0:00:00.946,0:00:02.670 I'm here to show you 0:00:02.670,0:00:06.371 how something you can't see can be so much fun to look at. 0:00:06.371,0:00:10.174 You're about to experience a new, available 0:00:10.174,0:00:13.154 and exciting technology that's going to make us rethink 0:00:13.154,0:00:15.282 how we waterproof our lives. 0:00:15.282,0:00:18.002 What I have here is a cinder block 0:00:18.002,0:00:20.498 that we've coated half with a nanotechnology spray 0:00:20.498,0:00:23.090 that can be applied to almost any material. 0:00:23.090,0:00:25.427 It's called Ultra-Ever Dry, 0:00:25.427,0:00:27.853 and when you apply it to any material, 0:00:27.853,0:00:30.958 it turns into a superhydrophobic shield. 0:00:30.958,0:00:33.484 So this is a cinder block, uncoated, 0:00:33.484,0:00:37.785 and you can see that it's porous, it absorbs water. 0:00:37.785,0:00:40.439 Not anymore. 0:00:40.439,0:00:44.666 Porous, nonporous. 0:00:44.666,0:00:47.418 So what's superhydrophobic? 0:00:47.418,0:00:49.911 Superhydrophobic is how we measure 0:00:49.911,0:00:52.393 a drop of water on a surface. 0:00:52.393,0:00:54.793 The rounder it is, the more hydrophobic it is, 0:00:54.793,0:00:57.721 and if it's really round, it's superhydrophobic. 0:00:57.721,0:01:00.667 A freshly waxed car, the water molecules slump 0:01:00.667,0:01:03.607 to about 90 degrees. 0:01:03.607,0:01:06.695 A windshield coating is going to give you about 110 degrees. 0:01:06.695,0:01:09.476 But what you're seeing here is 160 to 175 degrees, 0:01:09.476,0:01:13.488 and anything over 150 is superhydrophobic. 0:01:13.488,0:01:15.037 So as part of the demonstration, 0:01:15.037,0:01:17.551 what I have is a pair of gloves, 0:01:17.551,0:01:19.719 and we've coated one of the gloves 0:01:19.719,0:01:22.423 with the nanotechnology coating, 0:01:22.423,0:01:24.223 and let's see if you can tell which one, 0:01:24.223,0:01:26.559 and I'll give you a hint. 0:01:31.280,0:01:35.904 Did you guess the one that was dry? 0:01:35.904,0:01:40.606 When you have nanotechnology and nanoscience, 0:01:40.606,0:01:43.278 what's occurred is that we're able to now 0:01:43.278,0:01:45.791 look at atoms and molecules and actually control them 0:01:45.791,0:01:48.223 for great benefits. 0:01:48.223,0:01:50.222 And we're talking really small here. 0:01:50.222,0:01:52.494 The way you measure nanotechnology is in nanometers, 0:01:52.494,0:01:56.321 and one nanometer is a billionth of a meter, 0:01:56.321,0:01:57.968 and to put some scale to that, 0:01:57.968,0:02:01.274 if you had a nanoparticle that was one nanometer thick, 0:02:01.274,0:02:04.089 and you put it side by side, and you had 50,000 of them, 0:02:04.089,0:02:06.937 you'd be the width of a human hair. 0:02:06.937,0:02:09.945 So very small, but very useful. 0:02:09.945,0:02:12.849 And it's not just water that this works with. 0:02:12.849,0:02:15.600 It's a lot of water-based materials like concrete, 0:02:15.600,0:02:17.769 water-based paint, 0:02:17.769,0:02:19.417 mud, 0:02:19.417,0:02:22.800 and also some refined oils as well. 0:02:27.216,0:02:31.605 You can see the difference. 0:02:31.605,0:02:33.095 Moving onto the next demonstration, 0:02:33.095,0:02:35.389 we've taken a pane of glass and we've coated the outside of it, 0:02:35.389,0:02:38.639 we've framed it with the nanotechnology coating, 0:02:38.639,0:02:42.414 and we're going to pour this green-tinted water inside the middle, 0:02:42.414,0:02:44.375 and you're going to see, it's going to spread out on glass 0:02:44.375,0:02:45.925 like you'd normally think it would, 0:02:45.925,0:02:49.519 except when it hits the coating, it stops, 0:02:49.519,0:02:53.304 and I can't even coax it to leave. 0:02:53.304,0:02:54.907 It's that afraid of the water. 0:02:54.907,0:02:58.627 (Applause) 0:02:58.627,0:03:00.379 So what's going on here? What's happening? 0:03:00.379,0:03:03.667 Well, the surface of the spray coating 0:03:03.667,0:03:05.428 is actually filled with nanoparticles 0:03:05.428,0:03:07.502 that form a very rough and craggly surface. 0:03:07.502,0:03:10.091 You'd think it'd be smooth, but it's actually not. 0:03:10.091,0:03:12.862 And it has billions of interstitial spaces, 0:03:12.862,0:03:15.971 and those spaces, along with the nanoparticles, 0:03:15.971,0:03:18.323 reach up and grab the air molecules, 0:03:18.323,0:03:20.386 and cover the surface with air. 0:03:20.386,0:03:23.131 It's an umbrella of air all across it, 0:03:23.131,0:03:25.771 and that layer of air is what the water hits, 0:03:25.771,0:03:28.819 the mud hits, the concrete hits, and it glides right off. 0:03:28.819,0:03:30.835 So if I put this inside this water here, 0:03:30.835,0:03:34.955 you can see a silver reflective coating around it, 0:03:34.955,0:03:36.411 and that silver reflective coating 0:03:36.411,0:03:38.682 is the layer of air that's protecting the water 0:03:38.682,0:03:42.449 from touching the paddle, and it's dry. 0:03:45.340,0:03:47.837 So what are the applications? 0:03:47.837,0:03:50.285 I mean, many of you right now are probably going through your head. 0:03:50.285,0:03:51.783 Everyone that sees this gets excited, and says, 0:03:51.783,0:03:53.712 "Oh, I could use it for this and this and this." 0:03:53.712,0:03:55.774 The applications in a general sense 0:03:55.774,0:03:58.604 could be anything that's anti-wetting. 0:03:58.604,0:04:00.869 We've certainly seen that today. 0:04:00.869,0:04:03.453 It could be anything that's anti-icing, 0:04:03.453,0:04:06.908 because if you don't have water, you don't have ice. 0:04:06.908,0:04:09.180 It could be anti-corrosion. 0:04:09.180,0:04:11.206 No water, no corrosion. 0:04:11.206,0:04:13.404 It could be anti-bacterial. 0:04:13.404,0:04:16.113 Without water, the bacteria won't survive. 0:04:16.113,0:04:19.932 And it could be things that need to be self-cleaning as well. 0:04:21.629,0:04:25.501 So imagine how something like this 0:04:25.501,0:04:29.622 could help revolutionize your field of work. 0:04:29.622,0:04:32.021 And I'm going to leave you with one last demonstration, 0:04:32.021,0:04:34.622 but before I do that, I would like to say thank you, 0:04:34.622,0:04:36.665 and think small. 0:04:45.098,0:04:52.646 (Applause) 0:04:52.646,0:04:57.035 It's going to happen. Wait for it. Wait for it. 0:04:57.035,0:05:01.817 Chris Anderson: You guys didn't hear about us cutting out the Design from TED? (Laughter) 0:05:01.817,0:05:03.567 [Two minutes later...] 0:05:03.567,0:05:06.251 He ran into all sorts of problems in terms of managing the medical research part. 0:05:06.251,0:05:08.814 It's happening! 0:05:08.814,0:05:12.814 (Applause)