Gravity: What Forces Keep an Object in Orbit?

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The discussion centers on the forces that maintain an object's orbit, particularly focusing on the Moon. It is clarified that an object in orbit, like the Moon, does not require a force to prevent slowing down; rather, the absence of drag in space allows it to maintain its velocity. The conversation also touches on the concept of orbits depending on distance from the planet, suggesting that theoretically, an object could orbit at a very low altitude if it achieves sufficient speed. Additionally, the Moon's orbit is described as not perfectly circular, with variations in velocity due to its elliptical path. Finally, the difference in weightlessness experienced in orbit versus skydiving is explained by the presence of atmospheric drag during free fall on Earth.
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Hello, I'm new here and am very glad I found these forums, I've been seeking answers for some questions that have been bothering me for some time.

Ok, first of all I want to ask about orbits. I know what an orbit is ( a very fast object virtually falling endlessly , never touching the ground because of the Earth's curvature , like Newton's canon demonstrates). My question is though, what forces keep the certain object from not slowing down? Like the Moon, what keeps its velocity so accurate that allows the moon to complete an orbit in exactly the same amount of time as the previous one?

That will be all for now, because I'd like to keep you guys concentrated on one question, to get the best answers possible for them. I'll keep asking as we move on :D
 
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Because there is no wind resistance in space. The moon does however slowly lose energy (velocity/distance from the earth) from the gravitational interaction between it and the Earth (but this is very small).
 
pr1de said:
My question is though, what forces keep the certain object from not slowing down?
You don't need a force to stop it slowing down - you just need there to be no force to slow it down.

In practice drag from tiny bits of the outer atmosphere does slow down satelites and cause them to change orbit and eventually re-enter.
At the distance of the moon there is nothign to cause drag. There are other effects to do with tides but these actually cause the moon to speed up - the moon is moving away from us at a measurable rate
 
My 2nd question is..

Does orbit depend on distance from the planet? Say, if i would have had superman powers and could throw a rock from just 6 feet above the Earth with enough speed so that the rock can "fall" into orbit, considering there's no atmosphere to create drag, could the rock orbit the planet at just 6 feet of height, given the speed of the rock is high enough?
 
considering there's no atmosphere to create drag, could the rock orbit the planet at just 6 feet of height, given the speed of the rock is high enough?

Six feet above the surface of the Earth there definitely IS wind resistance.


Also mgb_phys, I didn't know it was speeding up! Snap... I guess it's stealing the energy from own own rotation?
 
James Leighe said:
Also mgb_phys, I didn't know it was speeding up! Snap... I guess it's stealing the energy from own own rotation?
Yes the days are getting longer
 
James Leighe said:
Six feet above the surface of the Earth there definitely IS wind resistance.


Also mgb_phys, I didn't know it was speeding up! Snap... I guess it's stealing the energy from own own rotation?

noo, i said imagine there's no atmosphere, like on the moon.
 
pr1de said:
noo, i said imagine there's no atmosphere, like on the moon.

Oh, then yeah... that's fine.
 
so it can orbit?
 
  • #10
So long as you don't stand in its path! :biggrin:

(or there aren't any hills, etc.)
 
  • #11
My third question is.. if orbiting is just a continuous free fall without any resistance , wouldn't you feel the same weightlessness when skydiving out of the plane? if yes, the how are you able to distinguish up and down while skydiving and not in space where every way you turn you feel the same?
 
  • #12
pr1de said:
My 2nd question is..

Does orbit depend on distance from the planet? Say, if i would have had superman powers and could throw a rock from just 6 feet above the Earth with enough speed so that the rock can "fall" into orbit, considering there's no atmosphere to create drag, could the rock orbit the planet at just 6 feet of height, given the speed of the rock is high enough?

Yes. Suicide method :

Go to the moon. Fire a bullet horizontally at 1679 m/s, and wait for 108 min in the same spot. :wink:

pr1de said:
My third question is.. if orbiting is just a continuous free fall without any resistance , wouldn't you feel the same weightlessness when skydiving out of the plane?
Initially yes, but then you feel resistance. You are not in free fall in the atmosphere.
 
  • #13
pr1de said:
if orbiting is just a continuous free fall without any resistance , wouldn't you feel the same weightlessness when skydiving out of the plane?
Yes. that's how you can train astronauts in a falling plane

if yes, the how are you able to distinguish up and down while skydiving and not in space where every way you turn you feel the same?
Only by wind resistance - if you skydived inside a sealed box you couldn't tell
 
  • #14
Hi pr1,
excellent...this is a great forum..just take answers as "tentative" and "mostly correct" most of the time, especially mine!

( a very fast object virtually falling endlessly , never touching the ground because of the Earth's curvature , like Newton's canon demonstrates).

does not have to be fast...for example, higher orbits require less speed..


My question is though, what forces keep the certain object from not slowing down
?

very complicated question..one I could not answer in a few sentences...but looking into gravitation and studying its various aspects will begin to give you insights for further understanding...Wikipedia is a free place to start...

In another discussion posted within the last year I posted an interesting fact that I had come across: the moon moves closer to the Earth by a small amount every year... it might have been a cm every ten years, but don't quote me on that..in any case orbits do vary for complex reasons...

Like the Moon, what keeps its velocity so accurate that allows the moon to complete an orbit in exactly the same amount of time as the previous one?

it's velocity is not really "accurate" but varies from Earth perspective as it passes in a non perfect, non circular orbit...I guess mostly elliptical...anyway the moon does not really orbit the earth, they both orbit their combined center of mass...hence the roughly elliptical orbit and the moon does NOT orbit "in exactly the same amount of time..." all we can say is that it's orbit IS fixed enough that it has been in place for many millions of years and likely will remain up there for many more millions of years...

If you want to get some insights here is a good place:

http://en.wikipedia.org/wiki/Orbit_of_the_Moon
 
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  • #15
When skydiving on earth, you reach terminal velocity.
 
  • #16
pr1de said:
My 2nd question is..

Does orbit depend on distance from the planet? Say, if i would have had superman powers and could throw a rock from just 6 feet above the Earth with enough speed so that the rock can "fall" into orbit, considering there's no atmosphere to create drag, could the rock orbit the planet at just 6 feet of height, given the speed of the rock is high enough?

Yes. period squared is proportional to radius cubed. As for the rock, yes, that is possible.
 
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