1 00:00:15,570 --> 00:00:18,330 Space, the final frontier. 2 00:00:20,370 --> 00:00:23,826 I first heard these words when I was just six years old, 3 00:00:23,850 --> 00:00:26,106 and I was completely inspired. 4 00:00:26,130 --> 00:00:28,506 I wanted to explore strange new worlds. 5 00:00:28,530 --> 00:00:30,026 I wanted to seek out new life. 6 00:00:30,050 --> 00:00:33,250 I wanted to see everything that the universe had to offer. 7 00:00:34,330 --> 00:00:38,026 And those dreams, those words, they took me on a journey, 8 00:00:38,050 --> 00:00:39,506 a journey of discovery, 9 00:00:39,530 --> 00:00:41,706 through school, through university, 10 00:00:41,730 --> 00:00:45,170 to do a PhD and finally to become a professional astronomer. 11 00:00:45,610 --> 00:00:48,026 I learned that the reality was 12 00:00:48,050 --> 00:00:51,210 I wouldn't be piloting a starship anytime soon. 13 00:00:52,450 --> 00:00:57,066 But I also learned that the universe is strange, wonderful and vast, 14 00:00:57,090 --> 00:00:59,890 actually too vast to be explored by spaceship. 15 00:01:00,730 --> 00:01:04,090 And so I turned my attention to astronomy, to using telescopes. 16 00:01:04,850 --> 00:01:07,626 Now, I show you before you an image of the night sky. 17 00:01:07,650 --> 00:01:09,570 You might see it anywhere in the world. 18 00:01:10,223 --> 00:01:14,010 And all of these stars are part of our local galaxy, the Milky Way. 19 00:01:14,570 --> 00:01:17,205 If you were to go to a darker part of the sky, 20 00:01:17,229 --> 00:01:19,523 a nice dark site, perhaps in the desert, 21 00:01:19,547 --> 00:01:21,988 you might see the center of our Milky Way galaxy 22 00:01:22,012 --> 00:01:24,646 spread out before you, hundreds of billions of stars. 23 00:01:25,540 --> 00:01:27,116 And it's a very beautiful image. 24 00:01:27,140 --> 00:01:28,291 It's colorful. 25 00:01:28,315 --> 00:01:31,029 And again, this is just a local corner of our universe. 26 00:01:31,430 --> 00:01:34,522 You can see there's a sort of strange dark dust across it. 27 00:01:34,546 --> 00:01:36,266 Now, that is local dust 28 00:01:36,290 --> 00:01:38,946 that's obscuring the light of the stars. 29 00:01:38,970 --> 00:01:40,546 But we can do a pretty good job. 30 00:01:40,570 --> 00:01:44,026 Just with our own eyes, we can explore our little corner of the universe. 31 00:01:44,050 --> 00:01:45,386 It's possible to do better. 32 00:01:45,410 --> 00:01:49,170 You can use wonderful telescopes like the Hubble Space Telescope. 33 00:01:49,730 --> 00:01:51,906 Now, astronomers have put together this image. 34 00:01:51,930 --> 00:01:53,826 It's called the Hubble Deep Field, 35 00:01:53,850 --> 00:01:58,186 and they've spent hundreds of hours observing just a tiny patch of the sky 36 00:01:58,210 --> 00:02:00,610 no larger than your thumbnail held at arm's length. 37 00:02:01,050 --> 00:02:02,306 And in this image 38 00:02:02,330 --> 00:02:03,986 you can see thousands of galaxies, 39 00:02:04,010 --> 00:02:07,466 and we know that there must be hundreds of millions, billions of galaxies 40 00:02:07,490 --> 00:02:08,866 in the entire universe, 41 00:02:08,890 --> 00:02:11,546 some like our own and some very different. 42 00:02:11,570 --> 00:02:14,226 So you think, OK, well, I can continue this journey. 43 00:02:14,250 --> 00:02:16,946 This is easy. I can just use a very powerful telescope 44 00:02:16,970 --> 00:02:18,770 and just look at the sky, no problem. 45 00:02:19,290 --> 00:02:22,886 It's actually really missing out if we just do that. 46 00:02:22,910 --> 00:02:25,646 Now, that's because everything I've talked about so far 47 00:02:25,670 --> 00:02:29,567 is just using the visible spectrum, just the thing that your eyes can see, 48 00:02:29,591 --> 00:02:32,951 and that's a tiny, tiny slice of what the universe has to offer us. 49 00:02:33,925 --> 00:02:38,147 There's also two very important problems with using visible light. 50 00:02:38,850 --> 00:02:41,726 The first is that dust that I mentioned earlier. 51 00:02:41,750 --> 00:02:44,686 The dust stops the visible light from getting to us. 52 00:02:44,710 --> 00:02:49,396 So as we look deeper into the universe, we see less light. 53 00:02:49,420 --> 00:02:52,836 But there's a really strange problem with using visible light 54 00:02:52,860 --> 00:02:54,996 in order to try and explore the universe. 55 00:02:55,020 --> 00:02:57,700 Say you're standing on a corner, a busy street corner. 56 00:02:58,180 --> 00:02:59,676 There's cars going by. 57 00:02:59,700 --> 00:03:01,100 An ambulance approaches. 58 00:03:01,940 --> 00:03:03,316 It has a high-pitched siren. 59 00:03:03,340 --> 00:03:07,076 (Imitates a siren passing by) 60 00:03:07,100 --> 00:03:09,436 The siren appeared to change in pitch 61 00:03:09,460 --> 00:03:11,540 as it moved towards and away from you. 62 00:03:12,060 --> 00:03:15,940 The ambulance driver did not change the siren just to mess with you. 63 00:03:16,860 --> 00:03:19,436 That was a product of your perception. 64 00:03:19,460 --> 00:03:22,196 The sound waves, as the ambulance approached, 65 00:03:22,220 --> 00:03:23,436 were compressed, 66 00:03:23,460 --> 00:03:25,396 and they changed higher in pitch. 67 00:03:25,420 --> 00:03:28,196 As the ambulance receded, the sound waves were stretched, 68 00:03:28,220 --> 00:03:30,276 and they sounded lower in pitch. 69 00:03:30,300 --> 00:03:32,300 The same thing happens with light. 70 00:03:32,860 --> 00:03:35,236 Objects moving towards us, 71 00:03:35,260 --> 00:03:38,436 their light waves are compressed and they appear bluer. 72 00:03:38,460 --> 00:03:40,676 Objects moving away from us, 73 00:03:40,700 --> 00:03:43,356 their light waves are stretched, and they appear redder. 74 00:03:43,380 --> 00:03:46,260 So we call these effects blueshift and redshift. 75 00:03:47,260 --> 00:03:49,237 Our universe is expanding, 76 00:03:49,261 --> 00:03:53,356 so everything is moving away from everything else, 77 00:03:53,380 --> 00:03:56,060 and that means everything appears to be red. 78 00:03:56,967 --> 00:04:00,556 And oddly enough, as you look more deeply into the universe, 79 00:04:00,580 --> 00:04:04,876 more distant objects are moving away further and faster, 80 00:04:04,900 --> 00:04:06,619 so they appear more red. 81 00:04:07,340 --> 00:04:10,635 So if I come back to the Hubble Deep Field 82 00:04:10,659 --> 00:04:13,356 and we were to continue to peer deeply into the universe 83 00:04:13,380 --> 00:04:14,916 just using the Hubble, 84 00:04:14,940 --> 00:04:17,636 as we get to a certain distance away, 85 00:04:17,660 --> 00:04:19,260 everything becomes red, 86 00:04:20,060 --> 00:04:22,036 and that presents something of a problem. 87 00:04:22,060 --> 00:04:24,116 Eventually, we get so far away 88 00:04:24,140 --> 00:04:27,116 everything is shifted into the infrared 89 00:04:27,140 --> 00:04:28,876 and we can't see anything at all. 90 00:04:28,900 --> 00:04:30,596 So there must be a way around this. 91 00:04:30,620 --> 00:04:32,436 Otherwise, I'm limited in my journey. 92 00:04:32,460 --> 00:04:34,356 I wanted to explore the whole universe, 93 00:04:34,380 --> 00:04:38,106 not just whatever I can see, you know, before the redshift kicks in. 94 00:04:38,130 --> 00:04:39,386 There is a technique. 95 00:04:39,410 --> 00:04:40,786 It's called radio astronomy. 96 00:04:40,810 --> 00:04:43,146 Astronomers have been using this for decades. 97 00:04:43,170 --> 00:04:44,466 It's a fantastic technique. 98 00:04:44,490 --> 00:04:47,986 I show you the Parkes Radio Telescope, affectionately known as "The Dish." 99 00:04:48,010 --> 00:04:49,386 You may have seen the movie. 100 00:04:49,410 --> 00:04:50,887 And radio is really brilliant. 101 00:04:50,911 --> 00:04:53,448 It allows us to peer much more deeply. 102 00:04:53,472 --> 00:04:55,666 It doesn't get stopped by dust, 103 00:04:55,690 --> 00:04:57,946 so you can see everything in the universe, 104 00:04:57,970 --> 00:04:59,826 and redshift is less of a problem 105 00:04:59,850 --> 00:05:03,050 because we can build receivers that receive across a large band. 106 00:05:03,570 --> 00:05:07,506 So what does Parkes see when we turn it to the center of the Milky Way? 107 00:05:07,530 --> 00:05:09,490 We should see something fantastic, right? 108 00:05:10,130 --> 00:05:13,026 Well, we do see something interesting. 109 00:05:13,050 --> 00:05:14,706 All that dust has gone. 110 00:05:14,730 --> 00:05:18,170 As I mentioned, radio goes straight through dust, so not a problem. 111 00:05:18,810 --> 00:05:20,706 But the view is very different. 112 00:05:20,730 --> 00:05:24,546 We can see that the center of the Milky Way is aglow, 113 00:05:24,570 --> 00:05:26,250 and this isn't starlight. 114 00:05:26,930 --> 00:05:30,066 This is a light called synchrotron radiation, 115 00:05:30,090 --> 00:05:34,690 and it's formed from electrons spiraling around cosmic magnetic fields. 116 00:05:35,000 --> 00:05:37,596 The plane is aglow with this light. 117 00:05:37,620 --> 00:05:40,916 And we can also see strange tufts coming off of it, 118 00:05:40,940 --> 00:05:43,436 and objects which don't appear to line up 119 00:05:43,460 --> 00:05:45,780 with anything that we can see with our own eyes. 120 00:05:46,740 --> 00:05:48,876 But it's hard to really interpret this image, 121 00:05:48,900 --> 00:05:51,676 because as you can see, it's very low resolution. 122 00:05:51,700 --> 00:05:53,876 Radio waves have a wavelength that's long, 123 00:05:53,900 --> 00:05:56,196 and that makes their resolution poorer. 124 00:05:56,220 --> 00:05:58,186 This image is also black and white, 125 00:05:58,210 --> 00:06:01,970 so we don't really know what is the color of everything in here. 126 00:06:02,860 --> 00:06:04,236 Well, fast-forward to today. 127 00:06:04,260 --> 00:06:05,716 We can build telescopes 128 00:06:05,740 --> 00:06:08,266 which can get over these problems. 129 00:06:08,290 --> 00:06:11,626 Now, I'm showing you here an image of the Murchison Radio Observatory, 130 00:06:11,650 --> 00:06:14,426 a fantastic place to build radio telescopes. 131 00:06:14,450 --> 00:06:16,746 It's flat, it's dry, 132 00:06:16,770 --> 00:06:19,746 and most importantly, it's radio quiet: 133 00:06:19,770 --> 00:06:22,866 no mobile phones, no Wi-Fi, nothing, 134 00:06:22,890 --> 00:06:25,386 just very, very radio quiet, 135 00:06:25,410 --> 00:06:28,130 so a perfect place to build a radio telescope. 136 00:06:29,010 --> 00:06:31,866 The telescope that I've been working on for a few years 137 00:06:31,890 --> 00:06:33,826 is called the Murchison Widefield Array, 138 00:06:33,850 --> 00:06:36,866 and I'm going to show you a little time lapse of it being built. 139 00:06:36,890 --> 00:06:40,146 This is a group of undergraduate and postgraduate students 140 00:06:40,170 --> 00:06:41,426 located in Perth. 141 00:06:41,450 --> 00:06:43,043 We call them the Student Army, 142 00:06:43,067 --> 00:06:45,884 and they volunteered their time to build a radio telescope. 143 00:06:45,908 --> 00:06:47,548 There's no course credit for this. 144 00:06:48,300 --> 00:06:51,196 And they're putting together these radio dipoles. 145 00:06:51,220 --> 00:06:56,180 They just receive at low frequencies, a bit like your FM radio or your TV. 146 00:06:56,980 --> 00:07:00,076 And here we are deploying them across the desert. 147 00:07:00,100 --> 00:07:02,516 The final telescope covers 10 square kilometers 148 00:07:02,540 --> 00:07:04,676 of the Western Australian desert. 149 00:07:04,700 --> 00:07:07,618 And the interesting thing is, there's no moving parts. 150 00:07:07,642 --> 00:07:09,899 We just deploy these little antennas 151 00:07:09,923 --> 00:07:11,780 essentially on chicken mesh. 152 00:07:11,804 --> 00:07:13,276 It's fairly cheap. 153 00:07:13,300 --> 00:07:15,276 Cables take the signals 154 00:07:15,300 --> 00:07:16,935 from the antennas 155 00:07:16,959 --> 00:07:19,516 and bring them to central processing units. 156 00:07:19,540 --> 00:07:21,316 And it's the size of this telescope, 157 00:07:21,340 --> 00:07:23,996 the fact that we've built it over the entire desert 158 00:07:24,020 --> 00:07:26,820 that gives us a better resolution than Parkes. 159 00:07:27,460 --> 00:07:30,996 Now, eventually all those cables bring them to a unit 160 00:07:31,020 --> 00:07:34,556 which sends it off to a supercomputer here in Perth, 161 00:07:34,580 --> 00:07:35,876 and that's where I come in. 162 00:07:35,900 --> 00:07:37,051 (Sighs) 163 00:07:37,075 --> 00:07:38,356 Radio data. 164 00:07:38,380 --> 00:07:40,396 I have spent the last five years 165 00:07:40,420 --> 00:07:43,276 working with very difficult, very interesting data 166 00:07:43,300 --> 00:07:45,276 that no one had really looked at before. 167 00:07:45,300 --> 00:07:47,436 I've spent a long time calibrating it, 168 00:07:47,460 --> 00:07:50,676 running millions of CPU hours on supercomputers 169 00:07:50,700 --> 00:07:52,926 and really trying to understand that data. 170 00:07:52,950 --> 00:07:54,101 With this data, 171 00:07:54,125 --> 00:07:58,148 we've performed a survey of the entire southern sky, 172 00:07:58,172 --> 00:08:03,286 the GaLactic and Extragalactic All-sky MWA Survey, 173 00:08:03,310 --> 00:08:04,825 or GLEAM, as I call it. 174 00:08:05,260 --> 00:08:07,155 Imagine you went to the Murchison, 175 00:08:07,179 --> 00:08:09,075 you camped out underneath the stars 176 00:08:09,099 --> 00:08:10,716 and you looked towards the south. 177 00:08:10,740 --> 00:08:12,407 You saw the south's celestial pole, 178 00:08:12,431 --> 00:08:13,636 the galaxy rising. 179 00:08:13,660 --> 00:08:16,276 If I fade in the radio light, 180 00:08:16,300 --> 00:08:18,956 this is what we observe with our survey. 181 00:08:18,980 --> 00:08:22,036 You can see that the galactic plane is no longer dark with dust. 182 00:08:22,060 --> 00:08:24,369 It's alight with synchrotron radiation, 183 00:08:24,393 --> 00:08:25,636 and thousands of dots -- 184 00:08:25,660 --> 00:08:28,956 our large Magellanic Cloud, our nearest galactic neighbor, 185 00:08:28,980 --> 00:08:32,196 is orange instead of its more familiar blue-white. 186 00:08:32,220 --> 00:08:35,596 So there's a lot going on in this. Let's take a closer look. 187 00:08:35,620 --> 00:08:38,036 If we look back towards the galactic center, 188 00:08:38,060 --> 00:08:41,276 where we originally saw the Parkes image that I showed you earlier, 189 00:08:41,300 --> 00:08:43,676 low resolution, black and white, 190 00:08:43,700 --> 00:08:46,246 and we fade to the GLEAM view, 191 00:08:46,270 --> 00:08:50,126 you can see the resolution has gone up by a factor of a hundred. 192 00:08:50,150 --> 00:08:53,006 We now have a color view of the sky, 193 00:08:53,030 --> 00:08:54,366 a technicolor view. 194 00:08:54,390 --> 00:08:57,366 Now, it's not a false color view. 195 00:08:57,390 --> 00:08:59,790 These are real radio colors. 196 00:09:00,670 --> 00:09:03,486 What I've done is I've colored the lowest frequencies red 197 00:09:03,510 --> 00:09:05,126 and the highest frequencies blue, 198 00:09:05,150 --> 00:09:06,726 and the middle ones green. 199 00:09:06,750 --> 00:09:08,966 And that gives us this rainbow view. 200 00:09:08,990 --> 00:09:10,846 And this isn't just false color. 201 00:09:10,870 --> 00:09:13,806 The colors in this image tell us about the physical processes 202 00:09:13,830 --> 00:09:15,070 going on in the universe. 203 00:09:15,644 --> 00:09:18,406 So for instance, if you look along the plane of the galaxy, 204 00:09:18,430 --> 00:09:19,886 it's alight with synchrotron, 205 00:09:19,910 --> 00:09:22,286 which is mostly reddish orange, 206 00:09:22,310 --> 00:09:25,430 but if we look very closely, we see little blue dots. 207 00:09:25,990 --> 00:09:27,566 Now, if we zoom in, 208 00:09:27,590 --> 00:09:30,126 these blue dots are ionized plasma 209 00:09:30,150 --> 00:09:31,790 around very bright stars, 210 00:09:32,350 --> 00:09:35,126 and what happens is that they block the red light, 211 00:09:35,150 --> 00:09:36,790 so they appear blue. 212 00:09:37,350 --> 00:09:40,016 And these can tell us about these star-forming regions 213 00:09:40,040 --> 00:09:41,296 in our galaxy. 214 00:09:41,320 --> 00:09:42,936 And we just see them immediately. 215 00:09:42,960 --> 00:09:46,016 We look at the galaxy, and the color tells us that they're there. 216 00:09:46,040 --> 00:09:47,616 You can see little soap bubbles, 217 00:09:47,640 --> 00:09:50,834 little circular images around the galactic plane, 218 00:09:50,858 --> 00:09:52,858 and these are supernova remnants. 219 00:09:53,580 --> 00:09:55,276 When a star explodes, 220 00:09:55,300 --> 00:09:57,756 its outer shell is cast off 221 00:09:57,780 --> 00:10:01,076 and it travels outward into space gathering up material, 222 00:10:01,100 --> 00:10:03,060 and it produces a little shell. 223 00:10:03,780 --> 00:10:07,156 It's been a long-standing mystery to astronomers 224 00:10:07,180 --> 00:10:09,260 where all the supernova remnants are. 225 00:10:09,940 --> 00:10:14,276 We know that there must be a lot of high-energy electrons in the plane 226 00:10:14,300 --> 00:10:16,956 to produce the synchrotron radiation that we see, 227 00:10:16,980 --> 00:10:19,556 and we think they're produced by supernova remnants, 228 00:10:19,580 --> 00:10:21,356 but there don't seem to be enough. 229 00:10:21,380 --> 00:10:25,276 Fortunately, GLEAM is really, really good at detecting supernova remnants. 230 00:10:26,160 --> 00:10:27,416 That's fine. 231 00:10:27,440 --> 00:10:29,436 We've explored our little local universe, 232 00:10:29,460 --> 00:10:31,836 but I wanted to go deeper, I wanted to go further. 233 00:10:31,860 --> 00:10:34,116 I wanted to go beyond the Milky Way. 234 00:10:34,140 --> 00:10:37,916 Well, as it happens, we can see a very interesting object in the top right, 235 00:10:37,940 --> 00:10:40,156 and this is a local radio galaxy, 236 00:10:40,180 --> 00:10:41,420 Centaurus A. 237 00:10:41,860 --> 00:10:43,011 If we zoom in on this, 238 00:10:43,035 --> 00:10:46,435 we can see that there are two huge plumes going out into space. 239 00:10:47,220 --> 00:10:50,116 And if you look right in the center between those two plumes, 240 00:10:50,140 --> 00:10:52,516 you'll see a galaxy just like our own. 241 00:10:52,540 --> 00:10:54,996 It's a spiral. It has a dust lane. 242 00:10:55,020 --> 00:10:56,636 It's a normal galaxy. 243 00:10:56,660 --> 00:10:59,676 But these jets are only visible in the radio. 244 00:10:59,700 --> 00:11:02,876 If we looked in the visible, we wouldn't even know they were there, 245 00:11:02,900 --> 00:11:05,940 and they're thousands of times larger than the host galaxy. 246 00:11:06,500 --> 00:11:08,900 What's going on? What's producing these jets? 247 00:11:10,180 --> 00:11:13,716 At the center of every galaxy that we know about 248 00:11:13,740 --> 00:11:15,996 is a supermassive black hole. 249 00:11:16,020 --> 00:11:17,509 Now, black holes are invisible. 250 00:11:18,060 --> 00:11:21,076 All you can see is the deflection of the light around them, 251 00:11:21,100 --> 00:11:25,396 and occasionally, when a star or a cloud of gas comes into their orbit, 252 00:11:25,420 --> 00:11:28,156 it is ripped apart by tidal forces, 253 00:11:28,180 --> 00:11:30,660 forming what we call an accretion disk. 254 00:11:31,260 --> 00:11:34,476 The accretion disk glows brightly in the x-rays, 255 00:11:34,500 --> 00:11:38,916 and huge magnetic fields can launch the material into space 256 00:11:38,940 --> 00:11:40,660 at nearly the speed of light. 257 00:11:41,053 --> 00:11:43,831 These jets are visible in the radio 258 00:11:43,855 --> 00:11:46,015 and this is what we pick up in our survey. 259 00:11:46,660 --> 00:11:49,436 Well, very well, so we've seen one radio galaxy. 260 00:11:49,460 --> 00:11:51,636 But if you just look at the top of that image, 261 00:11:51,660 --> 00:11:53,396 you'll see another radio galaxy. 262 00:11:53,420 --> 00:11:56,660 It's a little bit smaller, and that's just because it's further away. 263 00:11:57,148 --> 00:11:59,836 OK. Two radio galaxies. 264 00:11:59,860 --> 00:12:01,334 We can see this. This is fine. 265 00:12:01,358 --> 00:12:03,095 Well, what about all the other dots? 266 00:12:03,119 --> 00:12:04,679 Presumably those are just stars. 267 00:12:05,060 --> 00:12:06,276 They're not. 268 00:12:06,300 --> 00:12:07,900 They're all radio galaxies. 269 00:12:08,550 --> 00:12:11,446 Every single one of the dots in this image 270 00:12:11,470 --> 00:12:13,150 is a distant galaxy, 271 00:12:13,174 --> 00:12:16,031 millions to billions of light-years away 272 00:12:16,055 --> 00:12:18,726 with a supermassive black hole at its center 273 00:12:18,750 --> 00:12:22,190 pushing material into space at nearly the speed of light. 274 00:12:22,214 --> 00:12:23,713 It is mind-blowing. 275 00:12:24,850 --> 00:12:28,586 And this survey is even larger than what I've shown here. 276 00:12:28,610 --> 00:12:31,146 If we zoom out to the full extent of the survey, 277 00:12:31,170 --> 00:12:34,538 you can see I found 300,000 of these radio galaxies. 278 00:12:35,140 --> 00:12:37,244 We've discovered all of these galaxies 279 00:12:37,268 --> 00:12:40,828 right back to the very first supermassive black holes. 280 00:12:41,680 --> 00:12:44,640 There's something even more in this image. 281 00:12:45,320 --> 00:12:47,716 I'll take you right back to the dawn of time. 282 00:12:47,740 --> 00:12:50,896 When the universe formed, it was a big bang, 283 00:12:50,920 --> 00:12:54,816 which left the universe as a sea of hydrogen, neutral hydrogen. 284 00:12:54,840 --> 00:12:57,616 And when the very first stars and galaxies switched on, 285 00:12:57,640 --> 00:12:59,736 they ionized that hydrogen. 286 00:12:59,760 --> 00:13:03,200 So the universe went from neutral to ionized. 287 00:13:04,080 --> 00:13:07,256 That imprinted a signal all around us. 288 00:13:07,280 --> 00:13:09,016 Everywhere, it pervades us, 289 00:13:09,040 --> 00:13:10,465 like the Force. 290 00:13:10,489 --> 00:13:11,494 (Laughter) 291 00:13:11,518 --> 00:13:14,358 Because that happened so long ago, 292 00:13:14,920 --> 00:13:16,720 the signal was redshifted, 293 00:13:17,480 --> 00:13:20,776 so now that signal is at very low frequencies. 294 00:13:20,800 --> 00:13:23,256 It's at the same frequency as my survey, 295 00:13:23,280 --> 00:13:24,656 but it's so faint. 296 00:13:24,680 --> 00:13:28,560 It's a billionth the size of any of the objects in my survey. 297 00:13:29,240 --> 00:13:33,866 So our telescope may not be quite sensitive enough to pick up this signal. 298 00:13:33,890 --> 00:13:36,386 However, there's a new radio telescope. 299 00:13:36,410 --> 00:13:38,066 So I can't have a starship, 300 00:13:38,090 --> 00:13:39,346 but I can hopefully have 301 00:13:39,370 --> 00:13:42,226 one of the biggest radio telescopes in the world. 302 00:13:42,250 --> 00:13:45,866 We're building the Square Kilometre Array, a new radio telescope, 303 00:13:45,890 --> 00:13:48,626 and it's going to be a thousand times bigger than the MWA, 304 00:13:48,650 --> 00:13:51,866 a thousand times more sensitive, and have an even better resolution. 305 00:13:51,890 --> 00:13:54,106 So we should find tens of millions of galaxies. 306 00:13:54,130 --> 00:13:56,466 And perhaps, deep in that signal, 307 00:13:56,490 --> 00:14:00,666 I will get to look upon the very first stars and galaxies switching on, 308 00:14:00,690 --> 00:14:03,050 the beginning of time itself. 309 00:14:03,514 --> 00:14:04,665 Thank you. 310 00:14:04,689 --> 00:14:11,689 (Applause)