There's a reason we only ever see one side of the Moon. It's tidally locked to the Earth, presenting only one side to us as it orbits around the planet. Tidal locking is a fate that befalls lots of planetary bodies, and it can wreak havoc on the surface.
Why does tidal locking happen? And more importantly, why hasn't Earth become a tidally locked planet? And are we doomed to go that way eventually?
When the planet Zarmina was first reported as having been discovered, people got all excited about the idea of a planet existing in its star's habitable zone — only to have their excitement fade a little when they learned that Zarmina was tidally locked to its star. This reduced the chances of life, in any complex form, existing on the surface. Tidal locking does a number on a planet, and not just its surface temperature. Everything from water composition to geography changes as one side starts getting all the sunlight, and the other slowly freezes.
How Tidal Locking Happens
When a planet orbits a star, it is being pulled by the gravity of that star. The different sides of the planet are pulled to different degrees, with the side closest to the star receiving a small but noticeably larger pull. This bends the planet out of shape, from a ball into an ellipse. No water is necessary for this to happen. Even solid rock stretched out — the surfaces of both the Earth and the Moon stretch toward each other. This stretching doesn't happen immediately, though. It takes time for the planet to stretch its solid mass towards the sun and to settle back, and while it is stretching and settling, it is moving.
At first, it is moving in two different ways. It is rotating on its axis, the way the Earth does to produce night and day. It is also orbiting the star, as the Earth does to produce a year. Those two movements rarely sync up. For example, sometimes the rotation speeds past the orbit. In that case, instead of the bulges in the ellipse "pointing" directly at and away from the star, they turn past it.
The problem is, the near bulge is closer to the star than the rest of the planet, and it feels a gravitational pull dragging it backwards — so it's once again aligned with the center of the star. It doesn't necessarily get pulled all the way back, but it gets shifted a little bit. That shift happens every time the planet rotates. If the rotation is too slow and the orbit is fast, the bulge lags behind as the planet orbits forward, and the gravitational pull of the star drags it forward. No matter what, the planet gets a tug until its rotation is exactly the same period of time as its orbit. When that happens, it's tidally locked. It shows one face to the sun at all times.
Life on a Tidally Locked Planet
The immediate disadvantage of a tidally locked planet is obvious. One side of the planet cooks while the other freezes. Water on one side is vapor, and on the other side is ice. If there is any appreciable amount of life on the surface of the planet, it has to be in the twilight strip of land between the two halves.
But it's not as simple as getting the temperature right. If our atmosphere permanently lost the heat of the sun, it would first turn into a denser gas, then condense into a liquid, and then further condense into solid ice. Meanwhile, air that is constantly exposed to light — or that is heated by a ground that is constantly exposed to light — will heat up and expand.
Although it's doubtful that the atmosphere on the dark side of the planet would get to solid form, it would certainly keep condensing and leaving a vacuum to suck in the expanding hot air from the other side. This might make for circulation of atmosphere that would make the planet livable, but it would also lead to hellish storms, as the atmosphere from the light and dark side of the planet essentially switched sides continually.
And those winds may bring some very, very nasty things with them. Even geologists foresee major problems with tidally locked planets. Rock and soil erodes differently when it's exposed to different levels of light. The cool side of the planet is preserved fairly well, but the lit side of the planet is stripped of its oceans and made to face burning sun and scrubbing wind every day. It will erode faster, and rocks that might have turned to terrestrial sand in a climate with night and day may be vaporized, picked up by the wind, or dissolved in water vapor to go airborne. Life, if it manages to struggle along on such a planet, will either be underground or very, very hardy.
So will Earth become tidally locked?
So why are some planets and moons tidally locked while others are not? All planets bulge towards their stars, and all of them have their orbit slightly out of sync with their rotation. The mechanics of how it happens are the same in every case — but whether tidal locking actually happens depends on things like orbit distance, the mass of both bodies, and the malleability of the orbiting object.
Generally, closer objects are more likely to experience tidal locking. Far-away objects are less likely to experience dramatic differences in gravity between their two sides, resulting in smaller bulges, and the bulges themselves will feel less of a pull. For many stars, the habitable zone — the ring of space within which planets are able to sustain life — overlaps partially with a zone that makes planets likely to be tidally locked to their star, making them significantly less habitable.
Nervous scientists have speculated that the Earth might eventually be a tidally locked planet, but it appears that such a fate is not in store for us. At least not with the sun. The Moon, which we've already ensnared, might turn the tables on us. The Earth's rotation actually gets slowed down by the Moon a little bit each year.
Read more at Discovery News
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