If an object in free fall near earth, then an inertial frame of reference and I see the earth accelerating towards me with no force acting upon it. What causes that acceleration?

kvasilw0

kvasilw0

Answered question

2022-08-12

If an object in free fall near earth, then an inertial frame of reference and I see the earth accelerating towards me with no force acting upon it. What causes that acceleration?

Answer & Explanation

Jakob Chavez

Jakob Chavez

Beginner2022-08-13Added 14 answers

In classical (Newtonian) mechanics, you are not in an inertial frame, so your observations are not valid: the acceleration is fictitious.
In general relativity, the solution is more subtle. You are in an inertial frame, and so is the earth. But in general relativity, inertial frames are not global. The correct way to think about the earth's motion is to determine that it is following a geodesic, and so it has no proper acceleration. The apparent acceleration of earth is purely an artifact of the frame you've chosen, just as it is in the Newtonian case.
You are both in inertial frames, that happen to have a relative acceleration between them. This can't happen with flat spacetime, but there is no contradiction once you introduce curved spacetime.
Katelyn Reyes

Katelyn Reyes

Beginner2022-08-14Added 6 answers

The force acting on the ground is the normal force of the layer of the earth right beneath the ground. The force acting on the layer right below the ground is the normal force from right below that.
Ultimately, however, you can not really understand gravity just by thinking about inertial frame. The whole inertial frame business only works locally: globally, you have to know how spacetime is curved everywhere, and solve the full Einstein equations, etc, to figure out how the earth will behave in the presence of the gravitational field. As I have said, the "force" which acts on each particle of the earth, that makes it move in non geodesic motion, is the pressure (normal force) from its fellow particles.

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