5X5 Episode 75

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The Coriolis Effect

Voice-over: You're listening to the Skeptics' Guide 5x5, five minutes with five skeptics, with Steve, Jay, Rebecca, Bob and Evan.

S: This is the SGU 5x5 and tonight we are talking about The Coriolis Effect. The Coriolis Effect or the Coriolis force is actually a pseudo force or an illusionary force that appears to cause things to curve as they travel a long distance across a rotating or spinning frame of reference.

E: It's called the Coriolis Effect because it was first discovered by Gaspard-Gustave Coriolis a French mathematician, mechanical engineer and scientist. He's best known for work on motion of moving parts in machines relative to their fixed parts. He had a talent for interpreting and adapting these theories to applied mathematics and mechanics and while he was an assistant professor and a director of studies at the École Polytechnique in Paris from 1816 to 1838 he gave the terms work and kenetic energy their scientific and practical meanings and they're still used today. But in 1835 he published a paper called "On the equations of relative motion of a system bodies" which he described this force which, in the 20th century became known as the Coriolis Effect.

R: The funny thing is I think most people think of the Coriolis Effect as something it is not. A lot of people have heard of it when they're talking about the way that, say, water swirls down the drain or the way your toilet flushes. There's a really common thing that's done on tours around the equator where they show you a bowl of water with a hole at the bottom and they show water swirling down one way on one side of the equator and then they step over to the other side and show it swirling the other way. This effect has even been, ah, if you've been fooled by it don't feel bad because I read a book by Douglas Adams where he talks about it believing that it's totally true and at the time he wrote the book he still thought it was true. So you're not the only one and it's a very good illusion and good kind of trick. But the trick is really just in the bowls, the drains that you use, the way that they are pock marked or the subtle variation in the bowl can have a lot more to do with the way water drains than, for instance, what side of the equator you're on. You could also influence it by spinning the bowl a certain way and tipping it a certain way. So unfortunately that's not actually the Coriolis Effect that you see.

S: That's right because the Coriolis Effect is proportional to distance over which something is moving like, say , a cannonball shooting a mile or two or lets say the size of a weather system lake a tropical storm or a hurricane. However the size of a bathtub or a sink it's far, far, far too small for the Coriolis Effect to be significant. This is something called the Rosby number which describes the magnitude of the Coriolis Effect and for things the size of a tub it is literally negligible. Even the slightest momentum in the water in the tub will overwhelm any Coriolis force and that will determine the direction that the water spins when it goes down the drain.

B: In fact the Coriolis Effect is two or three orders of magnitude smaller than any of the random influences that are a much greater influence on the way that the water drains. But it can, you can pull it off, you can show the Coriolis force in a small body of water, something maybe tub sized or maybe smaller but it's an extreme effort to make it work. First off you need an incredibly smooth and uniform bowl. You will need small drain hole not a big one because you're going to need time for this force to build up. And you're also going to need about a week and a lot of patience for the water to become completely still so that all motion that may have been induced by you, by the water going in, will be completely washed away and then only then would you be able to potentially see the Coriolis effect in action but it's a very difficult experiment to pull off on something that small scale.

J: You know I had to admit I had a hard time really understanding what this meant until I had a discussion with Steve about it then I actually went to Wikipedia and looked at the graphic that they had on there so I highly recommend that you do this. Now I did come up with a way to help explain the idea of what this is visually. So lets say that an ant is travelling around a hulahoop and the hula hoop is rotating and then a cannonball is shot from the centre of that circle. It would appear to the ant that the cannonballs path is curving when it actually isn't. because the ant is actually moving on the outside of a sphere, just like we are on the Earth and that's the basic explanation of why the path of that cannonball looks like it is curving when it isn't. And the other thing is in regards to ballistics, let's say someone is shooting something above a half a mile. They may have to take into account the Coriolis effect because the Earth is actually spinning underneath that missile after it's shot and the position isn't going to be accurate as if it was being shot on something that isn't spinning. A ballistics expert has to take into account the spin of the earth in order to calculate where that shot is actually going to hit.

B: And the faster you're moving the more pronounced the Coriolis effect is will be and the further north or further south you are below the equator will also make it more and more pronounced. Another great way to visualise this is to picture four kids on a playground carousel that's spinning around and with each kid at the 12, 3, 6 and 9 positions. If the carousel is spinning and the kid at the 12 o'clock position shot the ball straight out, just pushed it straight out, the ball will curve to the left, depending on rotation of course, it will curve to the left to the person at the 3 o'clock position and then if he did it the same thing would happen it would go straight out briefly and then gently curve to the person ant the 6 o'clock position so if you were outside of that carousel and you looked at the ball would seem to be moving in a straight line but if you're on that rotating frame of reference only then will it appear to have a curved aspect to it.

E: It's a good point Bob, it's a good lesson for the kids so if there are four kids on that carousel and you're ninety degrees off centre to the left then that other kid vomits then, you know, be careful. It's not going to go straight ahead to the other kid it's going to go the left

B: (laughter)

S: That's right. So, to summarise the Coriolis force is an artefact of making observations within a rotating or spinning frame of reference. But if you are within that frame of reference you can actually treat it as if it is a real force and everything will work out as if that were true in all the calculations and observations that you make but really it's just an artefact of making observations from within a, what we call, non inertial frame of reference.

B: There are those that will argue that although it appears the force seems to just appear within the rotating frame of reference even though it's not a fundamental force of nature it is a bona fide force and should be treated as such.

S: SGU 5x5 is a companion podcast to the Skeptics' Guide to the Universe, a weekly science podcast brought to you by the New England Skeptical Society in association with skepchick.org. For more information on this and other episodes, visit our website at www.theskepticsguide.org. Music is provided by Jake Wilson.