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  • Y’know, if Shakespeare had been an astronomer, he’d have said thatthere is a tide in

  • the affairs of the Universe, and on such a full sea are we now afloat.”

  • He wouldve been right. You might just think of tides as the ocean going in and out every

  • day, but in fact what astronomers call tides are a subtle but inexorable force that have

  • literally shaped most objects in the Universe.

  • And to understand tides, we start with gravity.

  • Gravity is a force, and it weakens with distance. An important thing to note is that we measure

  • gravity from the center of mass of an object, not its surface. One way to think of the center

  • of mass of an object is the average position in an object of all its mass. For an evenly

  • distributed sphere, that’s it’s center.

  • Right now, unless youre an astronaut, youre about 6400 kilometers from the center of the

  • Earth. If you stand up, your head is a couple of meters farther away from the Earth’s

  • center than your feet. Since gravity weakens with distance, the force of Earth’s gravity

  • on your head is an eensy weensy bit less than it is on your feet. How much less? A mere

  • 0.00005%. And that’s way too small for you to ever notice.

  • But what if you were taller? Well, the taller you are, the farther your head is from the

  • Earth’s center, and the weaker force it will feel. If you were, say, about 300 kilometers

  • tall, the force of gravity would drop by about 10% at your head. That probably would be enough

  • to notice, if you weren’t dying from asphyxiation and, y’know, being 300 kilometers tall.

  • This change in the force of gravity over distance is what astronomers call the tidal force.

  • When you have a massive object affecting another object with its gravity, its tidal force depends

  • on several factors. For one thing, it depends on how strong the gravity is from the first

  • object; the stronger the force of gravity, the stronger stronger the tidal force will be on the affected object.

  • It also depends on how wide the affected object is. The wider it is, the more the force of

  • gravity from the first object changes across it, and the bigger the tidal force.

  • Finally, it depends on how far the affected object is from the first object. The farther

  • away the affected object is, the lower the tidal force will be. Tides depend on gravity,

  • and if gravity is weaker, so is the tidal force.

  • The overall effect of the tidal force is to stretch an object. Youre applying a stronger

  • force on one end than you are on the other, so youre pulling harder on one end. Thatll

  • stretch it! And this is where tidal forces become very important.

  • Look at the Moon. It has gravity, but much less than the Earth because it’s less massive.

  • It’s 380,000 kilometers away, so the gravitational force it has on you is pretty small. And youre

  • pretty small compared to that distance, just a couple of meters long from head to feet.

  • But the Earth is big! It’s nearly 13,000 kilometers across. That means the side of

  • the Earth facing the Moon is about 13,000 kilometers closer to the Moon than the other

  • side of the Earth. This is a pretty big distance, enough for tides to become important. The

  • side of the Earth facing the Moon is pulled harder by the Moon than the other side of

  • the Earth, so the Earth stretches. It becomes ever so slightly football-shaped, like a sphere

  • with two bulges, one pointing toward the Moon, and one pointing away.

  • This is probably the weirdest thing about tidal forces. You might expect only one bulge,

  • on the side of the Earth facing the Moon. But remember, we measure gravity from the

  • centers of objects. The side of the Earth facing the Moon feels a stronger pull toward

  • the Moon than the Earth’s center, so it’s pulled away from the center.

  • But the side facing away from the Moon feels a weaker force toward the Moon than the Earth’s

  • center. This means the center of the Earth is being pulled away from the far side. This

  • is exactly the same as if the far side is being pulled away from the center, and that’s

  • why you get two bulges on opposite sides of the Earth.

  • The tidal force is therefore strongest on the sides of the Earth facing toward and away

  • from the Moon, and weakest halfway in between them on each side.

  • A lot of the Earth is covered in water, and water responds to this changing force, this

  • stretching. The water bulges up where the tidal force is strongest, on opposite sides

  • of the Earth. If there’s a beach on one of those spots, the water will cover it, and

  • we say it’s high tide. If a beach is where the tidal force is low, the water’s been

  • pulled away from it, and it’s low tide.

  • But wait a second: The Earth is spinning! If youre on the part of the Earth facing

  • the Moon, youre at high tide. Six hours later, a quarter of a day, the Earth’s rotation

  • has swept you around to the spot where it’s low tide. Six hours after that youre at

  • high tide again, and then another six hours later youre at low tide for the second

  • time that day. Finally, a day after you started, youre back at high tide once more.

  • And that’s why we have two high tides and two low tides every day. Very generally speaking,

  • the ocean tide causes the sea level to rise and fall by a meter or two, every day.

  • Incidentally, the solid Earth can bulge as well. It’s not as fluid as water, but it

  • can move. The tidal force stretches the solid Earth by about 30 centimeters. If you just

  • sit in your house all day, you move up and down by about that much...twice!

  • Like the saying goes, a rising tide lifts allsurfaces.

  • The Earth’s spin has another effect. Lag in the water flow means the water can’t

  • respond instantly to the tidal force from the Moon. The Earth’s spin actually sweeps

  • the bulges forward a bit along the Earth. So picture this: the bulge nearest the Moon

  • is actually a bit ahead of the Earth-Moon line.

  • That bulge has mass; not a lot, but some. Since it has mass, it has gravity, and that

  • pulls on the Moon. It pulls the Moon forward in its orbit a bit, like pulling on a dog’s

  • leash, accelerating it. The Moon responds to this tug by going into a higher orbit:

  • The Moon is actually moving away from the Earth! The rate of recession of the moon has

  • been measured and it’s something like a few centimeters per year, roughly the same

  • speed your fingernails grow.

  • Now get this: the Moon has gravity. Just as the bulge is pulling the Moon ahead, the Moon

  • is pulling the bulge back, slowing it down. Because of friction with the rest of the Earth,

  • this slowing of the bulge is actually slowing the rotation of the Earth itself, making the

  • day longer. The effect is small, but again it’s measurable.

  • OK, let’s get a little change of perspective. Everything I’ve said about the Moon’s

  • tidal effect on the Earth works the other way, too. The Moon feels tides from the Earth,

  • and theyre pretty strong because the Earth is more massive and has more gravity than

  • the Moon. Just like Earth, there are two tidal bulges on the Moon; one facing the Earth and one facing away.

  • Long ago, the Moon was closer to the Earth, and spinning rapidly. The Moon’s tidal bulges

  • didn’t align with the Earth, and the Earth’s gravity tugged on them, slowing the Moon’s

  • spin and moving it farther away. As it moved farther away, the time it took to orbit once

  • around the Earth increased: Its orbital period got longer. Eventually, the lengthening rotation

  • of the Moon matched how long it took to go around the Earth. When that happened, the

  • axis of the bulges pointed right at the Earth.

  • That’s why the Moon only shows one face to us! It spins once per month, and goes around

  • us once per month. If it didn’t spin at all, over that month we’d see the entire

  • lunar surface. But since it does spin once per orbit, we only ever see one face.

  • This is called tidal locking, and it’s worked on nearly every big moon in the solar system;

  • tides from their home planet have matched their spin and orbital period. These moons

  • all show the same face toward their planet!

  • Now wait a second. If the Moon has gravity, which causes tides, and is the root cause

  • behind all these shenanigans, what about the Sun? It’s even bigger than the Moon!

  • Tides depends on the gravity from an object, and your distance from it. The Sun is far

  • more massive than the Moon, but much farther away. These two effects largely cancel each

  • other out, and when you do the math, you find the Sun’s tidal force on the Earth is just

  • about half that of the Moon’s. The way the Sun’s tidal force and the Moon’s tidal

  • force interact on Earth depends on their geometry, which changes as the Moon orbits us.

  • At new Moon, the Earth, Moon, and Sun are in a line. The Moon’s tidal force aligns

  • with the Sun’s, reinforcing it. This means we get an extra high high tide and an extra

  • low low tide on Earth. We call this the spring tide.

  • When the Moon is at first quarter, the tidal bulge from the Moon is 90° around from the

  • Sun’s; high tide from the Moon overlaps low tide from the Sun. We get a slightly lower

  • high tide, and a slightly higher low tide. We call those neap tides.

  • The pattern repeats when the Moon is full; the Moon, Earth, and Sun fall along a line

  • again, and we get spring tides. A week later the Moon has moved around, and we get neap tides again.

  • Not only that, the Moon orbits the Earth on an ellipse. When it’s closest to us we feel

  • a stronger effect. If that also happens at New or Full Moon, we get an added kick to

  • the spring tides. This is called the proxigean tide, and can lead to flooding in low-lying areas.

  • Unless you live on the coast, I bet you had no idea tides were so complex!

  • Tides are universal; they work wherever there’s gravity. If two stars orbit each other, each

  • raises a tide in the other. Just like the Earth and Moon, that can slow their spin and

  • increase their separation. Many planets orbiting other stars may be tidally locked to those

  • stars. Near a black hole, where the gravity is incredibly intense, the tides are so strong

  • they would pull you like taffy into a long, thin string. Astronomers call this effect

  • spaghettification. No, seriously, that’s what we call it!

  • Today you learned that tides are due to the changing force of gravity over distance. The

  • strength of the tidal force from an object depends on the gravity of the object, and

  • the size of and distance to the second object. Tides raise two bulges in an object, creating

  • two high tides and two low tides per day on Earth. Tides have slowed the Earth’s rotation,

  • moved the Moon away from the Earth, and locked the Moon’s rotation and orbit so that the

  • Moon always has one side facing us.

  • So. Tide goes in. Tide goes out. It turns out, I can explain that. Now you can too.

  • Crash Course is produced in association with PBS Digital Studios. This episode was written

  • by me, Phil Plait. The script was edited by Blake de Pastino, and our consultant is Dr.

  • Michelle Thaller. It was co-directed by Nicholas Jenkins and Nicole Sweeney, and the graphics

  • team is Thought Café.

Y’know, if Shakespeare had been an astronomer, he’d have said thatthere is a tide in

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潮汐天文學速成班#8 (Tides: Crash Course Astronomy #8)

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    葉子瑄 發佈於 2021 年 01 月 14 日
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