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These are the user uploaded subtitles that are being translated: 1 00:00:06,440 --> 00:00:10,080 For an instrument first developed as recently as the 17th century, 2 00:00:10,160 --> 00:00:12,281 the telescope has travelled a long way. 3 00:00:19,041 --> 00:00:22,961 The latest version of the once humble telescope will be going a lot farther. 4 00:00:24,522 --> 00:00:28,362 Carrying us ever closer to the first light that ever bathed the universe 5 00:00:28,442 --> 00:00:29,522 in which we live. 6 00:01:22,767 --> 00:01:25,807 Generational change is part and parcel of our lives. 7 00:01:26,207 --> 00:01:28,207 In terms of space exploration, 8 00:01:28,287 --> 00:01:31,527 the Hubble Space Telescope has been doing its extraordinary work 9 00:01:31,607 --> 00:01:33,568 for a generation now. 10 00:01:33,648 --> 00:01:35,888 And it's time to hand over the reins. 11 00:01:54,329 --> 00:01:57,170 What we've reached is the limit of Hubble's vision. 12 00:01:57,250 --> 00:01:58,890 As amazing as Hubble has been, 13 00:01:58,970 --> 00:02:01,490 we've come up against the immutable reality 14 00:02:01,570 --> 00:02:04,450 that Hubble can't, in fact, see everything. 15 00:02:15,251 --> 00:02:17,771 Galileo, Herschel, Hubble: 16 00:02:17,851 --> 00:02:20,772 our knowledge of space is marked by some of the greatest names 17 00:02:20,852 --> 00:02:22,972 in the human history of stargazing. 18 00:02:31,173 --> 00:02:33,133 But who was James Webb? 19 00:02:33,733 --> 00:02:37,293 His name is attached to the James Webb Space Telescope, 20 00:02:37,373 --> 00:02:39,253 which will soon be helping us understand 21 00:02:39,333 --> 00:02:42,294 what lies beyond even the amazing reach of Hubble. 22 00:02:57,175 --> 00:03:00,655 Originally called the Next Generation Space Telescope, 23 00:03:00,735 --> 00:03:05,496 Hubble's successor was renamed in 2002 to honor James E. Webb, 24 00:03:05,576 --> 00:03:10,456 who ran NASA from February 1961 to October 1968. 25 00:03:34,738 --> 00:03:38,858 Those dates, of course, put Webb at the heart of the American space program, 26 00:03:38,938 --> 00:03:41,019 and the moon landing in particular. 27 00:03:41,099 --> 00:03:43,699 But that was not Webb's sole preoccupation. 28 00:03:47,139 --> 00:03:50,019 Webb's energy encompassed robotic spacecraft, 29 00:03:50,099 --> 00:03:51,780 probes to Mars and Venus 30 00:03:51,860 --> 00:03:56,620 and, in 1965, his advocacy of a Large Space Telescope. 31 00:03:56,700 --> 00:03:59,180 He was, in other words, a man of vision. 32 00:04:46,264 --> 00:04:49,305 The James Webb Space Telescope is nearing completion, 33 00:04:49,385 --> 00:04:52,465 in readiness for a scheduled launch in October 2018. 34 00:04:53,065 --> 00:04:58,585 By a happy coincidence, exactly 50 years since James Webb's tenure at NASA ended. 35 00:05:08,506 --> 00:05:13,267 Its aim is modest: to study every phase in the history of the universe. 36 00:05:18,667 --> 00:05:20,867 Several major agencies have collaborated 37 00:05:20,947 --> 00:05:23,708 in the creation of the James Webb Space Telescope. 38 00:05:24,388 --> 00:05:27,668 NASA's Goddard Space Flight Center is at the hub. 39 00:05:27,748 --> 00:05:32,268 ESA will provide the launch vehicle, the ultra-reliable Ariane 5 rocket. 40 00:05:32,908 --> 00:05:35,109 Canada's Space Agency is involved, 41 00:05:35,189 --> 00:05:37,949 as is the Space Telescope Science Institute, 42 00:05:38,349 --> 00:05:40,789 while Northrop Grumman is the chief contractor. 43 00:05:50,950 --> 00:05:53,550 The Webb will be wonderful for the astronomy community. 44 00:05:53,870 --> 00:05:58,191 Not only will it give them the kinds of wonderful resolution 45 00:05:58,271 --> 00:06:00,551 we have with Hubble that you can get above the atmosphere, 46 00:06:00,631 --> 00:06:04,271 but it's gonna bring them access to a wave length region 47 00:06:04,351 --> 00:06:06,231 where many of them have not worked before. 48 00:06:12,832 --> 00:06:14,872 We have a telescope that's far more powerful 49 00:06:14,952 --> 00:06:16,952 than anything that we have had before, 50 00:06:17,592 --> 00:06:20,553 working at infrared wavelengths, which you can't see well from the ground. 51 00:06:21,033 --> 00:06:24,553 And that will enable us to see things from the most distant universe 52 00:06:24,633 --> 00:06:26,313 that we can only guess at 53 00:06:26,393 --> 00:06:28,913 to things at the outer solar system that we can only guess at. 54 00:06:33,234 --> 00:06:35,674 The Webb is gonna be such a powerful telescope. 55 00:06:35,754 --> 00:06:36,754 It's going to be like the Hubble 56 00:06:37,514 --> 00:06:39,114 and, in the case of the Hubble, 57 00:06:39,194 --> 00:06:43,314 probably more than half of the greatest observations, 58 00:06:43,394 --> 00:06:46,675 discoveries that the Hubble made, were things that people didn't anticipate. 59 00:06:46,755 --> 00:06:48,315 I expect the same for the Webb. 60 00:06:59,196 --> 00:07:01,516 The James Webb Space Telescope's mission duration 61 00:07:01,596 --> 00:07:03,556 is a planned 10 years, 62 00:07:03,636 --> 00:07:06,677 during which it has a number of specific goals to accomplish. 63 00:07:07,917 --> 00:07:09,877 It will search for the first galaxies, 64 00:07:11,037 --> 00:07:13,077 determine how galaxies were formed, observe the formation of stars, 65 00:07:17,918 --> 00:07:20,598 and measure the properties of planetary systems, 66 00:07:20,678 --> 00:07:24,718 both physical and chemical, including our own Solar System. 67 00:07:50,280 --> 00:07:53,001 Not least of all, the Webb will carry on the task 68 00:07:53,081 --> 00:07:56,921 that underlies so much of humankind's activity in space: 69 00:07:57,001 --> 00:08:01,521 investigating the potential for life in other far-flung places. 70 00:08:37,044 --> 00:08:41,525 The 6,200 kilogram space-based element of the Webb will not orbit Earth, 71 00:08:41,605 --> 00:08:42,925 as Hubble has been doing. 72 00:08:43,405 --> 00:08:44,925 Instead it will orbit the Sun. 73 00:08:49,685 --> 00:08:53,286 To do so it must first travel 1.5 million kilometers, 74 00:08:53,366 --> 00:08:55,806 a 30-day journey to L2, 75 00:08:55,886 --> 00:09:00,006 the Lagrangian point at which the gravitational forces of Sun and Earth 76 00:09:00,086 --> 00:09:01,286 are roughly equivalent. 77 00:09:13,688 --> 00:09:15,648 Each orbit will take six months 78 00:09:15,728 --> 00:09:19,648 and keep the JWST out of the shadow of both Earth and Sun. 79 00:09:45,650 --> 00:09:49,371 Its trajectory also makes 24/7 communications possible. 80 00:10:07,452 --> 00:10:10,733 The Webb will stay in line with Earth as it moves around the Sun. 81 00:10:11,573 --> 00:10:12,533 And that is because, 82 00:10:12,613 --> 00:10:16,173 while the James Webb Space Telescope is looking for first light, 83 00:10:16,253 --> 00:10:19,213 its first task is to find darkness: 84 00:10:19,293 --> 00:10:22,014 the condition in which it can operate at its best. 85 00:10:34,255 --> 00:10:35,695 Three main component systems 86 00:10:35,775 --> 00:10:38,975 make up the space-based James Webb Space Telescope: 87 00:10:39,535 --> 00:10:42,815 an Integrated Science Instrument Model, ISM, 88 00:10:42,895 --> 00:10:45,096 the Optical Telescope Element, OTE, 89 00:10:45,176 --> 00:10:46,936 and the Spacecraft element. 90 00:11:06,977 --> 00:11:10,578 The key to the JWST's enhanced vision is its primary mirror, 91 00:11:10,658 --> 00:11:13,138 which measures 6.5 meters across. 92 00:11:14,018 --> 00:11:16,698 It comprises 18 segments made of beryllium, 93 00:11:16,778 --> 00:11:19,138 the lightest of the alkaline earth metals. 94 00:11:23,099 --> 00:11:25,819 A five-layer sunshield the size of a tennis court 95 00:11:25,899 --> 00:11:29,579 will protect the JWST's dazzling array of specialist technology. 96 00:11:33,660 --> 00:11:38,380 As this orbiting infrared observatory continues the work begun by Hubble. 97 00:11:44,421 --> 00:11:49,181 On board are a near-infrared camera, a near-infrared spectrograph, 98 00:11:49,261 --> 00:11:52,581 a mid-infrared instrument, a near-infrared imager, 99 00:11:52,661 --> 00:11:54,942 and a slitless spectrograph. 100 00:12:02,022 --> 00:12:03,902 The NIRSpec has microshutters 101 00:12:03,982 --> 00:12:07,623 which will make it possible to observe up to 100 objects simultaneously. 102 00:12:20,584 --> 00:12:22,384 The Webb's cameras and spectrometers 103 00:12:22,464 --> 00:12:25,544 are capable of detecting extremely faint signals, 104 00:12:25,624 --> 00:12:30,025 a crucial factor in its attempt to see as far back as first light. 105 00:12:53,787 --> 00:12:56,147 While NASA busies itself with James Webb, 106 00:12:56,227 --> 00:13:00,507 its European counterpart, ESA, is hard at work on another, related mission 107 00:13:00,587 --> 00:13:02,907 with a much more famous name attached to it. 108 00:13:03,748 --> 00:13:08,588 Euclid is named for the Alexandrian Greek whose geometrical study, the elements, 109 00:13:08,668 --> 00:13:12,268 formed the basis of our mathematical thinking for almost two millennia. 110 00:13:13,708 --> 00:13:18,829 What we want is, actually, to continue our successful program 111 00:13:18,909 --> 00:13:25,709 which is actually providing the cutting edge space science, 112 00:13:26,190 --> 00:13:29,270 meeting the challenges of worldwide research. 113 00:13:30,550 --> 00:13:34,110 But where the original Euclid worked only with ruler and compass, 114 00:13:34,190 --> 00:13:38,511 his namesake in space will have much more sophisticated instruments in its locker. 115 00:13:40,671 --> 00:13:43,991 Like the Webb, Euclid boasts a modest mission: 116 00:13:44,071 --> 00:13:46,631 to map the geometry of the dark universe. 117 00:13:47,511 --> 00:13:51,232 Over a period of some six years it will look back over the entire time 118 00:13:51,312 --> 00:13:54,792 in which dark energy has contributed to the accelerating expansion 119 00:13:54,872 --> 00:13:55,992 of the universe. 120 00:13:57,872 --> 00:14:00,272 Scientists tell us that what we can see 121 00:14:00,352 --> 00:14:03,033 accounts for less than 5% of what is there. 122 00:14:03,713 --> 00:14:06,873 The rest is made up of dark matter, some 20%, 123 00:14:06,953 --> 00:14:08,913 and the remainder, of dark energy. 124 00:14:11,273 --> 00:14:14,034 They act in contradictory ways. 125 00:14:14,114 --> 00:14:17,914 Dark matter acts through gravity to play its role in forming galaxies 126 00:14:17,994 --> 00:14:20,474 and slowing the rate of expansion of the universe. 127 00:14:20,874 --> 00:14:23,715 Dark energy, on the other hand, defeats gravity 128 00:14:23,795 --> 00:14:26,835 and thus encourages acceleration of that expansion. 129 00:14:31,595 --> 00:14:35,596 The Euclid Consortium, part of ESA's "Cosmic Vision" program, 130 00:14:35,676 --> 00:14:40,156 brings together 1,000 scientists from 100 institutes in 14 countries, 131 00:14:40,236 --> 00:14:43,236 with added input from NASA in the United States. 132 00:14:45,156 --> 00:14:50,077 In 2013 Italy's Thales Alenia Space group was named as prime contractor, 133 00:14:50,157 --> 00:14:53,637 with Airbus in France responsible for the payload module. 134 00:14:59,518 --> 00:15:01,238 On board Euclid's payload module 135 00:15:01,318 --> 00:15:03,958 will be a telescope 1.2 meters in diameter, 136 00:15:04,318 --> 00:15:08,318 a visible light camera and a near-infrared camera and spectrometer. 137 00:15:13,039 --> 00:15:16,799 Euclid will undergo its critical design review in 2017, 138 00:15:16,879 --> 00:15:21,320 with its launch planned for December 2020 from Kourou in French Guiana. 139 00:15:24,880 --> 00:15:28,920 Like the JWST, it will orbit around the L2 point. 140 00:15:34,721 --> 00:15:37,201 Channeling the thinker whose name it bears, 141 00:15:37,281 --> 00:15:41,681 Euclid will be looking for genuine insight into the evolution of cosmic structures. 142 00:15:43,601 --> 00:15:47,522 Investigating the nature of dark energy, dark matter and gravity, 143 00:15:47,882 --> 00:15:51,762 it will track their observational signatures on the geometry of the universe 144 00:15:51,842 --> 00:15:54,442 and on the cosmic history of structure formation. 145 00:15:57,643 --> 00:16:00,043 Euclid will deploy two key systems: 146 00:16:00,123 --> 00:16:05,883 weak gravitational lensing, or WL, and baryonic acoustic oscillations, BAO. 147 00:16:07,524 --> 00:16:12,244 WL examines how background galaxies are disturbed by foreground dark matter, 148 00:16:12,604 --> 00:16:15,084 and measures modifications in the shape of galaxies 149 00:16:15,164 --> 00:16:18,484 brought on by the gravitational lensing of dark matter. 150 00:16:20,205 --> 00:16:22,645 BAO reveals the wiggle patterns 151 00:16:22,725 --> 00:16:25,125 which help us gauge the expansion of the universe, 152 00:16:25,205 --> 00:16:28,325 revealing the three-dimensional distribution of structures 153 00:16:28,405 --> 00:16:33,246 by means of the spectroscopic redshifts of galaxies and galaxy clusters. 154 00:16:34,286 --> 00:16:36,046 Putting it more simply, perhaps, 155 00:16:36,126 --> 00:16:40,526 Euclid's task, made easier by its unprecedented accuracy and stability, 156 00:16:40,606 --> 00:16:45,687 is to map the shape, position and movements of two billion galaxies, 157 00:16:46,167 --> 00:16:47,967 or one-third of the sky. 158 00:16:59,688 --> 00:17:05,129 Even more excitingly, JWST is not the only star performer, 159 00:17:05,209 --> 00:17:07,169 pardon the pun, on the horizon. 160 00:17:07,729 --> 00:17:10,649 In 2016 NASA confirmed the decision to go ahead 161 00:17:10,729 --> 00:17:15,769 with its Wide Field Infrared Survey Telescope, or WFIRST for short. 162 00:17:18,170 --> 00:17:21,890 WFIRST is a NASA observatory that has the top ranking 163 00:17:21,970 --> 00:17:25,370 of the National Academy of Sciences to launch in the 2020's. 164 00:17:26,130 --> 00:17:30,651 It has the same image precision and power as the Hubble space telescope 165 00:17:31,291 --> 00:17:34,531 but with 100 times the area of sky that it views. 166 00:17:34,611 --> 00:17:36,211 Looking at a large fraction of the sky 167 00:17:36,291 --> 00:17:38,011 allows you to get a more complete accounting, 168 00:17:38,091 --> 00:17:40,572 for example, the stars in the Large Magellanic Cloud, 169 00:17:40,652 --> 00:17:42,412 which is the nearest galaxy to us, 170 00:17:42,492 --> 00:17:44,452 or the stars in the Galactic Bulge. 171 00:17:44,532 --> 00:17:46,612 So, you can do a much more complete accounting 172 00:17:46,692 --> 00:17:48,052 in a much shorter amount of time. 173 00:17:54,093 --> 00:17:58,453 This new observatory will offer astrophysicists the best of both worlds 174 00:17:58,533 --> 00:18:03,614 by casting its eye both wide and deep as it seeks to shed light on dark energy, 175 00:18:03,694 --> 00:18:06,214 exoplanets and cosmic acceleration. 176 00:18:34,816 --> 00:18:38,057 Surveying large areas in near-infrared light, 177 00:18:38,137 --> 00:18:41,777 a single image from WFIRST will have all the depth and sharpness 178 00:18:41,857 --> 00:18:43,737 to which Hubble has accustomed us, 179 00:18:43,817 --> 00:18:46,417 but will cover 100 times the area. 180 00:18:46,777 --> 00:18:50,778 In fact a single image will encompass as many as a million galaxies. 181 00:19:01,579 --> 00:19:03,859 The new telescope's work will slip into the groove 182 00:19:03,939 --> 00:19:06,979 already made by Kepler, the Sloan Digital Survey 183 00:19:07,059 --> 00:19:10,619 and TESS, the Transit Exoplanet Survey Satellite. 184 00:19:11,259 --> 00:19:15,460 WFIRST will use microlensing rather than the transit method of detection. 185 00:19:19,540 --> 00:19:22,540 It will employ a 2.4m diameter telescope 186 00:19:22,620 --> 00:19:25,221 provided by the National Reconnaissance Office, 187 00:19:25,301 --> 00:19:28,181 but the best-of-both-worlds part of the WFIRST story 188 00:19:28,261 --> 00:19:29,941 comes with the coronagraph 189 00:19:30,021 --> 00:19:33,301 which NASA has been able to add to its instrumental array. 190 00:19:39,022 --> 00:19:42,662 This is a means of dimming the light from a so-called host star 191 00:19:42,942 --> 00:19:45,983 in order to see better the planet or planets orbiting it. 192 00:19:54,103 --> 00:19:57,904 And that is highly significant if we remember that the host star 193 00:19:57,984 --> 00:20:02,264 may be up to a billion times brighter than any exoplanet identified. 194 00:20:06,504 --> 00:20:10,105 If successful, the coronagraph technique will make it much easier 195 00:20:10,185 --> 00:20:14,025 to determine the chemical composition of planetary atmospheres. 196 00:20:17,385 --> 00:20:20,706 WFIRST will be able to use a unique deformable telescope 197 00:20:20,786 --> 00:20:22,066 controlled by computer. 198 00:20:22,746 --> 00:20:26,266 This first mission, due for launch in the mid-2020's, 199 00:20:26,346 --> 00:20:29,426 being what is called a technology demonstration, 200 00:20:29,506 --> 00:20:31,226 laying down a scientific marker 201 00:20:31,306 --> 00:20:35,387 for future missions to go in even more determined pursuit 202 00:20:35,467 --> 00:20:39,587 of life beyond the confines of our own Solar System. 203 00:20:53,828 --> 00:20:56,149 While all of this is going on in space, 204 00:20:56,229 --> 00:20:59,669 here on Earth another agency will be tackling the question of dark matter 205 00:20:59,749 --> 00:21:01,029 from yet another angle. 206 00:21:04,749 --> 00:21:06,189 At CERN in Geneva, 207 00:21:06,269 --> 00:21:10,270 the Large Hadron Collider is now running at full power for the first time. 208 00:21:12,670 --> 00:21:16,470 The very exciting and intriguing possibility 209 00:21:16,550 --> 00:21:21,071 that in addition to gravity there might be a new force 210 00:21:21,151 --> 00:21:25,231 between our visible matter and dark matter 211 00:21:25,671 --> 00:21:31,592 which is transmitted by a new photon-like particle, 212 00:21:31,672 --> 00:21:36,152 which we call dark photons or heavy photon or para-photons, 213 00:21:36,232 --> 00:21:38,872 there are many different names for this particle. 214 00:21:38,952 --> 00:21:43,073 This experiment, its apparatus, which is about 30 meters long, 215 00:21:43,153 --> 00:21:49,153 and the main idea is that we search for so-called invisible decay of dark photons, 216 00:21:49,233 --> 00:21:53,314 and these particles could be quite light, below 1 GeV. 217 00:21:53,394 --> 00:21:54,594 And what is most important 218 00:21:54,674 --> 00:22:00,034 that these particles could be searched for at low energy experiment. 219 00:22:00,114 --> 00:22:01,874 With fixed-target experiment. 220 00:22:02,234 --> 00:22:03,314 So what you see here 221 00:22:03,394 --> 00:22:05,795 is the beam pipe where the beam is coming. 222 00:22:06,275 --> 00:22:09,275 The electrons are deflected by two magnets, 223 00:22:09,355 --> 00:22:12,515 which are about 50 meters upstream. 224 00:22:12,595 --> 00:22:14,755 The purpose of that is really we need to be sure 225 00:22:14,835 --> 00:22:17,796 that we get here are electron of 100 GeV. 226 00:22:18,236 --> 00:22:21,916 So, in this magnet when the electrons are deflected 227 00:22:21,996 --> 00:22:23,996 you generate synchrotron radiation, 228 00:22:24,076 --> 00:22:26,596 and this we detect with this detector here. 229 00:22:33,037 --> 00:22:36,677 So, the idea is when the high energy electron 230 00:22:36,757 --> 00:22:40,598 collide with the active target, which is electro-magnetic colorimeter, 231 00:22:40,678 --> 00:22:45,278 it creates, in this high energy collision with a nuclei, 232 00:22:45,958 --> 00:22:50,239 create dark photons which carry away from the setup... 233 00:22:51,359 --> 00:22:53,879 a significant fraction of the primary energy. 234 00:22:53,959 --> 00:22:57,399 So the experimental signature of the existence of a prime 235 00:22:57,479 --> 00:23:00,279 is an event with such missing energy, 236 00:23:00,359 --> 00:23:03,520 and we search for this event with this setup. 237 00:23:07,160 --> 00:23:11,240 Might its scientists be able to replicate dark matter itself? 23479

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