WEBVTT 00:00:07.016 --> 00:00:08.476 In 2012, 00:00:08.476 --> 00:00:13.136 a team of Japanese and Danish researchers set a world record, 00:00:13.136 --> 00:00:15.716 transmitting 1 petabit of data— 00:00:15.716 --> 00:00:19.006 that’s 10,000 hours of high-def video— 00:00:19.006 --> 00:00:22.526 over a fifty-kilometer cable, in a second. 00:00:22.526 --> 00:00:24.426 This wasn’t just any cable. 00:00:24.426 --> 00:00:27.466 It was a souped-up version of fiber optics— 00:00:27.466 --> 00:00:29.766 the hidden network that links our planet 00:00:29.766 --> 00:00:32.236 and makes the internet possible. NOTE Paragraph 00:00:32.236 --> 00:00:33.116 For decades, 00:00:33.116 --> 00:00:36.496 long-distance communications between cities and countries 00:00:36.496 --> 00:00:38.546 were carried by electrical signals, 00:00:38.546 --> 00:00:40.266 in wires made of copper. 00:00:40.266 --> 00:00:42.236 This was slow and inefficient, 00:00:42.236 --> 00:00:47.656 with metal wires limiting data rates and power lost as wasted heat. 00:00:47.656 --> 00:00:49.596 But in the late 20th century, 00:00:49.596 --> 00:00:53.596 engineers mastered a far superior method of transmission. 00:00:53.596 --> 00:00:55.056 Instead of metal, 00:00:55.056 --> 00:01:00.146 glass can be carefully melted and drawn into flexible fiber strands, 00:01:00.146 --> 00:01:04.535 hundreds of kilometers long and no thicker than human hair. 00:01:04.535 --> 00:01:06.237 And instead of electricity, 00:01:06.237 --> 00:01:11.487 these strands carry pulses of light, representing digital data. NOTE Paragraph 00:01:11.487 --> 00:01:16.227 But how does light travel within glass, rather than just pass through it? 00:01:16.227 --> 00:01:21.511 The trick lies in a phenomenon known as total internal reflection. 00:01:21.511 --> 00:01:23.168 Since Isaac Newton’s time, 00:01:23.168 --> 00:01:26.798 lensmakers and scientists have known that light bends 00:01:26.798 --> 00:01:31.588 when it passes between air and materials like water or glass. 00:01:31.588 --> 00:01:36.239 When a ray of light inside glass hits its surface at a steep angle, 00:01:36.239 --> 00:01:39.969 it refracts, or bends as it exits into air. 00:01:39.969 --> 00:01:42.959 But if the ray travels at a shallow angle, 00:01:42.959 --> 00:01:46.029 it’ll bend so far that it stays trapped, 00:01:46.029 --> 00:01:48.949 bouncing along inside the glass. 00:01:48.949 --> 00:01:50.319 Under the right condition, 00:01:50.319 --> 00:01:55.549 something normally transparent to light can instead hide it from the world. NOTE Paragraph 00:01:55.549 --> 00:01:57.991 Compared to electricity or radio, 00:01:57.991 --> 00:02:01.781 fiber optic signals barely degrade over great distances— 00:02:01.781 --> 00:02:04.051 a little power does scatter away, 00:02:04.051 --> 00:02:06.581 and fibers can’t bend too sharply, 00:02:06.581 --> 00:02:08.491 otherwise the light leaks out. 00:02:08.491 --> 00:02:12.791 Today, a single optical fiber carries many wavelengths of light, 00:02:12.791 --> 00:02:15.256 each a different channel of data. 00:02:15.256 --> 00:02:19.466 And a fiber optic cable contains hundreds of these fiber strands. 00:02:19.466 --> 00:02:23.445 Over a million kilometers of cable crisscross our ocean floors 00:02:23.445 --> 00:02:25.045 to link the continents— 00:02:25.045 --> 00:02:29.435 that’s enough to wind around the Equator nearly thirty times. NOTE Paragraph 00:02:29.435 --> 00:02:30.631 With fiber optics, 00:02:30.631 --> 00:02:32.851 distance hardly limits data, 00:02:32.851 --> 00:02:36.851 which has allowed the internet to evolve into a planetary computer. 00:02:36.851 --> 00:02:37.651 Increasingly, 00:02:37.651 --> 00:02:43.221 our mobile work and play rely on legions of overworked computer servers, 00:02:43.221 --> 00:02:47.161 warehoused in gigantic data centers flung across the world. 00:02:47.161 --> 00:02:49.081 This is called cloud computing, 00:02:49.081 --> 00:02:51.361 and it leads to two big problems: 00:02:51.361 --> 00:02:54.144 heat waste and bandwidth demand. 00:02:54.144 --> 00:02:58.844 The vast majority of internet traffic shuttles around inside data centers, 00:02:58.844 --> 00:03:03.544 where thousands of servers are connected by traditional electrical cables. 00:03:03.544 --> 00:03:06.286 Half of their running power is wasted as heat. 00:03:06.286 --> 00:03:10.446 Meanwhile, wireless bandwidth demand steadily marches on, 00:03:10.446 --> 00:03:13.536 and the gigahertz signals used in our mobile devices 00:03:13.536 --> 00:03:16.336 are reaching their data delivery limits. NOTE Paragraph 00:03:16.336 --> 00:03:19.866 It seems fiber optics has been too good for its own good, 00:03:19.866 --> 00:03:24.576 fueling overly-ambitious cloud and mobile computing expectations. 00:03:24.576 --> 00:03:29.826 But a related technology, integrated photonics, has come to the rescue. NOTE Paragraph 00:03:29.827 --> 00:03:32.857 Light can be guided not only in optical fibers, 00:03:32.857 --> 00:03:36.217 but also in ultrathin silicon wires. 00:03:36.217 --> 00:03:39.547 Silicon wires don’t guide light as well as fiber. 00:03:39.547 --> 00:03:42.117 But they do enable engineers to shrink 00:03:42.117 --> 00:03:45.597 all the devices in a hundred kilometer fiber optic network 00:03:45.597 --> 00:03:49.237 down to tiny photonic chips that plug into servers 00:03:49.237 --> 00:03:53.327 and convert their electrical signals to optical and back. 00:03:53.327 --> 00:03:59.429 These electricity-to-light chips allow for wasteful electrical cables in data centers 00:03:59.429 --> 00:04:02.809 to be swapped out for power-efficient fiber. NOTE Paragraph 00:04:02.809 --> 00:04:07.379 Photonic chips can help break open wireless bandwidth limitations, too. 00:04:07.379 --> 00:04:10.861 Researchers are working to replace mobile gigahertz signals 00:04:10.861 --> 00:04:12.651 with terahertz frequencies, 00:04:12.651 --> 00:04:15.581 to carry data thousands of times faster. 00:04:15.581 --> 00:04:17.621 But these are short-range signals: 00:04:17.621 --> 00:04:19.721 they get absorbed by moisture in the air, 00:04:19.721 --> 00:04:21.961 or blocked by tall buildings. 00:04:21.961 --> 00:04:25.331 With tiny wireless-to-fiber photonic transmitter chips 00:04:25.331 --> 00:04:27.001 distributed throughout cities, 00:04:27.001 --> 00:04:31.431 terahertz signals can be relayed over long-range distances. 00:04:31.431 --> 00:04:34.069 They can do so via a stable middleman, 00:04:34.069 --> 00:04:39.429 optical fiber, and make hyperfast wireless connectivity a reality. NOTE Paragraph 00:04:39.429 --> 00:04:41.303 For all of human history, 00:04:41.303 --> 00:04:43.893 light has gifted us with sight and heat, 00:04:43.893 --> 00:04:49.183 serving as a steady companion while we explored and settled the physical world. 00:04:49.183 --> 00:04:52.812 Now, we’ve saddled light with information and redirected it 00:04:52.812 --> 00:04:55.762 to run along a fiber optic superhighway— 00:04:55.762 --> 00:04:59.102 with many different integrated photonic exits— 00:04:59.102 --> 00:05:02.882 to build an even more expansive, virtual world.