A Question Concerning Gravitational Potential Energy

AI Thread Summary
The discussion centers on the concept of gravitational potential energy, specifically the formula U_{r} = -Gm_{1}m_{2}/r, and whether it represents the potential energy of individual bodies or the total energy of their interaction. It is clarified that U represents the total gravitational potential energy of the system involving both masses. When discussing potential energy for one object, it is suggested that this is a simplification that does not capture the full symmetry of the system. The conversation also touches on how to approach problems involving two bodies of similar sizes, emphasizing the need to calculate the difference in potential energy at different distances to determine kinetic energy. Understanding these nuances is essential for solving gravitational problems accurately.
Silvius
Messages
13
Reaction score
0
Hey guys,

I'm currently trying to get my head around the concept of gravitational potential energy;

U_{r} = -\frac{Gm_{1}m_{2}}{r}

My question concerns whether this relates to both bodies in the system individually, or together.

That is, if I have two masses separated by a distance r, does the above formula describe the gravitational potential energy possessed by one of those bodies, or does it describe the total potential energy of the interaction between the two bodies? Or, another way of looking at it - is the total energy of the system U or 2U?

Thanks!
 
Physics news on Phys.org
\vec{r} is measured from the origin, wherever you choose to place that. Each object in general has it's own \vec{r} coordinate, and thus will have a different potential. Note that the potential of each object depends on the location of the origin.
 
rcgldr said:
Ur is the total gravitational potential energy of the system.

Hmm okay. I guess it's just a bit confusing since people/questions often seem to refer simply to one of the bodies having the potential energy given by that equation (e.g., "a satellite at radius R has potential energy U = -Gm1m2/r").

Is this just an issue of expression, or am I missing something deeper here...?

Thanks!
 
Silvius said:
Hey guys,

I'm currently trying to get my head around the concept of gravitational potential energy;

U_{r} = -\frac{Gm_{1}m_{2}}{r}

My question concerns whether this relates to both bodies in the system individually, or together.

That is, if I have two masses separated by a distance r, does the above formula describe the gravitational potential energy possessed by one of those bodies, or does it describe the total potential energy of the interaction between the two bodies? Or, another way of looking at it - is the total energy of the system U or 2U?

Thanks!...

... often seem to refer simply to one of the bodies having the potential energy given by that equation (e.g., "a satellite at radius R has potential energy U = -Gm1m2/r").

U as it is given is the energy for the system of both objects.

When they mention the potential energy of one object, they are splitting the symmetry in a sense, like U=m1*P(r). I made up the symbol P=-Gm2/r for gravitational potential, which is definitely different from gravitational potential energy.

I don't think I found an eloquent way to say it, it's complicated, there are more situations to be confused by, study more, ask us more questions!
 
algebrat said:
U as it is given is the energy for the system of both objects.

When they mention the potential energy of one object, they are splitting the symmetry in a sense, like U=m1*P(r). I made up the symbol P=-Gm2/r for gravitational potential, which is definitely different from gravitational potential energy.

I don't think I found an eloquent way to say it, it's complicated, there are more situations to be confused by, study more, ask us more questions!

Thanks so much for the help =)

Bearing the above in mind, how would I approach the following type of problem;

"Two Earth sized/shaped bodies are separated by a distance R in deep space. The bodies are attracted to each other, and hence accelerate towards each other. How fast will each body be when they collide?" (Obviously this isn't a specific problem).

If one body were Earth sized and the other were, say, the size of the sun, the problem would be much simpler; I could simply assume that the sun wouldn't move much - being so much bigger than the Earth - and hence my expression for the potential energy would only really apply to the Earth. Thus, I would find the difference in potential energy of the system at R and then at twice the radius (when the bodies are touching), and I would be able to say that that difference in potential energy has been converted entirely into the kinetic energy of the Earth-sized body.

But in this case, I cannot make such an assumption. Would I then find the difference in potential energy of the system at each of the two points, and halve that to find the kinetic energy of each of the bodies? Am I thinking about this the right way?
 

Thread 'Is calling fictitious forces "not real" just about terminology?'

Hi there, im studying nanoscience at the university in Basel. Today I looked at the topic of intertial and non-inertial reference frames and the existence of fictitious forces. I understand that you call forces real in physics if they appear in interplay. Meaning that a force is real when there is the "actio" partner to the "reactio" partner. If this condition is not satisfied the force is not real. I also understand that if you specifically look at non-inertial reference frames you can...
View full post »

Thread 'Derivation of Hamilton's Principle: Questions'

I have recently been really interested in the derivation of Hamiltons Principle. On my research I found that with the term ##m \cdot \frac{d}{dt} (\frac{dr}{dt} \cdot \delta r) = 0## (1) one may derivate ##\delta \int (T - V) dt = 0## (2). The derivation itself I understood quiet good, but what I don't understand is where the equation (1) came from, because in my research it was just given and not derived from anywhere. Does anybody know where (1) comes from or why from it the...
View full post »

Similar threads

Gravitational potential energy question -- Ojbect sitting on the Earth
Replies
3
Views
1K
Gravitational potential energy -- Why is it always negative?
Replies
10
Views
3K
I How to interpret this definition of potential energy?
Replies
10
Views
2K
Two separate "gravitational potential energy" equations?
Replies
11
Views
3K
Meaning of potential energy in external fields
Replies
19
Views
2K
Gravitational potential energy and continuous matter
Replies
2
Views
1K
Conservative forces, Nonconservative forces and Potential Energy
Replies
9
Views
3K
What does gravitational potential mean ?
Replies
8
Views
2K
Question About Potential Energy
Replies
3
Views
2K
Gravitational potential between two massive particles....
Replies
4
Views
2K

Hot Threads

Recent Insights

Back
Top