Gravitational Force at the Center of the Earth?

In summary, the conversation discusses the formula for gravitational force between two masses, which is Fg= G(m1m2)/r^2. However, this formula is only valid for regions of space outside the Earth. Inside the Earth, one must use Gauss' Law, which states that the closed surface integral of the gravitational field across a closed surface is equal to 4πG times the mass enclosed by the surface. At the exact center of the Earth, the gravitational force is zero, and as one approaches the center, the force increases proportionally to the radius. This results in a form of simple harmonic motion. It is also important to note that at the center of the Earth, the mass is not concentrated, so the net
  • #1
Kaoi
21
0
Okay, this was just a curious question that's been bobbing around in my head recently.

The formula for gravitational force between two masses is

[tex]F_{g} = G \frac{m_{1}m_{2}}{r^2}[/tex]

right?

So, gravitational force increases as you approach the center of the earth. I was wondering, what is the gravitational force at the exact center of the earth? I thought it could be approximated by

[tex]\lim_{r \rightarrow 0} G \frac{m_{1}m_{2}}{r^2} = \infty[/tex]

But I know that's wrong. I just don't know why. Why wouldn't there be infinite force at the center of the earth, and if there was, why wouldn't we collapse on ourself? :rofl:
 
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  • #2
Your second formula is ok for a black hole.
For normal plannet like earth, using Gauss law we can have the folowing equation :

F(r) = G(4p*r*rho*m)/3

with rho is the density of the earth,
m : mass of the thing going to the Earth center.
r : distance to the center.

The key point is that when you go into the Earth center, the mass behind you will not have any gravitational force on you, it cancels out. So at the Earth center, the gravitational force is zero.
 
  • #3
Kaoi said:
Okay, this was just a curious question that's been bobbing around in my head recently.

The formula for gravitational force between two masses is

[tex]F_{g} = G \frac{m_{1}m_{2}}{r^2}[/tex]

right?

This equation is correct only for a location OUTSIDE the surface of the earth, i.e. r>R where R is the radius of the earth. For inside the earth, if one assumes the Earth being a sphere with a uniform density, then haiha has given the proper form to use.

Zz.
 
  • #4
Within the classical domain, Newton's general law of gravitation holds ABSOLUTELY, as long as you apply it CORRECTLY.

Your paradox with the limiting process arises because you haven't applied the law correctly.
The net result of a correct usage in this case is given in haiha's post.
 
  • #5
The formula for gravity beneath the surface of the Earth is very interesting. If you perform the calculations, you will find that gravity is zero at the Earth's center, increases proportially to to the radius r as you travel up to the surface, and then falls off as 1/r^2 after you leave the surface.
 
  • #6
Kaoi said:
Okay, this was just a curious question that's been bobbing around in my head recently.

The formula for gravitational force between two masses is

[tex]F_{g} = G \frac{m_{1}m_{2}}{r^2}[/tex]

right?

So, gravitational force increases as you approach the center of the earth. I was wondering, what is the gravitational force at the exact center of the earth? I thought it could be approximated by

[tex]\lim_{r \rightarrow 0} G \frac{m_{1}m_{2}}{r^2} = \infty[/tex]

But I know that's wrong. I just don't know why. Why wouldn't there be infinite force at the center of the earth, and if there was, why wouldn't we collapse on ourself? :rofl:

As others have already said, the formula you provided is only valid for regions of space outside the earth. Newton's theory of gravity works just fine inside the Earth as well (otherwise Newton would have noticed an obvious error!). But you need to use the integral form of Gauss' Law for gravity (you can use Newton's law itself, but the calculation is a bit more tricky). Simply put, Gauss' Law says that the closed surface integral of the gravitational field across a closed surface is equal to [tex]4 \pi G[/tex] times the mass enclosed by the surface.

I strongly recommend that you do this calculation yourself, because it only takes about 5-10 minutes, and will likely answer all of your questions. One very interesting result you'll notice is that until you get outside the surface of the earth, the gravitational force is proportional to the distance from the center of the earth. Whenever force is proportional to distance, this should remind you of simple harmonic motion. Indeed, gravitational force inside the surface of a planet is identical to the force that a stretched spring exerts on a mass. It actually turns out that if you could drill a hole from one side of the moon to the other and drop a ball through, it would go back and forth in simple harmonic motion. If you did this on the earth, then air resistance would cause the ball to experience damped harmonic motion.
 
  • #7
What you haven't taken into account, though, is that as the radius is decreased, so is the mass. Therefore, you're not dealing with a case of a finite number divided by zero, but with zero divided by zero.
 
  • #8
Mass is not concentrated at the very center. When you are below surface you are attracted not only by what is below you, but also by what is left above.
 
  • #9
Borek said:
When you are below surface you are attracted not only by what is below you, but also by what is left above.
In the simplified case considered here, where we assume a spherically symmetric mass distribution, the net attraction from the mass above you is zero.
 
  • #10
But, what this says then, is that, at the center of the earth, if you would be attracted by what is above, then the net force would be zero if we integrate all the continuous outward radial force.
 
  • #11
magujabi said:
But, what this says then, is that, at the center of the earth, if you would be attracted by what is above, then the net force would be zero if we integrate all the continuous outward radial force.

Isn't that what everyone has been trying to say? It is even stated explicitly in msg. #5 from more than 3 years ago!

Zz.
 
  • #12
Well, I just joined this forum this morning. Forgive me if I haven't read all of the messages. Since you're being so polite, though, sure, I agree now that that's what everybody has been trying to say.
 
  • #13
Doc Al said:
In the simplified case considered here, where we assume a spherically symmetric mass distribution, the net attraction from the mass above you is zero.

I know, I was just pointing to thing that was obviously missed by the OP.

Three years ago.

I need new glasses.
 
  • #14
consider this, since r>R (radius of earth) r reducing causes magnitude of force increasing, but if r<R when r reduces so the total mass of the Earth included to attract reduces too, until r=0 we'll get the total mass of the Earth covered is 0, so the total force is 0 (analogy of Gauss Law in Electric Field of an uniform distributed sphere charge say with radius R and density p(rho)..
 
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  • #15
einstor said:
consider this, since r>R (radius of earth) r reducing causes magnitude of force increasing, but if r<R when r reduces so the total mass of the Earth included to attract reduces too, until r=0 we'll get the total mass of the Earth covered is 0, so the total force is 0 (analogy of Gauss Law in Electric Field of an uniform distributed sphere charge say with radius R and density p(rho)..
Sure, this makes perfect sense. This problem unfortunately, though, doesn't lend itself to a convenient algebraic solution. Looking at the force below the surface of the earth, we can use 4/3(pi)rmp, using p for rho, the mass density of the earth. The attraction from above then, would be 4/3(pi)(R-r)mp for the attraction from above. Combining these, and since they are opposite in direction, we get F = 4/3(pi)(2r-R)mp, which says that the force is zero half way to the center. The two dimensional approach just doesn't seem give a correct answer.
 
  • #16
magujabi said:
Looking at the force below the surface of the earth, we can use 4/3(pi)rmp, using p for rho, the mass density of the earth.
This is correct, and is the formula given in post #2 by haiha. It's the gravitational force on a mass 'm' that is a distance 'r' from the center of the earth. It includes the gravitational attraction from all parts of the earth.
The attraction from above then, would be 4/3(pi)(R-r)mp for the attraction from above.
No. The attraction 'from above' is zero.
 
  • #17
Doc Al said:
The attraction 'from above' is zero.

Correct me if I am wrong, but isn't it a matter of how we define 'above'? If we assume 'above' means everything that is further from the center than we are, attraction from above is zero, as it already canceled out. But if 'above' is understood as 'whatever we have have over our heads' and 'below' means everything that we can see when we look down (that is, if we take into account our intuitive feeling of direction), then we are attracted by whatever is above AND attracted by whatever is below - and these attractions cancel out.

Or am I missing something? I am walking on a thin ice :uhh:
 
  • #18
I am new to this forum, and sorry if I have just barged in and joined discussions, but, could you expalin to me what would be the gravitational force on a ball bearing, sitting on a bench, in straight alignment and in between, two other ball bearings, one of less mass, and the other of greater mass, irrespective of the gravitational attraction of the Earth of course.
 
  • #19
Borek said:
Correct me if I am wrong, but isn't it a matter of how we define 'above'? If we assume 'above' means everything that is further from the center than we are, attraction from above is zero, as it already canceled out. But if 'above' is understood as 'whatever we have have over our heads' and 'below' means everything that we can see when we look down (that is, if we take into account our intuitive feeling of direction), then we are attracted by whatever is above AND attracted by whatever is below - and these attractions cancel out.

Or am I missing something? I am walking on a thin ice :uhh:
Well, the statement "The attraction 'from above' is zero" certainly depends on what we mean by 'above'. (That's why I put it in quotes.) From the context of this discussion, I'd say that it meant your first example: everything at a greater distance from the center. That's certainly what I meant.

I have no idea how to sharply define your second meaning, 'whatever we have have over our heads'. In any case, why would you think above and below would 'cancel out'? Wouldn't that imply gravity = 0?

In any case, the formula given in post #2 includes the gravitational attraction from all the Earth's mass. (Given the simplifying assumption of a uniform distribution of mass.)
 
  • #20
Doc Al said:
I have no idea how to sharply define your second meaning, 'whatever we have have over our heads'. In any case, why would you think above and below would 'cancel out'? Wouldn't that imply gravity = 0?

As usual, lack of precision on my side :redface:

I am somewhere inside. Earth mass consist of inner and outer part (which are what you defined as above and below). Outer shell has part that is below and above (my definition of above/below), and their attractions cancel out. Above and below are separated by the plane (marked in red). Inner sphere is what is left attracting.

It is a little bit convoluted, but it better fits my feeling about what is above/below. In the end it yields the same result.
 

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  • #21
Borek said:
I am somewhere inside. Earth mass consist of inner and outer part (which are what you defined as above and below). Outer shell has part that is below and above (my definition of above/below), and their attractions cancel out. Above and below are separated by the plane (marked in red). Inner sphere is what is left attracting.
Ah... so 'above' and 'below' refer to the two parts of the outer shell. OK, now what you said makes sense.

You are one crazy dude, Borek! :tongue:
 
  • #22
Doc Al said:
No. The attraction 'from above' is zero.

But, if we try and resolve that formula given by haiha in post #2 with the graphic explanation given by Borek, we would have to modify that formula to state F = 4/3(pi)(2r-R)mp, to take into consideration the force that is cancelled. I still don't see from that graphic, though, what the masss "above," i.e. radially toward the surface, geometrically cancels with. I am assuming I am missing something, but still, since it cancels, wouldn't it have to be subtracted... from haiha's formula?
 
  • #23
magujabi said:
But, if we try and resolve that formula given by haiha in post #2 with the graphic explanation given by Borek, we would have to modify that formula to state F = 4/3(pi)(2r-R)mp, to take into consideration the force that is cancelled. I still don't see from that graphic, though, what the masss "above," i.e. radially toward the surface, geometrically cancels with. I am assuming I am missing something, but still, since it cancels, wouldn't it have to be subtracted... from haiha's formula?
No. Haiha's formula describes the full gravitational attraction experienced by a mass at some distance from the Earth's center (when that distance is less than the radius of the earth). It includes the attraction from all parts of the earth.

You can divide the Earth's mass into two pieces:
(1) the part of the Earth that less than or equal to a distance 'r' from the center; think of this as the inner core;
(2) the part of the Earth that is greater than a distance 'r' from the center; think of this as the outer shell.

It just so happens that the gravitational field from a uniform shell of mass is zero at all points within the shell. (This was proven by Newton long ago; it is one of Newton's Shell theorems.) That means that the outer shell (2) does not contribute to the force felt by the mass at location 'r'. All of the gravitational force at location 'r' is due to the attraction of the inner core (1).

What Borek was doing was dividing the outer shell (2) into two parts: a part 'above' and a part 'below'. The attraction from each of those parts cancel. (His terminology confused me at first.)
 
  • #24
Doc Al said:
You can divide the Earth's mass into two pieces:
(1) the part of the Earth that less than or equal to a distance 'r' from the center; think of this as the inner core;
(2) the part of the Earth that is greater than a distance 'r' from the center; think of this as the outer shell.

It just so happens that the gravitational field from a uniform shell of mass is zero at all points within the shell. (This was proven by Newton long ago; it is one of Newton's Shell theorems.) That means that the outer shell (2) does not contribute to the force felt by the mass at location 'r'. All of the gravitational force at location 'r' is due to the attraction of the inner core (1).

This is the explanation I have been seeking. Embarrassed, I have to admit I was unaware of Newton's Shell Theorems. I will sleep better tonight. Thank you. :smile:
 

1. What is the magnitude of gravitational force at the center of the Earth?

The magnitude of gravitational force at the center of the Earth is approximately 9.8 meters per second squared (m/s²). This is due to the mass of the Earth pulling objects towards its center.

2. Does the gravitational force at the center of the Earth change?

No, the gravitational force at the center of the Earth remains constant. This is because the mass of the Earth is evenly distributed throughout its entire volume, leading to a consistent gravitational force at all points within the Earth.

3. How does the gravitational force at the center of the Earth compare to the surface?

The gravitational force at the center of the Earth is greater than the force at the surface. This is due to the fact that as you move closer to the center of an object, the gravitational force increases.

4. What is the direction of the gravitational force at the center of the Earth?

The gravitational force at the center of the Earth acts in all directions, pulling objects towards the center. This is known as a radial force, where the direction of the force is always towards the center of the object.

5. How does the gravitational force at the center of the Earth affect objects on the surface?

The gravitational force at the center of the Earth is responsible for keeping objects on the surface from floating away into space. It also determines the weight of objects on the surface, as the force of gravity pulls them towards the center of the Earth.

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