0:00:05.684,0:00:08.684 French fries are delicious. 0:00:08.684,0:00:12.684 French fries with ketchup are a little slice of heaven. 0:00:12.684,0:00:14.432 The problem is it's basically impossible 0:00:14.432,0:00:16.463 to pour the exactly right amount. 0:00:16.463,0:00:19.768 We're so used to pouring ketchup that we don't realize 0:00:19.768,0:00:21.851 how weird its behavior is. 0:00:21.851,0:00:26.430 Imagine a ketchup bottle filled with a straight up solid like steel. 0:00:26.430,0:00:29.475 No amount of shaking would ever get the steel out. 0:00:29.475,0:00:32.395 Now imagine that same bottle full of a liquid like water. 0:00:32.395,0:00:34.434 That would pour like a dream. 0:00:34.434,0:00:36.851 Ketchup, though, can't seem to make up its mind. 0:00:36.851,0:00:38.933 Is it is a solid? Or a liquid? 0:00:38.933,0:00:41.654 The answer is, it depends. 0:00:41.654,0:00:44.846 The world's most common fluids like water, oils and alcohols 0:00:44.846,0:00:47.597 respond to force linearly. 0:00:47.597,0:00:51.238 If you push on them twice as hard, they move twice as fast. 0:00:51.238,0:00:54.355 Sir Isaac Newton, of apple fame, first proposed this relationship, 0:00:54.355,0:00:57.739 and so those fluids are called Newtonian fluids. 0:00:57.739,0:01:00.695 Ketchup, though, is part of a merry band of linear rule breakers 0:01:00.695,0:01:03.286 called Non-Newtonian fluids. 0:01:03.286,0:01:06.368 Mayonnaise, toothpaste, blood, paint, peanut butter 0:01:06.368,0:01:09.870 and lots of other fluids respond to force non-linearly. 0:01:09.870,0:01:11.915 That is, their apparent thickness changes 0:01:11.915,0:01:15.336 depending on how hard you push, or how long, or how fast. 0:01:15.336,0:01:18.551 And ketchup is actually Non-Newtonian in two different ways. 0:01:18.551,0:01:22.849 Way number one: the harder you push, the thinner ketchup seems to get. 0:01:22.849,0:01:24.715 Below a certain pushing force, 0:01:24.715,0:01:26.717 ketchup basically behaves like a solid. 0:01:26.717,0:01:29.134 But once you pass that breaking point, 0:01:29.134,0:01:33.384 it switches gears and becomes a thousand times thinner than it was before. 0:01:33.384,0:01:35.384 Sound familiar right? 0:01:35.384,0:01:39.276 Way number two: if you push with a force below the threshold force 0:01:39.276,0:01:41.569 eventually, the ketchup will start to flow. 0:01:41.569,0:01:45.158 In this case, time, not force, is the key to releasing ketchup 0:01:45.158,0:01:46.992 from its glassy prison. 0:01:46.992,0:01:49.620 Alright, so, why does ketchup act all weird? 0:01:49.620,0:01:52.634 Well, it's made from tomatoes, pulverized, smashed, thrashed, 0:01:52.634,0:01:55.457 utterly destroyed tomatoes. 0:01:55.457,0:01:56.801 See these tiny particles? 0:01:56.801,0:01:58.586 This is what remains of tomatoes cells 0:01:58.586,0:02:01.215 after they go through the ketchup treatment. 0:02:01.215,0:02:02.925 And the liquid around those particles? 0:02:02.925,0:02:05.967 That's mostly water and some vinegar, sugar, and spices. 0:02:05.967,0:02:08.190 When ketchup is just sitting around, 0:02:08.190,0:02:11.551 the tomato particles are evenly and randomly distributed. 0:02:11.551,0:02:13.967 Now, let's say you apply a weak force very quickly. 0:02:13.967,0:02:15.522 The particles bump into each other, 0:02:15.522,0:02:17.218 but can't get out of each other's way, 0:02:17.218,0:02:18.717 so the ketchup doesn't flow. 0:02:18.717,0:02:21.777 Now, let's say you apply a strong force very quickly. 0:02:21.777,0:02:24.613 That extra force is enough to squish the tomato particles, 0:02:24.613,0:02:25.945 so maybe instead of little spheres, 0:02:25.945,0:02:28.827 they get smushed into little ellipses, and boom! 0:02:28.827,0:02:30.784 Now you have enough space for one group of particles 0:02:30.784,0:02:33.633 to get passed others and the ketchup flows. 0:02:33.633,0:02:37.716 Now let's say you apply a very weak force but for a very long time. 0:02:37.716,0:02:41.253 Turns out, we're not exactly sure what happens in this scenario. 0:02:41.253,0:02:45.009 One possibility is that the tomato particles near the walls of the container 0:02:45.009,0:02:47.299 slowly get bumped towards the middle, 0:02:47.299,0:02:48.800 leaving the soup they were dissolved in, 0:02:48.800,0:02:50.383 which remember is basically water, 0:02:50.383,0:02:51.884 near the edges. 0:02:51.884,0:02:54.383 That water serves as a lubricant betwen the glass bottle 0:02:54.383,0:02:56.436 and the center plug of ketchup, 0:02:56.436,0:02:58.551 and so the ketchup flows. 0:02:58.551,0:03:01.941 Another possibility is that the particles slowly rearrange themselves 0:03:01.941,0:03:05.801 into lots of small groups, which then flow past each other. 0:03:05.801,0:03:08.133 Scientists who study fluid flows are still actively researching 0:03:08.133,0:03:11.326 how ketchup and its merry friends work. 0:03:11.326,0:03:13.411 Ketchup basically gets thinner the harder you push, 0:03:13.411,0:03:16.498 but other substances, like oobleck or some natural peanut butters, 0:03:16.498,0:03:19.301 actually get thicker the harder you push. 0:03:19.301,0:03:21.717 Others can climb up rotating rods, 0:03:21.717,0:03:24.090 or continue to pour themselves out of a beeker, 0:03:24.090,0:03:26.012 once you get them started. 0:03:26.012,0:03:27.384 From a physics perspective, though, 0:03:27.384,0:03:30.217 ketchup is one of the more complicated mixtures out there. 0:03:30.217,0:03:32.467 And as if that weren't enough, the balance of ingredients 0:03:32.467,0:03:35.300 and the presence of natural thickeners like xanthan gum, 0:03:35.300,0:03:37.934 which is also found in many fruit drinks and milkshakes, 0:03:37.934,0:03:39.605 can mean that two different ketchups 0:03:39.605,0:03:41.549 can behave completely differently. 0:03:41.549,0:03:44.234 But most will show two telltale properties: 0:03:44.234,0:03:46.069 sudden thinning at a threshold force, 0:03:46.069,0:03:48.321 and more gradual thinning after a small force 0:03:48.321,0:03:50.365 is applied for a long time. 0:03:50.365,0:03:53.327 And that means you could get ketchup out of the bottle in two ways: 0:03:53.327,0:03:55.966 either give it a series of long, slow languid shakes 0:03:55.966,0:03:58.467 making sure you don't ever stop applying force, 0:03:58.467,0:04:02.504 or you could hit the bottle once very, very hard. 0:04:02.504,0:04:04.717 What the real pros do is keep the lid on, 0:04:04.717,0:04:07.132 give the bottle a few short, sharp shakes 0:04:07.132,0:04:08.550 to wake up all those tomato particles, 0:04:08.550,0:04:10.428 and then take the lid off 0:04:10.428,0:04:13.801 and do a nice controlled pour onto their heavenly fries.