --> 00:20:29,160 These worlds are maybe 292 00:20:29,162 --> 00:20:31,596 1.5 or 2 times the size of the earth, 293 00:20:31,598 --> 00:20:35,499 with maybe as much as 10 times the mass. 294 00:20:35,501 --> 00:20:38,603 Could this super-sized earthlike planet 295 00:20:38,605 --> 00:20:40,972 be our second home? 296 00:20:40,974 --> 00:20:43,140 A planet like this seems to meet 297 00:20:43,142 --> 00:20:45,209 a lot of our standards for an earth 2.0. 298 00:20:45,211 --> 00:20:47,812 It's around a star like our sun. 299 00:20:47,814 --> 00:20:50,915 It's smack-dab in the middle of the habitable zone. 300 00:20:50,917 --> 00:20:53,417 The problem is there are other factors at play. 301 00:20:53,419 --> 00:20:56,087 One of those is simply the mass of the planet. 302 00:21:02,629 --> 00:21:04,762 Kepler-452b's size 303 00:21:04,764 --> 00:21:09,033 has an extreme effect on its gravity. 304 00:21:09,035 --> 00:21:12,970 Because of its incredible mass, the gravity on the surface 305 00:21:12,972 --> 00:21:16,841 is about twice what we feel here on the earth. 306 00:21:18,911 --> 00:21:20,711 That extra gravity 307 00:21:20,713 --> 00:21:24,382 would make colonizing the planet difficult. 308 00:21:24,384 --> 00:21:25,850 Just about any chore you could imagine 309 00:21:25,852 --> 00:21:27,852 doing that you don't like doing on the earth, 310 00:21:27,854 --> 00:21:30,821 you're going to like it even less on a planet like that. 311 00:21:30,823 --> 00:21:33,324 When the garbage can weighs twice as much as it does here 312 00:21:33,326 --> 00:21:35,860 on the earth, that's not going to be very much fun. 313 00:21:35,862 --> 00:21:38,295 Maybe lebron james and I will be okay, 314 00:21:38,297 --> 00:21:42,033 but normal humans, I'm not so sure. 315 00:21:43,436 --> 00:21:47,004 And we could be stuck on the planet's surface. 316 00:21:48,608 --> 00:21:51,242 If you landed on the surface of one of these super-earths, 317 00:21:51,244 --> 00:21:53,678 it'd be pretty easy to get down onto the surface, 318 00:21:53,680 --> 00:21:57,248 but it would be very difficult to get back up. 319 00:21:57,250 --> 00:21:59,383 It's already incredibly difficult 320 00:21:59,385 --> 00:22:00,685 for us to leave the earth. 321 00:22:00,687 --> 00:22:03,621 Think of our giant engines and rockets, 322 00:22:03,623 --> 00:22:05,656 these incredible miracles of engineering 323 00:22:05,658 --> 00:22:07,858 that we need to blast off. 324 00:22:07,860 --> 00:22:12,063 You need twice that to get off of kepler-452b. 325 00:22:15,435 --> 00:22:19,970 And to make matters worse, kepler-452b's atmosphere 326 00:22:19,972 --> 00:22:24,075 is thought to be radically different from earth's. 327 00:22:24,077 --> 00:22:25,943 In some sense, how big the planet is, 328 00:22:25,945 --> 00:22:30,081 how massive it is will determine what its atmosphere is like. 329 00:22:30,083 --> 00:22:32,249 If you have a lot of mass and a lot of gravity, 330 00:22:32,251 --> 00:22:34,285 you can hold onto a lot of air. 331 00:22:34,287 --> 00:22:36,887 You can have a much larger atmosphere, 332 00:22:36,889 --> 00:22:40,491 much thicker, much denser, and higher pressure at the surface. 333 00:22:42,662 --> 00:22:47,531 The thick atmosphere could trap heat from the star. 334 00:22:47,533 --> 00:22:51,035 Surface temperatures become ferociously hot, 335 00:22:51,037 --> 00:22:52,570 and crushing pressures 336 00:22:52,572 --> 00:22:57,074 make the surface completely uninhabitable. 337 00:22:57,076 --> 00:22:59,844 So it's possible this planet has a very thick atmosphere 338 00:22:59,846 --> 00:23:02,546 that's become more of a runaway greenhouse effect. 339 00:23:02,548 --> 00:23:05,116 The planet has gotten hotter and hotter over time. 340 00:23:05,118 --> 00:23:07,118 Maybe instead of finding an earth 2.0, 341 00:23:07,120 --> 00:23:09,687 what we've found is a venus 2.0. 342 00:23:14,627 --> 00:23:18,195 Super-earths may have an appealing name, 343 00:23:18,197 --> 00:23:22,400 but their intense gravity would make them difficult to live on, 344 00:23:22,402 --> 00:23:26,036 and we could not survive in their thick atmospheres. 345 00:23:31,978 --> 00:23:34,945 So far, all the worlds we've found have turned out 346 00:23:34,947 --> 00:23:38,616 to be uninhabitable, 347 00:23:38,618 --> 00:23:44,422 but what if our new home is not a planet? 348 00:23:44,424 --> 00:23:48,192 Earth 2.0 may not be an exoplanet at all. 349 00:23:48,194 --> 00:23:50,494 It might be an exomoon. 350 00:24:09,882 --> 00:24:12,583 We live in a cosmic shooting range 351 00:24:14,654 --> 00:24:17,154 where planets die every day, 352 00:24:19,725 --> 00:24:25,996 but backup planets like our own seem almost impossible to find. 353 00:24:25,998 --> 00:24:30,167 Have we been looking for the wrong thing? 354 00:24:30,169 --> 00:24:32,002 I think there's a pretty good chance 355 00:24:32,004 --> 00:24:35,539 that earth 2.0 might not be a planet per se, 356 00:24:35,541 --> 00:24:39,109 but actually a moon of a giant planet. 357 00:24:39,111 --> 00:24:40,444 The exciting thing about an exomoon 358 00:24:40,446 --> 00:24:42,947 is that they could potentially be habitable. 359 00:24:42,949 --> 00:24:44,148 So is it possible 360 00:24:44,150 --> 00:24:46,083 that as we look at different solar systems, 361 00:24:46,085 --> 00:24:50,321 the real analog for earth 2.0 will turn out to be an exomoon? 362 00:24:56,729 --> 00:24:59,697 2017. 363 00:24:59,699 --> 00:25:02,766 The kepler telescope scanned a sunlike star 364 00:25:02,768 --> 00:25:05,236 8,000 light-years away, 365 00:25:05,238 --> 00:25:07,972 and professor david kipping and his team 366 00:25:07,974 --> 00:25:12,543 watched the transiting exoplanet 367 00:25:12,545 --> 00:25:17,348 kepler-1625b. 368 00:25:17,350 --> 00:25:22,219 Kepler-1625 was one of the many thousands of planets 369 00:25:22,221 --> 00:25:24,221 discovered by kepler, 370 00:25:24,223 --> 00:25:26,891 but what made it different from our perspective 371 00:25:26,893 --> 00:25:29,493 as a moon hunter was that this is a planet 372 00:25:29,495 --> 00:25:32,897 which was jupiter-sized, far away from its star, 373 00:25:32,899 --> 00:25:35,065 and apparently on a near-circular orbit, 374 00:25:35,067 --> 00:25:39,003 so everything that we want for finding exomoons. 375 00:25:43,876 --> 00:25:47,144 The exoplanet kepler-1625b 376 00:25:47,146 --> 00:25:50,681 is an uninhabitable gas giant, like jupiter. 377 00:25:52,785 --> 00:25:56,020 But it is in the habitable zone, 378 00:25:56,022 --> 00:25:59,890 and that means its moons would be, too. 379 00:26:02,028 --> 00:26:06,230 Unfortunately, these exomoons are incredibly hard to see. 380 00:26:09,702 --> 00:26:13,337 The way that kepler finds exoplanets out there 381 00:26:13,339 --> 00:26:16,240 really does relate to the size of the planet, 382 00:26:16,242 --> 00:26:17,841 and for moons, it's much, much more difficult 383 00:26:17,843 --> 00:26:20,978 because it's smaller so it's harder to detect. 384 00:26:20,980 --> 00:26:22,980 Kipping: The largest moon in the solar system 385 00:26:22,982 --> 00:26:24,748 is ganymede around jupiter. 386 00:26:24,750 --> 00:26:27,351 It's about 40% the size of the earth, 387 00:26:27,353 --> 00:26:31,255 and we really very rarely detect planets that small. 388 00:26:31,257 --> 00:26:33,624 So, of course, looking for exomoons 389 00:26:33,626 --> 00:26:36,560 is going to be very, very challenging. 390 00:26:41,100 --> 00:26:43,601 In 2018, the team recruited 391 00:26:43,603 --> 00:26:47,004 the powerful hubble space telescope 392 00:26:47,006 --> 00:26:50,941 and used the data to hunt for the tiny silhouette 393 00:26:50,943 --> 00:26:54,011 of any moons. 394 00:26:54,013 --> 00:26:56,146 If you have an exomoon orbiting a planet, 395 00:26:56,148 --> 00:26:58,148 sometimes it's going to lead the planet 396 00:26:58,150 --> 00:26:59,717 when it transits the star, 397 00:26:59,719 --> 00:27:01,485 and sometimes it's going to trail behind 398 00:27:01,487 --> 00:27:03,020 as it transits the star, 399 00:27:03,022 --> 00:27:05,856 and you see a little bump in the transit dip itself 400 00:27:05,858 --> 00:27:07,558 at different places. 401 00:27:09,395 --> 00:27:12,963 And the team detected the signal... 402 00:27:12,965 --> 00:27:18,469 not one, but two objects orbiting together, 403 00:27:18,471 --> 00:27:23,440 confirmation of the first exomoon ever discovered. 404 00:27:33,052 --> 00:27:35,619 It was an amazing discovery. 405 00:27:35,621 --> 00:27:37,921 I've been looking for exomoons my entire career. 406 00:27:37,923 --> 00:27:40,491 For 10 years, we have been in this quest to try 407 00:27:40,493 --> 00:27:42,893 and find these things. 408 00:27:42,895 --> 00:27:44,228 Caspi: This discovery, 409 00:27:44,230 --> 00:27:47,898 this announcement was absolutely remarkable. 410 00:27:47,900 --> 00:27:49,933 Not only does it mean that we might find 411 00:27:49,935 --> 00:27:52,002 earth twins everywhere in the milky way, 412 00:27:52,004 --> 00:27:53,871 but it gives us something to strive for, 413 00:27:53,873 --> 00:27:55,472 for human exploration. 414 00:28:00,446 --> 00:28:03,247 On this alien exomoon, 415 00:28:03,249 --> 00:28:06,550 the skies would be nothing like earth's. 416 00:28:06,552 --> 00:28:07,851 Visually, I think it would be 417 00:28:07,853 --> 00:28:09,553 an absolutely stunning place to be. 418 00:28:09,555 --> 00:28:12,089 You look up in the sky, and you see this ringed planet 419 00:28:12,091 --> 00:28:14,324 looming huge in the sky. 420 00:28:17,797 --> 00:28:21,265 A world that could be like earth, 421 00:28:21,267 --> 00:28:24,201 only orbiting another planet. 422 00:28:29,942 --> 00:28:34,311 But don't pack your space suit just yet. 423 00:28:34,313 --> 00:28:35,879 Even though the planet and the moon 424 00:28:35,881 --> 00:28:37,614 are potentially the right distance 425 00:28:37,616 --> 00:28:39,383 away from the star that we might imagine 426 00:28:39,385 --> 00:28:41,785 there being liquid water on the surface, 427 00:28:41,787 --> 00:28:45,122 both the moon and the planet are likely gaseous objects 428 00:28:45,124 --> 00:28:47,624 with no solid surface to speak of. 429 00:28:50,096 --> 00:28:53,030 Although the moon probably isn't habitable, 430 00:28:53,032 --> 00:28:55,466 it is an important step for finding worlds 431 00:28:55,468 --> 00:28:59,236 like our own in the galaxy. 432 00:28:59,238 --> 00:29:02,106 If we find exomoons around exoplanets, 433 00:29:02,108 --> 00:29:04,508 that potentially hugely increases 434 00:29:04,510 --> 00:29:07,644 the number of habitable worlds that are out there. 435 00:29:07,646 --> 00:29:09,346 We just need more accurate measurements, 436 00:29:09,348 --> 00:29:10,714 and then all of a sudden, 437 00:29:10,716 --> 00:29:12,983 the universe is going to be full of exomoons. 438 00:29:18,457 --> 00:29:20,290 But these worlds need to be more 439 00:29:20,292 --> 00:29:24,294 than just earth look-alikes. 440 00:29:24,296 --> 00:29:25,696 Everyone gets very excited 441 00:29:25,698 --> 00:29:28,365 when we find earthlike planets around other stars, 442 00:29:28,367 --> 00:29:31,335 but "earthlike" kind of just means how big it is 443 00:29:31,337 --> 00:29:33,537 and whether it can support liquid water 444 00:29:33,539 --> 00:29:35,672 where it is in relation to its star. 445 00:29:35,674 --> 00:29:39,676 All of that is great, but it's just not enough. 446 00:29:42,982 --> 00:29:46,183 A planet's composition could be make-or-break 447 00:29:46,185 --> 00:29:47,951 for our new home... 448 00:29:50,089 --> 00:29:53,423 The difference between the perfect world 449 00:29:53,425 --> 00:29:55,359 and a ticking time bomb. 450 00:30:15,614 --> 00:30:19,950 The hunt for earth 2.0 is still on. 451 00:30:19,952 --> 00:30:23,687 We've examined intense, red dwarf systems... 452 00:30:24,957 --> 00:30:27,858 Massive super-earths, 453 00:30:27,860 --> 00:30:31,495 and alien exomoons 454 00:30:31,497 --> 00:30:36,266 but so far, there's no place like home. 455 00:30:36,268 --> 00:30:38,702 There are all these criteria we have to tick off... 456 00:30:38,704 --> 00:30:40,938 a sunlike star, 457 00:30:40,940 --> 00:30:43,941 an orbit that puts it at about the right temperature, 458 00:30:43,943 --> 00:30:46,944 a solid surface, something that could retain an atmosphere. 459 00:30:48,981 --> 00:30:52,516 But a planet that appears earthlike on the outside 460 00:30:52,518 --> 00:30:55,586 may not be earthlike on the inside. 461 00:30:59,525 --> 00:31:01,625 One of the things that makes our world so unique 462 00:31:01,627 --> 00:31:02,893 is its plate tectonics, 463 00:31:02,895 --> 00:31:04,928 and that actually regulates our climate. 464 00:31:08,000 --> 00:31:11,368 The earth's climate depends on cycles of materials, 465 00:31:11,370 --> 00:31:14,905 like carbon dioxide and water. 466 00:31:14,907 --> 00:31:18,508 Molecules move between the earth's molten interior 467 00:31:18,510 --> 00:31:21,912 and the surface through active plate tectonics 468 00:31:21,914 --> 00:31:23,680 and volcanic eruptions. 469 00:31:25,851 --> 00:31:28,619 These cycles help to regulate the temperature 470 00:31:28,621 --> 00:31:31,054 and composition of the earth's atmosphere. 471 00:31:34,560 --> 00:31:37,361 If we were to find another earthlike planet out there, 472 00:31:37,363 --> 00:31:40,197 and it had geologic activity, that means that at least 473 00:31:40,199 --> 00:31:43,634 it has the means to sustain the carbon cycle 474 00:31:43,636 --> 00:31:45,435 and all of these natural phenomenon 475 00:31:45,437 --> 00:31:50,007 that makes this planet habitable and sustainable. 476 00:31:54,146 --> 00:31:57,581 How can we know what's happening inside a planet? 477 00:31:59,919 --> 00:32:05,389 A clue can be found in vast ranges across our world... 478 00:32:05,391 --> 00:32:07,090 mountains. 479 00:32:13,499 --> 00:32:17,100 Kipping: These topographical features are an indicator 480 00:32:17,102 --> 00:32:20,170 that the planet is alive and there is still processes 481 00:32:20,172 --> 00:32:22,072 happening underneath its surface. 482 00:32:26,879 --> 00:32:28,445 Mountain ranges are created 483 00:32:28,447 --> 00:32:31,715 when a planet's tectonic plates collide, 484 00:32:33,719 --> 00:32:37,120 and even though exoplanets are light-years away, 485 00:32:37,122 --> 00:32:40,657 astronomers could work out whether their surfaces 486 00:32:40,659 --> 00:32:43,660 are smooth or covered in peaks. 487 00:32:47,166 --> 00:32:49,466 Kipping: Those mountain ranges are poking out, 488 00:32:49,468 --> 00:32:52,869 and depending on which rotation the planet is in, 489 00:32:52,871 --> 00:32:55,272 the planet will appear very slightly bigger 490 00:32:55,274 --> 00:32:58,141 or very slightly smaller depending on the silhouette 491 00:32:58,143 --> 00:32:59,643 which is being cast. 492 00:33:03,983 --> 00:33:07,317 These tiny changes in light could be the sign 493 00:33:07,319 --> 00:33:10,454 that an exoplanet is healthy and active. 494 00:33:13,425 --> 00:33:15,492 But we can only use this method 495 00:33:15,494 --> 00:33:19,162 when a planet is in front of its star. 496 00:33:19,164 --> 00:33:22,899 What if astronomers could use starlight itself 497 00:33:22,901 --> 00:33:27,504 to determine the geology of a planet? 498 00:33:27,506 --> 00:33:30,974 We think that planets form at roughly the same sort of time 499 00:33:30,976 --> 00:33:32,442 that stars form, 500 00:33:32,444 --> 00:33:36,113 and they all form from this same giant cloud of material. 501 00:33:38,684 --> 00:33:41,318 And so if you measure the composition of a star, 502 00:33:41,320 --> 00:33:44,154 then it seems reasonable to take those values and assume 503 00:33:44,156 --> 00:33:47,090 they're somewhat similar for the planets as well. 504 00:33:49,962 --> 00:33:52,996 Astronomers can work out what chemical elements 505 00:33:52,998 --> 00:33:56,700 are present in the star, by splitting its light 506 00:33:56,702 --> 00:34:02,072 into different wavelengths, and any planets around that star 507 00:34:02,074 --> 00:34:05,842 will have a similar chemical composition. 508 00:34:05,844 --> 00:34:08,812 Composition is actually a really important part 509 00:34:08,814 --> 00:34:11,548 of whether or not it's actually going to be habitable. 510 00:34:11,550 --> 00:34:14,918 The composition really is its geology. 511 00:34:17,656 --> 00:34:20,123 Rocky exoplanets are all made 512 00:34:20,125 --> 00:34:23,260 from the same basic ingredients... 513 00:34:23,262 --> 00:34:28,331 chemical elements like oxygen, silicon, and aluminum. 514 00:34:28,333 --> 00:34:30,600 Change the balance of ingredients, 515 00:34:30,602 --> 00:34:34,771 and you get very different planets. 516 00:34:34,773 --> 00:34:36,173 If we have some idea 517 00:34:36,175 --> 00:34:38,708 of the composition of a rocky planet, 518 00:34:38,710 --> 00:34:41,344 we can actually use that to give us clues 519 00:34:41,346 --> 00:34:45,682 as to whether a world has or doesn't have plate tectonics. 520 00:34:49,354 --> 00:34:50,987 New research indicates 521 00:34:50,989 --> 00:34:53,990 that exoplanets with too much silicon and sodium 522 00:34:53,992 --> 00:34:58,395 form different types of rock than those on earth, 523 00:34:58,397 --> 00:35:02,866 creating rigid planets where plate tectonics stall 524 00:35:02,868 --> 00:35:08,105 and carbon dioxide builds up with devastating consequences. 525 00:35:10,375 --> 00:35:12,309 Without active geology, we end up with 526 00:35:12,311 --> 00:35:14,945 maybe a venetian atmosphere. 527 00:35:14,947 --> 00:35:17,414 That means there a runaway greenhouse effect. 528 00:35:17,416 --> 00:35:19,149 It's gotten hotter and hotter. 529 00:35:19,151 --> 00:35:21,051 Gases are baked out of the rocks. 530 00:35:21,053 --> 00:35:23,186 There's no way to actually rein them back out, 531 00:35:23,188 --> 00:35:24,955 not a good place for life at all. 532 00:35:29,361 --> 00:35:33,463 At worse, the planet becomes a pressure cooker, 533 00:35:33,465 --> 00:35:36,333 waiting to explode. 534 00:35:36,335 --> 00:35:38,168 If we change the composition of a planet, 535 00:35:38,170 --> 00:35:39,803 it affects its tectonic system. 536 00:35:39,805 --> 00:35:42,572 That entirely changes how a planet loses heat, 537 00:35:42,574 --> 00:35:44,407 and the heat builds up and builds up and builds up, 538 00:35:44,409 --> 00:35:46,943 and then maybe there's a catastrophic overturn 539 00:35:46,945 --> 00:35:48,211 of the crust. 540 00:35:58,557 --> 00:36:01,591 The solid crust of the planet collapses. 541 00:36:04,663 --> 00:36:07,864 Oceans of lava bubble up, 542 00:36:07,866 --> 00:36:13,170 and a greenhouse atmosphere boils the surface... 543 00:36:13,172 --> 00:36:17,107 a violent end to a potential new home. 544 00:36:20,112 --> 00:36:21,778 Clearly, you need to know 545 00:36:21,780 --> 00:36:23,046 about the composition of those planets 546 00:36:23,048 --> 00:36:24,915 before you can start making statements 547 00:36:24,917 --> 00:36:27,884 about how habitable those worlds truly are. 548 00:36:30,789 --> 00:36:33,757 But there's something else that a planet needs 549 00:36:33,759 --> 00:36:37,293 to be earthlike, an invisible shield 550 00:36:37,295 --> 00:36:42,098 that protects it from the dangers of space, 551 00:36:42,100 --> 00:36:45,602 providing warmth and life-giving water... 552 00:36:45,604 --> 00:36:47,137 an atmosphere. 553 00:37:05,224 --> 00:37:10,493 The hunt for earth 2.0 has turned up plenty of planets, 554 00:37:10,495 --> 00:37:13,230 but for a planet to be like earth, 555 00:37:13,232 --> 00:37:17,167 it has to check a lot of boxes. 556 00:37:17,169 --> 00:37:20,170 If you're really looking for earth 2.0, 557 00:37:20,172 --> 00:37:21,871 then you're gonna have to find a planet 558 00:37:21,873 --> 00:37:24,641 that's the same mass and size as earth, 559 00:37:24,643 --> 00:37:26,776 orbiting a sunlike star 560 00:37:26,778 --> 00:37:30,914 at about the same distance with a similar atmosphere 561 00:37:30,916 --> 00:37:35,085 and a lot of surface water that's in liquid form. 562 00:37:35,087 --> 00:37:36,319 Good luck. 563 00:37:40,359 --> 00:37:42,292 And on the list of requirements, 564 00:37:42,294 --> 00:37:47,564 an exoplanet's atmosphere is critical. 565 00:37:47,566 --> 00:37:50,467 It protects the planet from huge temperature swings. 566 00:37:50,469 --> 00:37:53,236 It protects the planet from small asteroid impacts. 567 00:37:53,238 --> 00:37:55,572 It protects the planet from dangerous radiation 568 00:37:55,574 --> 00:37:57,274 from space and from the star. 569 00:37:57,276 --> 00:38:00,010 It is almost literally a shield around the planet, 570 00:38:00,012 --> 00:38:03,747 protecting us from outer space. 571 00:38:03,749 --> 00:38:07,917 But to also has to be the right kind of atmosphere. 572 00:38:11,923 --> 00:38:15,258 Get it wrong, and the planet can have crushing, 573 00:38:15,260 --> 00:38:17,694 boiling conditions on the surface. 574 00:38:20,198 --> 00:38:22,032 Look at our own solar system. 575 00:38:22,034 --> 00:38:23,867 The sun's habitable zone includes 576 00:38:23,869 --> 00:38:26,903 three different planets, venus, earth and mars, 577 00:38:26,905 --> 00:38:29,406 but mars has a thin atmosphere and is too cold. 578 00:38:29,408 --> 00:38:32,242 Venus has too thick of an atmosphere and is too hot. 579 00:38:32,244 --> 00:38:35,445 We're the only planet that happens to be just right. 580 00:38:40,952 --> 00:38:43,753 So far, astronomers have mostly had to guess 581 00:38:43,755 --> 00:38:48,091 if these exoplanets have atmospheres, 582 00:38:48,093 --> 00:38:52,762 but now we're looking for them directly, 583 00:38:52,764 --> 00:38:54,998 searching for earthlike atmospheres 584 00:38:55,000 --> 00:38:57,400 around earthlike planets. 585 00:38:59,638 --> 00:39:02,372 This is incredibly hard to do, 586 00:39:02,374 --> 00:39:05,675 so in order to look at the details of these atmospheres 587 00:39:05,677 --> 00:39:07,777 in the glare of the star 588 00:39:07,779 --> 00:39:11,915 requires incredibly precise technology 589 00:39:11,917 --> 00:39:13,750 and precise measurements. 590 00:39:16,154 --> 00:39:19,122 Astronomers detect atmospheres by watching 591 00:39:19,124 --> 00:39:22,025 a planet pass in front of the star. 592 00:39:24,363 --> 00:39:28,264 A small fraction of light shines around the edge of the planet 593 00:39:28,266 --> 00:39:31,301 and through the atmosphere 594 00:39:31,303 --> 00:39:35,271 where molecules like water, hydrogen, and carbon dioxide 595 00:39:35,273 --> 00:39:41,211 absorb particular wavelengths of light from the star. 596 00:39:41,213 --> 00:39:43,780 If we can see the light of the star 597 00:39:43,782 --> 00:39:46,216 shining through around the planet, 598 00:39:46,218 --> 00:39:48,718 we can maybe deduce some information about 599 00:39:48,720 --> 00:39:50,320 does it have an atmosphere? 600 00:39:50,322 --> 00:39:51,821 What are the properties of that atmosphere? 601 00:39:51,823 --> 00:39:54,991 How hot is it? What's it made out of? 602 00:39:54,993 --> 00:39:56,926 That's how we'll be able to determine 603 00:39:56,928 --> 00:39:59,796 if things in the atmosphere might indicate 604 00:39:59,798 --> 00:40:02,399 that the surface is hospitable to life. 605 00:40:04,803 --> 00:40:07,937 So far, we haven't seen any exoplanets 606 00:40:07,939 --> 00:40:11,174 with atmospheres that we could live in, 607 00:40:11,176 --> 00:40:13,443 but that's about to change. 608 00:40:19,751 --> 00:40:21,718 Scientists around the world 609 00:40:21,720 --> 00:40:24,754 are working on the next generation of telescopes 610 00:40:24,756 --> 00:40:29,159 to revolutionize exoplanet astronomy. 611 00:40:29,161 --> 00:40:31,094 We've got some ideas, and some telescopes 612 00:40:31,096 --> 00:40:34,097 that are gonna be built probably in the next couple of decades 613 00:40:34,099 --> 00:40:37,367 will be big enough, will be sophisticated enough 614 00:40:37,369 --> 00:40:39,736 to be able to see this sort of thing. 615 00:40:41,406 --> 00:40:46,409 Missions like the james webb space telescope... 616 00:40:46,411 --> 00:40:49,579 seven times more powerful than hubble, 617 00:40:49,581 --> 00:40:53,583 it should allow us to see the atmospheres of planets 618 00:40:53,585 --> 00:40:55,685 across the galaxy 619 00:40:55,687 --> 00:41:01,858 and be a tool that finally finds a second earth. 620 00:41:01,860 --> 00:41:04,427 The key things we'd be looking for in these atmospheres 621 00:41:04,429 --> 00:41:07,764 are in the infrared part of the electromagnetic spectrum, 622 00:41:07,766 --> 00:41:11,468 which is where webb is designed to work. 623 00:41:11,470 --> 00:41:13,136 The james webb space telescope is, 624 00:41:13,138 --> 00:41:17,540 I believe, going to be the next really critical mission 625 00:41:17,542 --> 00:41:22,946 to help us in our search for potentially earthlike planets. 626 00:41:26,718 --> 00:41:31,721 We're still searching for that perfect earth twin, 627 00:41:31,723 --> 00:41:35,058 and every day, 628 00:41:35,060 --> 00:41:38,461 we get closed to finding it. 629 00:41:38,463 --> 00:41:42,899 30 years ago, we had zero exoplanets. 630 00:41:42,901 --> 00:41:45,668 Today, we know of thousands. 631 00:41:45,670 --> 00:41:48,538 With the next generation of instruments, 632 00:41:48,540 --> 00:41:51,541 we're going to uncover tens of thousands, 633 00:41:51,543 --> 00:41:56,679 hundreds of thousands, even millions of exoplanets. 634 00:41:56,681 --> 00:42:00,984 All with the ultimate aim of leaving earth, 635 00:42:00,986 --> 00:42:06,155 a civilization spread across the stars. 636 00:42:06,157 --> 00:42:08,191 One of the things I love about being a human 637 00:42:08,193 --> 00:42:10,493 is the fact that I'm born with this curiosity. 638 00:42:10,495 --> 00:42:14,230 This curiosity drives us to explore, explore earth, 639 00:42:14,232 --> 00:42:18,167 explore our solar system and beyond into the galaxy. 640 00:42:18,169 --> 00:42:21,371 We'll be learning about these planets for a long time. 641 00:42:21,373 --> 00:42:23,873 We have just started this journey. 51043