WEBVTT 00:00:07.255 --> 00:00:10.812 The Heisenberg Uncertainty Principle is one of a handful of ideas 00:00:10.812 --> 00:00:14.686 from quantum physics to expand into general pop culture. 00:00:14.686 --> 00:00:18.112 It says that you can never simultaneously know the exact position 00:00:18.112 --> 00:00:22.893 and the exact speed of an object and shows up as a metaphor in everything 00:00:22.893 --> 00:00:26.409 from literary criticism to sports commentary. 00:00:26.409 --> 00:00:29.429 Uncertainty is often explained as a result of measurement, 00:00:29.429 --> 00:00:34.561 that the act of measuring an object's position changes its speed, or vice versa. 00:00:34.561 --> 00:00:38.378 The real origin is much deeper and more amazing. 00:00:38.378 --> 00:00:41.759 The Uncertainty Principle exists because everything in the universe 00:00:41.759 --> 00:00:46.318 behaves like both a particle and a wave at the same time. 00:00:46.318 --> 00:00:50.458 In quantum mechanics, the exact position and exact speed of an object 00:00:50.458 --> 00:00:51.896 have no meaning. 00:00:51.896 --> 00:00:53.147 To understand this, 00:00:53.147 --> 00:00:57.053 we need to think about what it means to behave like a particle or a wave. 00:00:57.053 --> 00:01:01.857 Particles, by definition, exist in a single place at any instant in time. 00:01:01.857 --> 00:01:05.286 We can represent this by a graph showing the probability of finding 00:01:05.286 --> 00:01:09.030 the object at a particular place, which looks like a spike, 00:01:09.030 --> 00:01:13.707 100% at one specific position, and zero everywhere else. 00:01:13.707 --> 00:01:17.621 Waves, on the other hand, are disturbances spread out in space, 00:01:17.621 --> 00:01:20.338 like ripples covering the surface of a pond. 00:01:20.338 --> 00:01:23.767 We can clearly identify features of the wave pattern as a whole, 00:01:23.767 --> 00:01:25.933 most importantly, its wavelength, 00:01:25.933 --> 00:01:28.640 which is the distance between two neighboring peaks, 00:01:28.640 --> 00:01:30.459 or two neighboring valleys. 00:01:30.459 --> 00:01:33.017 But we can't assign it a single position. 00:01:33.017 --> 00:01:36.282 It has a good probability of being in lots of different places. 00:01:36.282 --> 00:01:39.099 Wavelength is essential for quantum physics 00:01:39.099 --> 00:01:42.419 because an object's wavelength is related to its momentum, 00:01:42.419 --> 00:01:44.024 mass times velocity. 00:01:44.024 --> 00:01:46.909 A fast-moving object has lots of momentum, 00:01:46.909 --> 00:01:50.019 which corresponds to a very short wavelength. 00:01:50.019 --> 00:01:54.559 A heavy object has lots of momentum even if it's not moving very fast, 00:01:54.559 --> 00:01:57.156 which again means a very short wavelength. 00:01:57.156 --> 00:02:00.927 This is why we don't notice the wave nature of everyday objects. 00:02:00.927 --> 00:02:02.644 If you toss a baseball up in the air, 00:02:02.644 --> 00:02:07.029 its wavelength is a billionth of a trillionth of a trillionth of a meter, 00:02:07.029 --> 00:02:09.364 far too tiny to ever detect. 00:02:09.364 --> 00:02:12.324 Small things, like atoms or electrons though, 00:02:12.324 --> 00:02:16.142 can have wavelengths big enough to measure in physics experiments. 00:02:16.142 --> 00:02:19.475 So, if we have a pure wave, we can measure its wavelength, 00:02:19.475 --> 00:02:23.101 and thus its momentum, but it has no position. 00:02:23.101 --> 00:02:25.248 We can know a particles position very well, 00:02:25.248 --> 00:02:28.489 but it doesn't have a wavelength, so we don't know its momentum. 00:02:28.489 --> 00:02:31.600 To get a particle with both position and momentum, 00:02:31.600 --> 00:02:33.760 we need to mix the two pictures 00:02:33.760 --> 00:02:37.163 to make a graph that has waves, but only in a small area. 00:02:37.163 --> 00:02:38.800 How can we do this? 00:02:38.800 --> 00:02:41.554 By combining waves with different wavelengths, 00:02:41.554 --> 00:02:46.528 which means giving our quantum object some possibility of having different momenta. 00:02:46.528 --> 00:02:49.282 When we add two waves, we find that there are places 00:02:49.282 --> 00:02:52.055 where the peaks line up, making a bigger wave, 00:02:52.055 --> 00:02:55.821 and other places where the peaks of one fill in the valleys of the other. 00:02:55.821 --> 00:02:58.279 The result has regions where we see waves 00:02:58.279 --> 00:03:01.106 separated by regions of nothing at all. 00:03:01.106 --> 00:03:02.590 If we add a third wave, 00:03:02.590 --> 00:03:05.709 the regions where the waves cancel out get bigger, 00:03:05.709 --> 00:03:09.891 a fourth and they get bigger still, with the wavier regions becoming narrower. 00:03:09.891 --> 00:03:13.089 If we keep adding waves, we can make a wave packet 00:03:13.089 --> 00:03:16.168 with a clear wavelength in one small region. 00:03:16.168 --> 00:03:20.224 That's a quantum object with both wave and particle nature, 00:03:20.224 --> 00:03:23.311 but to accomplish this, we had to lose certainty 00:03:23.311 --> 00:03:25.805 about both position and momentum. 00:03:25.805 --> 00:03:28.223 The positions isn't restricted to a single point. 00:03:28.223 --> 00:03:30.918 There's a good probability of finding it within some range 00:03:30.918 --> 00:03:32.837 of the center of the wave packet, 00:03:32.837 --> 00:03:35.586 and we made the wave packet by adding lots of waves, 00:03:35.586 --> 00:03:38.012 which means there's some probability of finding it 00:03:38.012 --> 00:03:41.291 with the momentum corresponding to any one of those. 00:03:41.291 --> 00:03:44.740 Both position and momentum are now uncertain, 00:03:44.740 --> 00:03:46.816 and the uncertainties are connected. 00:03:46.816 --> 00:03:49.209 If you want to reduce the position uncertainty 00:03:49.209 --> 00:03:52.628 by making a smaller wave packet, you need to add more waves, 00:03:52.628 --> 00:03:54.865 which means a bigger momentum uncertainty. 00:03:54.865 --> 00:03:58.047 If you want to know the momentum better, you need a bigger wave packet, 00:03:58.047 --> 00:04:01.012 which means a bigger position uncertainty. 00:04:01.012 --> 00:04:03.221 That's the Heisenberg Uncertainty Principle, 00:04:03.221 --> 00:04:08.207 first stated by German physicist Werner Heisenberg back in 1927. 00:04:08.207 --> 00:04:12.589 This uncertainty isn't a matter of measuring well or badly, 00:04:12.589 --> 00:04:17.107 but an inevitable result of combining particle and wave nature. 00:04:17.107 --> 00:04:20.663 The Uncertainty Principle isn't just a practical limit on measurment. 00:04:20.663 --> 00:04:23.733 It's a limit on what properties an object can have, 00:04:23.733 --> 00:04:28.157 built into the fundamental structure of the universe itself.