Please double-click on the English subtitles below to play the video.
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If you'd like to learn how to play the lobster, we have some here.
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And that's not a joke, we really do.
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So come up afterwards and I'll show you how to play a lobster.
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So, actually, I started working on what's called the mantis shrimp
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a few years ago because they make sound.
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This is a recording I made of a mantis shrimp
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that's found off the coast of California.
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And while that's an absolutely fascinating sound,
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it actually turns out to be a very difficult project.
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And while I was struggling to figure out how and why mantis shrimp,
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or stomatopods, make sound, I started to think about their appendages.
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And mantis shrimp are called "mantis shrimp" after the praying mantises,
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which also have a fast feeding appendage. And I started to think,
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well, maybe it will be interesting, while listening to their sounds,
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to figure out how these animals generate very fast feeding strikes.
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And so today I'll talk about the extreme stomatopod strike,
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work that I've done in collaboration with Wyatt Korff and Roy Caldwell.
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So, mantis shrimp come in two varieties:
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there are spearers and smashers.
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And this is a spearing mantis shrimp, or stomatopod.
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And he lives in the sand, and he catches things that go by overhead.
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So, a quick strike like that. And if we slow it down a bit,
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this is the mantis shrimp -- the same species --
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recorded at 1,000 frames a second,
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played back at 15 frames per second.
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And you can see it's just a really spectacular extension of the limbs,
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exploding upward to actually just catch
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a dead piece of shrimp that I had offered it.
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Now, the other type of mantis shrimp is the smasher stomatopod,
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and these guys open up snails for a living.
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And so this guy gets the snail all set up and gives it a good whack.
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(Laughter)
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So, I'll play it one more time.
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He wiggles it in place, tugs it with his nose, and smash.
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And a few smashes later, the snail is broken open, and he's got a good dinner.
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So, the smasher raptorial appendage can stab with a point at the end,
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or it can smash with the heel.
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And today I'll talk about the smashing type of strike.
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And so the first question that came to mind was,
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well, how fast does this limb move?
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Because it's moving pretty darn fast on that video.
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And I immediately came upon a problem.
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Every single high-speed video system in the biology department
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at Berkeley wasn't fast enough to catch this movement.
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We simply couldn't capture it on video.
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And so this had me stymied for quite a long period of time.
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And then a BBC crew came cruising through the biology department,
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looking for a story to do about new technologies in biology.
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And so we struck up a deal.
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I said, "Well, if you guys rent the high-speed video system
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that could capture these movements,
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you guys can film us collecting the data."
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And believe it or not, they went for it. (Laughter)
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So we got this incredible video system. It's very new technology --
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it just came out about a year ago --
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that allows you to film at extremely high speeds in low light.
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And low light is a critical issue with filming animals,
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because if it's too high, you fry them. (Laughter)
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So this is a mantis shrimp. There are the eyes up here,
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and there's that raptorial appendage, and there's the heel.
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And that thing's going to swing around and smash the snail.
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And the snail's wired to a stick,
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so he's a little bit easier to set up the shot. And -- yeah.
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(Laughter)
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I hope there aren't any snail rights activists around here.
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(Laughter)
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So this was filmed at 5,000 frames per second,
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and I'm playing it back at 15. And so this is slowed down 333 times.
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And as you'll notice, it's still pretty gosh darn fast
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slowed down 333 times. It's an incredibly powerful movement.
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The whole limb extends out. The body flexes backwards --
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just a spectacular movement.
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And so what we did is, we took a look at these videos,
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and we measured how fast the limb was moving
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to get back to that original question.
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And we were in for our first surprise.
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So what we calculated was that the limbs were moving
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at the peak speed ranging from 10 meters per second
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all the way up to 23 meters per second.
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And for those of you who prefer miles per hour,
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that's over 45 miles per hour in water. And this is really darn fast.
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In fact, it's so fast we were able to add a new point
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on the extreme animal movement spectrum.
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And mantis shrimp are officially the fastest measured feeding strike
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of any animal system. So our first surprise.
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(Applause)
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So that was really cool and very unexpected.
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So, you might be wondering, well, how do they do it?
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And actually, this work was done in the 1960s
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by a famous biologist named Malcolm Burrows.
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And what he showed in mantis shrimp is that they use
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what's called a "catch mechanism," or "click mechanism."
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And what this basically consists of is a large muscle
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that takes a good long time to contract,
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and a latch that prevents anything from moving.
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So the muscle contracts, and nothing happens.
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And once the muscle's contracted completely, everything's stored up --
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the latch flies upward, and you've got the movement.
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And that's basically what's called a "power amplification system."
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It takes a long time for the muscle to contract,
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and a very short time for the limb to fly out.
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And so I thought that this was sort of the end of the story.
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This was how mantis shrimps make these very fast strikes.
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But then I took a trip to the National Museum of Natural History.
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And if any of you ever have a chance,
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backstage of the National Museum of Natural History
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is one of the world's best collections of preserved mantis shrimp. And what --
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(Laughter)
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this is serious business for me.
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(Laughter)
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So, this -- what I saw, on every single mantis shrimp limb,
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whether it's a spearer or a smasher,
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is a beautiful saddle-shaped structure
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right on the top surface of the limb. And you can see it right here.
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It just looks like a saddle you'd put on a horse.
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It's a very beautiful structure.
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And it's surrounded by membranous areas. And those membranous areas
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suggested to me that maybe this is some kind of dynamically flexible structure.
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And this really sort of had me scratching my head for a while.
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And then we did a series of calculations, and what we were able to show
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is that these mantis shrimp have to have a spring.
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There needs to be some kind of spring-loaded mechanism
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in order to generate the amount of force that we observe,
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and the speed that we observe, and the output of the system.
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So we thought, OK, this must be a spring --
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the saddle could very well be a spring.
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And we went back to those high-speed videos again,
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and we could actually visualize the saddle compressing and extending.
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And I'll just do that one more time.
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And then if you take a look at the video --
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it's a little bit hard to see -- it's outlined in yellow.
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The saddle is outlined in yellow. You can actually see it
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extending over the course of the strike, and actually hyperextending.
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So, we've had very solid evidence showing
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that that saddle-shaped structure actually compresses and extends,
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and does, in fact, function as a spring.
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The saddle-shaped structure is also known as a "hyperbolic paraboloid surface,"
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or an "anticlastic surface."
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And this is very well known to engineers and architects,
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because it's a very strong surface in compression.
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It has curves in two directions,
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one curve upward and opposite transverse curve down the other,
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so any kind of perturbation spreads the forces
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over the surface of this type of shape.
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So it's very well known to engineers, not as well known to biologists.
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It's also known to quite a few people who make jewelry,
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because it requires very little material
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to build this type of surface, and it's very strong.
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So if you're going to build a thin gold structure,
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it's very nice to have it in a shape that's strong.
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Now, it's also known to architects. One of the most famous architects
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is Eduardo Catalano, who popularized this structure.
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And what's shown here is a saddle-shaped roof that he built
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that's 87 and a half feet spanwise.
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It's two and a half inches thick, and supported at two points.
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And one of the reasons why he designed roofs this way is because it's --
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he found it fascinating that you could build such a strong structure
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that's made of so few materials and can be supported by so few points.
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And all of these are the same principles that apply
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to the saddle-shaped spring in stomatopods.
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In biological systems it's important not to have a whole lot
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of extra material requirements for building it.
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So, very interesting parallels between the biological
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and the engineering worlds. And interestingly, this turns out --
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the stomatopod saddle turns out to be the first
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described biological hyperbolic paraboloid spring.
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That's a bit long, but it is sort of interesting.
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So the next and final question was, well, how much force
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does a mantis shrimp produce if they're able to break open snails?
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And so I wired up what's called a load cell.
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A load cell measures forces, and this is actually
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a piezoelectronic load cell that has a little crystal in it.
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And when this crystal is squeezed, the electrical properties change
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and it -- which -- in proportion to the forces that go in.
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So these animals are wonderfully aggressive,
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and are really hungry all the time. And so all I had to do
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was actually put a little shrimp paste on the front of the load cell,
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and they'd smash away at it.
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And so this is just a regular video of the animal
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just smashing the heck out of this load cell.
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And we were able to get some force measurements out.
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And again, we were in for a surprise.
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I purchased a 100-pound load cell, thinking,
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no animal could produce more than 100 pounds at this size of an animal.
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And what do you know? They immediately overloaded the load cell.
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So these are actually some old data
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where I had to find the smallest animals in the lab,
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and we were able to measure forces of well over 100 pounds
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generated by an animal about this big.
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And actually, just last week I got a 300-pound load cell
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up and running, and I've clocked these animals generating
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well over 200 pounds of force.
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And again, I think this will be a world record.
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I have to do a little bit more background reading,
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but I think this will be the largest amount of force produced
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by an animal of a given -- per body mass. So, really incredible forces.
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And again, that brings us back to the importance of that spring
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in storing up and releasing so much energy in this system.
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But that was not the end of the story.
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Now, things -- I'm making this sound very easy, this is actually a lot of work.
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And I got all these force measurements,
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and then I went and looked at the force output of the system.
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And this is just very simple -- time is on the X-axis
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and the force is on the Y-axis. And you can see two peaks.
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And that was what really got me puzzled.
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The first peak, obviously, is the limb hitting the load cell.
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But there's a really large second peak half a millisecond later,
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and I didn't know what that was.
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So now, you'd expect a second peak for other reasons,
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but not half a millisecond later.
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Again, going back to those high-speed videos,
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there's a pretty good hint of what might be going on.
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Here's that same orientation that we saw earlier.
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There's that raptorial appendage -- there's the heel,
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and it's going to swing around and hit the load cell.
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And what I'd like you to do in this shot is keep your eye on this,
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on the surface of the load cell, as the limb comes flying through.
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And I hope what you are able to see is actually a flash of light.
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Audience: Wow.
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Sheila Patek: And so if we just take that one frame, what you can actually see there
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at the end of that yellow arrow is a vapor bubble.
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And what that is, is cavitation.
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And cavitation is an extremely potent fluid dynamic phenomenon
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which occurs when you have areas of water
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moving at extremely different speeds.
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And when this happens, it can cause areas of very low pressure,
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which results in the water literally vaporizing.
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And when that vapor bubble collapses, it emits sound, light and heat,
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and it's a very destructive process.
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And so here it is in the stomatopod. And again, this is a situation
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where engineers are very familiar with this phenomenon,
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because it destroys boat propellers.
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People have been struggling for years to try and design
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a very fast rotating boat propeller that doesn't cavitate
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and literally wear away the metal and put holes in it,
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just like these pictures show.
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So this is a potent force in fluid systems, and just to sort of take it one step further,
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I'm going to show you the mantis shrimp approaching the snail.
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This is taken at 20,000 frames per second, and I have to give
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full credit to the BBC cameraman, Tim Green, for setting this shot up,
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because I could never have done this in a million years --
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one of the benefits of working with professional cameramen.
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You can see it coming in, and an incredible flash of light,
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and all this cavitation spreading over the surface of the snail.
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So really, just an amazing image,
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slowed down extremely, to extremely slow speeds.
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And again, we can see it in slightly different form there,
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with the bubble forming and collapsing between those two surfaces.
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In fact, you might have even seen some cavitation going up the edge of the limb.
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So to solve this quandary of the two force peaks:
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what I think was going on is: that first impact is actually
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the limb hitting the load cell, and the second impact is actually
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the collapse of the cavitation bubble.
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And these animals may very well be making use of
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not only the force and the energy stored with that specialized spring,
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but the extremes of the fluid dynamics. And they might actually be
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making use of fluid dynamics as a second force for breaking the snail.
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So, really fascinating double whammy, so to speak, from these animals.
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So, one question I often get after this talk --
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so I figured I'd answer it now -- is, well, what happens to the animal?
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Because obviously, if it's breaking snails,
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the poor limb must be disintegrating. And indeed it does.
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That's the smashing part of the heel on both these images,
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and it gets worn away. In fact, I've seen them wear away
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their heel all the way to the flesh.
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But one of the convenient things about being an arthropod
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is that you have to molt. And every three months or so
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these animals molt, and they build a new limb and it's no problem.
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Very, very convenient solution to that particular problem.
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So, I'd like to end on sort of a wacky note.
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(Laughter)
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Maybe this is all wacky to folks like you, I don't know.
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(Laughter)
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So, the saddles -- that saddle-shaped spring --
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has actually been well known to biologists for a long time,
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not as a spring but as a visual signal.
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And there's actually a spectacular colored dot
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in the center of the saddles of many species of stomatopods.
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And this is quite interesting, to find evolutionary origins
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of visual signals on what's really, in all species, their spring.
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15:10
And I think one explanation for this could be
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going back to the molting phenomenon.
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So these animals go into a molting period where they're
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unable to strike -- their bodies become very soft.
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And they're literally unable to strike or they will self-destruct.
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This is for real. And what they do is, up until that time period
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when they can't strike, they become really obnoxious and awful,
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and they strike everything in sight; it doesn't matter who or what.
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And the second they get into that time point when they can't strike any more,
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they just signal. They wave their legs around.
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And it's one of the classic examples in animal behavior of bluffing.
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It's a well-established fact of these animals
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that they actually bluff. They can't actually strike, but they pretend to.
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And so I'm very curious about whether those colored dots
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in the center of the saddles are conveying some kind of information
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about their ability to strike, or their strike force,
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and something about the time period in the molting cycle.
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So sort of an interesting strange fact to find a visual structure
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right in the middle of their spring.
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So to conclude, I mostly want to acknowledge my two collaborators,
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Wyatt Korff and Roy Caldwell, who worked closely with me on this.
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And also the Miller Institute for Basic Research in Science,
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which gave me three years of funding to just do science all the time,
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and for that I'm very grateful. Thank you very much.
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(Applause)
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