Why do we only see one side of the moon?

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In summary: Okay, so you're asking why the Earth doesn't fall into the Sun.- WarrenIn summary, the conversation revolves around the rotation of the Moon and the Earth, and how they are not rotating at the exact same speed as originally believed. It is explained that the Moon is actually tidal locked in the Earth's gravity, causing it to rotate at the same speed it revolves around the Earth. The concept is further demonstrated with visual aids and links to additional information. There is also a discussion about ego and rationality, and a question about why planets in the Sun's orbit don't drift towards it. Ultimately, it is concluded that gravity is what keeps the planets
  • #1
Azrioch
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My friend who is taking an Astronomy course said that the Moon and the Earth rotate at the exact same speed because the Earth and Moon were both hit by something at the same time... or something to that effect. It didn't really make logical sense to me.

Does anyone know why we only see one side of the moon?
 
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  • #2
Greetings!

I think he has something wrong there as well. The moon and the Earth do not rotate at the same speed. Rather, the moon rotates at the same speed that it revolves around the earth. This is because it is tidal locked in the Earth's gravity.

This site has some good info for you:
http://starryskies.com/The_sky/events/lunar-2003/eclipse9.html
 
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  • #3
Welcome to Physics Forums, Azrioch! :smile:

Like Brad_Ad23 said, the Moon and Earth don't rotate (spin on their axis) at the same speed.

Visual aid...Take a quarter and a penny (or whatever 2 Italian coins that have faces). Lay them flat and move the penny around the quarter (orbit) such that the face on the penny is always facing the quarter. See that the orbital period of the penny (once around the quarter) matches the penny's period of rotation (one spin on its own axis). That's essentially the earth-moon situation.

As explained by the links provided, this is due to gravity which pulls the Earth and Moon into a slightly elongated shape (like how the moon rises the ocean tides on the Earth...this works on rock too just to a much lesser extent). As that elongated shape rotates forward (with the rotation of the planet/moon), there is a slight braking action as the gravity of the other pulls back on that raised portion. The Moon's rotation has been slowed to a point where it's rotation speed matches it's orbital period. So it maintains the same face toward the Earth. But the moon still rotates with respect to the sun (as you see from the quarter/penny example).

more helpful links...
http://itss.raytheon.com/cafe/qadir/q866.html
http://www.seds.org/billa/tnp/luna.html [Broken]
 
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  • #4
If the same side of the moon is always facing Earth then it is not rotating around it's own axis at all. According to GR, the moon is following a "straight path" around the Earth.
 
  • #5
Originally posted by AndersHermansson
If the same side of the moon is always facing Earth then it is not rotating around it's own axis at all. According to GR, the moon is following a "straight path" around the Earth.
You're an idiot.

- Warren
 
  • #6
Originally posted by AndersHermansson
If the same side of the moon is always facing Earth then it is not rotating around it's own axis at all. According to GR, the moon is following a "straight path" around the Earth.

If you face a lampost and walk around it, always facing toward it, you will find that the landscape behind it rotates the same way it would if you stood still and turned around. In fact you will successively face every point of the compass. To put it shortly, you will have turned around. And that's what the moon does vis-a-vis the earth.
 
  • #7
Originally posted by chroot
You're an idiot.

- Warren
 
  • #8
Originally posted by chroot
You're an idiot.

- Warren
So unnecessary.[zz)]
 
  • #9
Originally posted by chroot
You're an idiot.

- Warren

Hi Warren,
How are you doing, I mean really?

You seem like such a nice guy and your comments demonstrate your absolute brilliance in deconstructing the errors you find in all of these silly questions! ((who needs questions anyway when one has all the answers?... oops!))

Keep up the good work and maybe some day you will win the Nobel Prize for insightful criticism!

:smile:
 
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  • #10
Hell, I'd be happy with the Nobel in physics, personally.

Some questions beg answers; some statements beg intelligent counterpoint. Others... simply aren't worth it.

- Warren
 
  • #11
Originally posted by chroot
Hell, I'd be happy with the Nobel in physics, personally.

Some questions beg answers; some statements beg intelligent counterpoint. Others... simply aren't worth it.

- Warren

And so why make the effort to belittle someone? Oh yes, it is to state your superiority for everyone to see. What else could it be?
 
  • #12
Originally posted by subtillioN
And so why make the effort to belittle someone? Oh yes, it is to state your superiority for everyone to see. What else could it be?
Why yes, you're correct. I am, in fact, better than you. Good of you to see it. :)

- Warren
 
  • #13
Originally posted by chroot
Why yes, you're correct. I am, in fact, better than you. Good of you to see it. :)

- Warren

so your ego escapes into the open...
 
  • #14
Originally posted by subtillioN
so your ego escapes into the open...
Was it ever contained?

- Warren
 
  • #15
Originally posted by chroot
Was it ever contained?

- Warren


ok so it has taken over your rationality...which apparently is not hard to do.
 
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  • #16
To respond to SelfAdjoint,

In a very weak sense you are correct. Orbits are merely the paths of least action in a warped spacetime, however, it does not necessitate an object in orbit not rotate. See for example: The Earth rotates as it revolves around the sun.

It is merely that at certain distances, gravity tidal locks objects into a rotational period equal to the revolutionary period.
 
  • #17
i read also that the moon is moving away from the earth.. something like an inch a year.. or half inch..

would take some time to break free i guess
 
  • #18
Yep, the Earth is slowing its rotation, becoming tidally locked to the Moon. To conserve angular momentum, the Moon's orbit increases a little.

- Warren
 
  • #19
how come planets that are in the suns orbit don't drift towards the sun slowly?
 
  • #20
Originally posted by kleinma
how come planets that are in the suns orbit don't drift towards the sun slowly?
Er, why would they?

- Warren
 
  • #21
Originally posted by chroot
Er, why would they?

- Warren

gravity? i mean i obviously know that they don't drift towards the sun... but why not.. if the suns gravity pulls things towards it.. as Earth's gravity does, then why doesn't the sun draw the planets in?
 
  • #22
Originally posted by kleinma
gravity? i mean i obviously know that they don't drift towards the sun... but why not.. if the suns gravity pulls things towards it.. as Earth's gravity does, then why doesn't the sun draw the planets in?

The gravitational pull of the sun is supposedly exactly offset by the tangential velocity of the earth. It is in a constant state of acceleration (falling) toward the sun but it's tangential velocity keeps it from ever reaching it. This Newtonian assumption, of course, is how we "measure" the mass of these bodies, by simply fitting the equations to the observation of the orbit and the speed. But this in turn rests on further assumptions of the mass of the Earth and the mass of the sun. The whole thing could be way off if a single one of these assumptions is incorrect, which the plasma model seems to suggest. The masses of these objects may be very much less than our current estimates.


The question is whether the gravitational Newtonian interpretation is even correct, given the new Plasma models of the solar system. The regularity of the orbits (as seen in Bode's law and the same pattern is seen in the structure of the electron shells of an atom) may in fact be due to more of an electro-magnetic harmonic resonance than a simple gravitational accident. Such a purely gravitational scheme fails to explain the extreme regularity of the orbits of the solar system and much else including the rotational curve of the galaxies.

A good test would be to place an object in the orbit of the Earth and cancel its tangential motion wrt the sun to see if it falls toward the sun. Does anyone know if this test has ever been done?


---------------

on a tangential note...

Does anyone know if the interplanetary probes are/were sent along the plane of the ecliptic of the solar system or if they are offset to escape the interstellar debris that collects upon this plane?

In all the images I have seen it seen they appear to be offset from the plane, but perhaps there have been a few that have traveled directly through another orbital intersection with the plane of the ecliptic?

There may be some data in those experiments which point to the resonance mechanism hinted at above.
 
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  • #23
Originally posted by subtillioN


A good test would be to place an object in the orbit of the Earth and cancel its tangential motion wrt the sun to see if it falls toward the sun. Does anyone know if this test has ever been done?



Yes, everytime we've launched a probe into an orbit that takes it in closer to the Sun. In fact, if any of our "assumptions" of celestrial mechanics were of by any significant amount, none of our probes would have ever reached their destinations.
 
  • #24
Originally posted by Janus
Yes, everytime we've launched a probe into an orbit that takes it in closer to the Sun. In fact, if any of our "assumptions" of celestrial mechanics were of by any significant amount, none of our probes would have ever reached their destinations.

Very true, but do you know if any of the probes have crossed the plane of the ecliptic at any of the planetary orbits?
 
  • #25
Originally posted by subtillioN
Very true, but do you know if any of the probes have crossed the plane of the ecliptic at any of the planetary orbits?

They all have. The probes are launched along Earth's orbital plane. They follow this trajectory until they reach that point where the Earth's and destination planet's orbital planes cross, at which point they do what is known as a "broken plane maneuver" , which tranfers them to the orbital plane of the destination planet.
 
  • #26
Originally posted by Janus
They all have. The probes are launched along Earth's orbital plane. They follow this trajectory until they reach that point where the Earth's and destination planet's orbital planes cross, at which point they do what is known as a "broken plane maneuver" , which tranfers them to the orbital plane of the destination planet.

Thank you very much. :smile:
 
  • #27
can you explain tangential velocity a little better to someone that isn't very physics savy
 
  • #28
Tangential velocity is just velocity in the direction perpendicular to the force of gravity that would be felt by the probe.
eg. The moon orbits around the Earth and so feels a gravitational force towards the earth.
The thing that stops the moon from falling into the Earth is its tangential velocity (velocity perp. to this force)
 
  • #29
Originally posted by kleinma
gravity? i mean i obviously know that they don't drift towards the sun... but why not.. if the suns gravity pulls things towards it.. as Earth's gravity does, then why doesn't the sun draw the planets in?
Thats the definition of an orbit.

A common way to put it is that all of the planets ARE accelerating (or falling) toward the sun. The just also happen to be moving tangentially at the exact rate necessary to cancel that acceleration.
 
  • #30
Originally posted by russ_watters
Thats the definition of an orbit.

A common way to put it is that all of the planets ARE accelerating (or falling) toward the sun. The just also happen to be moving tangentially at the exact rate necessary to cancel that acceleration.

Well, of course it doesn't really cancel out the acceleration so much as it offsets it tangentially.
 
  • #31
Originally posted by russ_watters
Thats the definition of an orbit.

A common way to put it is that all of the planets ARE accelerating (or falling) toward the sun. The just also happen to be moving tangentially at the exact rate necessary to cancel that acceleration.

but it can't just be coincedence that they move tangentially at the rate needed to prevent moving towards the sun, what is the reason that they do this?
 
  • #32
Originally posted by kleinma
but it can't just be coincedence that they move tangentially at the rate needed to prevent moving towards the sun, what is the reason that they do this?

That is an excellent point. The standard model assumes that these regularly spaced orbits (modeled by Bodes Law) happened by accident. This same pattern of regularly spaced orbits is encountered in the electronic shell spacing of the atoms. Can this be a mere coincidence? I think not. There must be some other mechanism involved in the formation of orbits that applies to the orbits of the electrons as well. It is a quantum level fluid-dynamic wave-resonance mechanism and it is modeled in a new Unified Field Theory called Sorce Theory.

See www.anpheon.org
 
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  • #33
*slaps head*

It is just a coincidence. Why? Because the orbits that these planets happen to have formed in are stable, and hence will remain. There are many other solar systems discovered that are in no way like our own.

Planets travel in things called orbits. Orbital velocity is defined as follows:

The velocity necessary so that for every meter you fall the body you are orbiting curves 1 meter away from you. In other words, bodies in orbit are indeed in free fall. The only thing that distinguishes an orbiting body from a non-orbiting one, is that the non-orbiting one will not have enough velocity and will tend to fall more than it moves. A body that orbits is balanced. And obviously one that moves far faster than the other body curves away under it will break orbit.
 
  • #34
Originally posted by Brad_Ad23
*slaps head*

It is just a coincidence. Why? Because the orbits that these planets happen to have formed in are stable, and hence will remain. There are many other solar systems discovered that are in no way like our own.


Of course. That is how we have detected them. They have giant orbiting planets that exert a massive pull on their star.The fact is that we don't know all the detals of these solar systems either, such as all the orbits of all the planets.
 
  • #35
It doesn't matter we don't know all the details. What matters is that the orbits are more or less random, and the ones that ar stable, as in any chaotic system, will tend to last longer than those that are not.
 
<h2>1. Why do we only see one side of the moon?</h2><p>This is because the moon's rotation and orbit around the Earth are synchronized, meaning that it takes the same amount of time for the moon to rotate on its axis as it does to complete one orbit around the Earth. As a result, the same side of the moon always faces the Earth.</p><h2>2. Is there any scientific explanation for why we only see one side of the moon?</h2><p>Yes, the phenomenon of only seeing one side of the moon is known as tidal locking. It is caused by the gravitational pull of the Earth on the moon, which has caused the moon's rotation to become synchronized with its orbit.</p><h2>3. Can we ever see the other side of the moon?</h2><p>Yes, it is possible to see the other side of the moon, but only with the help of spacecraft. In 1959, the Soviet spacecraft Luna 3 captured the first images of the far side of the moon. Since then, various other spacecraft have also captured images of the far side of the moon.</p><h2>4. Does the moon rotate at all?</h2><p>Yes, the moon does rotate on its axis, but it takes the same amount of time to rotate as it does to orbit the Earth, which is why we only see one side of the moon from Earth.</p><h2>5. Will we ever be able to see the other side of the moon from Earth?</h2><p>No, it is highly unlikely that we will ever be able to see the other side of the moon from Earth. The moon's rotation and orbit are expected to remain synchronized for billions of years, unless there is a significant change in its orbit or a collision with another celestial body.</p>

1. Why do we only see one side of the moon?

This is because the moon's rotation and orbit around the Earth are synchronized, meaning that it takes the same amount of time for the moon to rotate on its axis as it does to complete one orbit around the Earth. As a result, the same side of the moon always faces the Earth.

2. Is there any scientific explanation for why we only see one side of the moon?

Yes, the phenomenon of only seeing one side of the moon is known as tidal locking. It is caused by the gravitational pull of the Earth on the moon, which has caused the moon's rotation to become synchronized with its orbit.

3. Can we ever see the other side of the moon?

Yes, it is possible to see the other side of the moon, but only with the help of spacecraft. In 1959, the Soviet spacecraft Luna 3 captured the first images of the far side of the moon. Since then, various other spacecraft have also captured images of the far side of the moon.

4. Does the moon rotate at all?

Yes, the moon does rotate on its axis, but it takes the same amount of time to rotate as it does to orbit the Earth, which is why we only see one side of the moon from Earth.

5. Will we ever be able to see the other side of the moon from Earth?

No, it is highly unlikely that we will ever be able to see the other side of the moon from Earth. The moon's rotation and orbit are expected to remain synchronized for billions of years, unless there is a significant change in its orbit or a collision with another celestial body.

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