Drop the Moon 1m From the Earth, what's the acceleration?

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Discussion Overview

The discussion revolves around the hypothetical scenario of dropping the Moon from a height of 1 meter towards the Earth, exploring the implications for gravitational acceleration and the interaction between the two celestial bodies. Participants examine the principles of gravitational attraction, free fall, and the effects of mass on acceleration, with a focus on theoretical and conceptual aspects.

Discussion Character

  • Exploratory
  • Technical explanation
  • Conceptual clarification
  • Debate/contested

Main Points Raised

  • Some participants assert that free fall acceleration is independent of mass, citing known values for Earth and Moon.
  • Others propose using Newton's laws to compute gravitational forces and accelerations, emphasizing the role of mass and distance in these calculations.
  • A participant highlights that the gravitational force between two masses is symmetric and that the acceleration of one mass due to the other does not depend on its own mass.
  • There is a discussion about the relative acceleration of two objects and how it depends on both masses, while free fall acceleration can be considered mass-independent in certain contexts.
  • Some participants reference a previous discussion about the falling rates of different objects on the Moon, questioning the simplifications made in reasoning about mass and acceleration.
  • Concerns are raised about the Moon's response to gravitational forces, suggesting that it cannot be treated as a rigid body in all scenarios.

Areas of Agreement / Disagreement

Participants express varying views on the dependency of acceleration on mass, with some agreeing that free fall can be treated as mass-independent in specific cases, while others emphasize the importance of considering both masses in gravitational interactions. The discussion remains unresolved regarding the implications of these concepts in the hypothetical scenario presented.

Contextual Notes

Participants note limitations in applying simplified models to complex gravitational interactions, particularly regarding the Moon's physical response and the assumptions made in calculations. There is also mention of the need to consider the effects of distance and the nature of the bodies involved.

mm2ps
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We know that free fall acceleration is independent of mass.

9.8 m/s^2 on the Earth Surface

and

1.63 m/s^2 on the Surface of the Moon.

But what would happen if you dropped the Moon on the Earth or, the other way around, dropped the Earth on the Moon? Which acceleration would it be? Is the acceleration indeed have some dependency on mass?



Douglas
 
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You can compute this yourself by equating Newton's second law with his third law.
 
The general formula that describes the gravitational attraction between two objects is
[tex]F = \frac{G M_1 M_2}{r^2}[/tex]
where G is the gravitational constant and r is the distance between the centers of gravity. When you take M1 = mass of the Earth or moon, and r approximately equal to the radius of the Earth or moon (the radius of the Earth is about 6000 kilometers, so dropping an object at 1 meter above its surface would make it a negligible 6000,001 kilometers) you can write this as
[tex]F = M_2 g[/tex]
where
[tex]g = \frac{G M_1}{R^2}[/tex]

If you use this formula, you always get the right answer. In the case of earth/moon attraction I would suggest using it, because - unlike an apple falling towards the Earth - the attraction of one to the other is not negligible for either.
 
Consider two masses M1 and M2 (one could be Earth, the other the Moon). The force that M1 exerts on M2 is given by:

F = - M1 M2 G/r^2 r-hat

Here r is the distance between the two masses, G the gravitational constant and r-hat is the unit vector that points from M1 to M2. By Newton't third law the foce that M2 exerts on M1 should be the same in magnitude, but the opposite in sign. You can see this from the above formula. If we had taken M1 to denote the other mass, then everything would be reversed, but the formula is symmetric, except that r-hat would point in the opposite direction.

From Newton's second law:

F = M a

it follows that the acceleration of M2 due to the gravitational force of M1 is given by:

a2 = - M1 G/r^2 r-hat

This does not depend on the mass M2. In case of the Moon, you see that the Moon will not accelerate at 1 g, because the Moon is very far from the Earth (note that r should be taken from the center of the Eart, so the value of g at the Earth's surface follows by putting r = 6378 km, the radius of the Earth).

Similarly, you also see that M1 accelerates toward M2. To find the relative acceleration, you need to add up the two accelerations.


Note that the Moon is always accelerating toward the Earth. As the Moon revolves around the Earth, it's velocity is constantly changing direction in the direction of Earth. This is called centripetal acceleration. This explains why the Moon isn't falling down on the Earth, despite it accelerating toward the Earth.
 
So are you all saying that the relative acceleration does depend on both objects, however, when we talk about free fall being independent of mass, as it is generally between Earth and an object with negligible mass it can be ignored?



Douglas
 
Yes. Both objects attract each other.
But yes, usually you can ignore one.

If you wonder why, try using the "full" law to calculate the acceleration of the Earth due to a 100 g object at 1 meter above its surface (using F = m a).
[Note that the force is always the same by the way, it's because of the m in F = m a that the same force leads to different accelerations hence motions.]
 
mm2ps said:
So are you all saying that the relative acceleration does depend on both objects, however, when we talk about free fall being independent of mass, as it is generally between Earth and an object with negligible mass it can be ignored?
While the relative acceleration of two objects toward each other does indeed depend on both objects masses, the acceleration of either object from the perspective of an inertial observer only depends on the mass of the other object. In this sense, free fall acceleration truly is mass-independent.
 
There was a discussion some time ago on another forum if a feather and a hammer would take precisely the same time to fall when dropped from rest at some height above the Moon's surface.

Soon in that discussion the Moon had to be replaced by an ideal Moon that had no atmosphere at all, otherwise that would be a trivial dominant effect.

Some said that the Moon will accelerate to the hammer more than to the feather. But I objected to this simplistic reasoning, because you cannot pretend that the entire Moon will react as a rigid body. When you are standing on the Moon your feet are depressing the Moon's surface a bit. When the hammer is dropped the surface rebounds. This perturbation will eventually travel to all parts of the Moon's interior.
 

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