Griffiths Problem 4.8 [SOLVED]: Why Don't You Need to Add Energy?

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So it is free.In summary, the answer to why the energy of dipole 1 is not added to the energy of dipole 2 is because bringing the first dipole from infinity requires no energy and bringing the second dipole from infinity while holding the first one at rest requires an equal energy to -p2 dot E_1, which is the total energy stored in the system. Holding the first dipole at rest does not require any work according to the definition of work in physics.
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ehrenfest
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[SOLVED] Griffiths Problem 4.8

Homework Statement


This question refers to Griffiths E and M book.

Why is the answer not 2 times that?
Why don't you need to add the energy of dipole 1 to the energy of dipole 2 like

[tex] \bf -p_1 \cdot E_2 - p_2 \cdot E_1 [/tex]

?

Homework Equations


The Attempt at a Solution

 
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  • #2
ehrenfest said:

Homework Statement


This question refers to Griffiths E and M book.

Why is the answer not 2 times that?
Why don't you need to add the energy of dipole 1 to the energy of dipole 2 like

[tex] \bf -p_1 \cdot E_2 - p_2 \cdot E_1 [/tex]

?


Homework Equations





The Attempt at a Solution


For the same reason that the potential energy of a pair of two point charges is k q_1 q_2/r.

Imagine assembling the system, starting with the two dipoles at infinite distances. Bringing the first dipole from infinity requires no energy. Bringing the second dipole from infinity (while holding the first one at rest) requires an energy equal to - p2 dot E_1. That's the total energy stored in the system since it's the total energy that was required to assemble the system
 
  • #3
nrqed said:
For the same reason that the potential energy of a pair of two point charges is k q_1 q_2/r.

Imagine assembling the system, starting with the two dipoles at infinite distances. Bringing the first dipole from infinity requires no energy. Bringing the second dipole from infinity (while holding the first one at rest) requires an energy equal to - p2 dot E_1. That's the total energy stored in the system since it's the total energy that was required to assemble the system

But it also requires energy to hold the first dipole at rest, doesn't it? Well I guess there is no work done doing that. But it seems like you don't get that for free!
 
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  • #4
ehrenfest said:
But it also requires energy to hold the first dipole at rest, doesn't it? Well I guess there is no work done doing that. But is seems like you don't get that for free!

as you say, there is no work involved doing that. I know what you mean but there is a very clear definition of work in physics and we have to stick to it.
 

1. What is Griffiths Problem 4.8?

Griffiths Problem 4.8 is a physics problem that deals with the conservation of energy and the concept of potential energy in a system.

2. What is the importance of solving this problem?

Solving Griffiths Problem 4.8 allows us to understand the fundamental principles of energy conservation and potential energy, which are key concepts in physics and have numerous applications in the real world.

3. Why is it significant that energy does not need to be added in this problem?

This is significant because it highlights the fact that in a closed system, the total energy remains constant. This is known as the law of conservation of energy and is a fundamental principle in physics.

4. What are some real-world examples of this problem?

Some real-world examples of this problem include a pendulum swinging back and forth, a roller coaster moving along its track, and a ball rolling down a hill. In each of these cases, the total energy of the system remains constant, and no additional energy needs to be added.

5. How can the solution to this problem be applied to other areas of science?

The solution to Griffiths Problem 4.8 can be applied to other areas of science, such as engineering and chemistry, where the concept of energy conservation is crucial in understanding and predicting the behavior of systems. It also has implications in fields such as renewable energy and climate change, where the conservation of energy plays a significant role.

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