How to Find Particle Acceleration Using Conservation of Energy?

Ron_Gis
Messages
4
Reaction score
0
Help

An isolated system of two identical particles, each of mass m, is described by an energy function
E = ½ m |v1|^2 + ½ m |v2|^2 + ½ k |x1 – x2|^2
How can I use conservation of energy to find the acceleration of each particle in terms of the position of the particle? I would be thankful if someone could give me a hint ?

Ron
 
Physics news on Phys.org
Well, the derivative of E with respect to time is zero, so...
 
krab said:
Well, the derivative of E with respect to time is zero, so...


Hello krab,

thank you for your help. Your approch to the problem is correct. If the total energy is conserved, the first derivative with respect to time of the given equation should be zero. I have some problems with the maths. Nevertheless, I think that the first derivative is given by

m a1 dot v1 + m a2 dot v2 + 0 where a1 = dv1/dt and a2 = dv2/dt

but I am not sure about this. Furthermore, it is not possible to divide a scalar through a vector, even if the solution is correct. I am too stupid to find the correct expression for the accelerations a1 and a2. I would be thankful if you could help me again.

Ron
 
Ron_Gis said:
, I think that the first derivative is given by

m a1 dot v1 + m a2 dot v2 + 0 where a1 = dv1/dt and a2 = dv2/dt

but I am not sure about this.
The first part is correct, but x1 and x2 change with time, so why did you get that the time derivative of ½ k |x1 ? x2|^2 is zero?
 
krab said:
The first part is correct, but x1 and x2 change with time, so why did you get that the time derivative of ½ k |x1 ? x2|^2 is zero?

Hello krab,

you are right again. The first derivative is given by

m a1 dot v1 + m a2 dot v2 + k (x1 – x2) dot (v1 – v2)

and this expression is equal to zero.

Nevertheless, the dot product is a scalar and I have to find an expression for the accelerations, which are vectors. I think that this is not possible, simply by rearranging this equation. Would you be kind enough to give me another hint.

Regards Ron
 
Ron_Gis said:
The first derivative is given by

m a1 dot v1 + m a2 dot v2 + k (x1 ? x2) dot (v1 ? v2)

and this expression is equal to zero.

Nevertheless, the dot product is a scalar and I have to find an expression for the accelerations, which are vectors. I think that this is not possible, simply by rearranging this equation. Would you be kind enough to give me another hint.

Regards Ron
You are right. You cannot get it from just this equation. Are you allowed to use the fact that in this isolated system, total momentum is conserved? If so then v1+v2=constant, so a1=-a2 and the result follows.

Alternatively, go back to the beginning and use a "virtual displacement". Pretend that you move say particle 1 by a vector dx1. Use the energy equation to calculate the difference in energy this displaced system would have. From the definition of work, you know that this energy difference is F1 dot dx1.
 
Hello krab,

I think that I have found the correct solution. Thank you for your help.

Regards Ron
 

Similar threads

I Parallel plate particle acceleraton questions
Replies
14
Views
3K
A Relation between the track of a particle and its energy loss
Replies
6
Views
2K
I Energy and states of a particle in a box.
Replies
3
Views
1K
A system of independent particles (energy levels)
Replies
1
Views
1K
I How Does Binding Energy Relate to Nucleon Distance in Atomic Nuclei?
Replies
17
Views
3K
I How to find the most likely modes of decay for a particle
Replies
3
Views
2K
Where to Find Energy in Joules of Particle Accelerators
Replies
12
Views
2K
Finding the Ratio of Particles in a Three-Level Quantum System
Replies
1
Views
2K
A Energy Levels and Wave Functions of Identical Particle Systems
Replies
1
Views
1K
B Conservation of momentum in a closed system
Replies
3
Views
2K

Hot Threads

Recent Insights

Back
Top