Can Dipole Moments Be Added Like Forces?

AI Thread Summary
Dipole moments are vector quantities that can be added similarly to forces, but they must consist of one positive and one negative charge; two positive charges cannot form a dipole. In calculating dipole moments for clusters of atoms, each pair of atoms can be treated as having a dipole moment that can be summed as vectors, but the presence of a net charge complicates this. The integral equation for continuous dipole moments involves integrating over charge distributions, and if the distribution is uniform, it can be simplified. The direction of dipole moments is conventionally defined from negative to positive charge to maintain consistency with other physical laws. Understanding dipole moments is essential for analyzing interactions in electric fields and charge distributions.
calvinjhfeng
Messages
30
Reaction score
0
Hi, I am sort of new to Physics forum but I am urgently in need of help. It would be very much appreciated if you could clear my confusion.
Let me break them down into bullet points instead of one giant paragraph.

1.Dipole moments are vector quantities. I can just add them up like I do to forces?
2. Does dipole have to be composed of 1 positive and 1 negative charge? Can it be two positive charges?

Right now I am trying to compute the dipole moment of a cluster of atoms in a specific shape discretely and then continuously.
3.For the discrete part, I want to know whether if it's correct to treat each pair of atoms(in my case, they are ions+) with a dipole moment with a direction pointing somewhere, and then add them up like vectors of force?
4.For continuous part, I must integrate it over a volume. I don't understand the equation
P(r) = integral of p(r0) (r0 - r) dr^3.
what is p(r0)*(r0 - r)
r0 = r zero = r initial i think?

What if my charge distribution is constant and uniform? Does that mean I can pull it out and times the volume of the shape?

Thank you.
 
Physics news on Phys.org
1. dipole moments are pseudo-vectors like moment of inertia or torque, they add the same way.

2. the electric dipole is defined in terms of + and - charge.

3. depends on the situation. two positive ions won't have a dipole between them - their individual dipoles are usually magnetic and come from their electrons. In an electric field, though, the electrons will tend to hang about to one side creating an electric dipole.

4. that sort of relation always comes with a diagram... look at the diagram.

Looks like you have a specific problem in mind - how about posting it?
Meantime - refresher:
 
Last edited by a moderator:
Simon Bridge said:
2. the electric dipole is defined in terms of + and - charge.

No, it's defined as a term in the multipole expansion of a general distribution of charge:

Electric dipole moment (general case)

Multipole expansion

This is also covered in E&M textbooks like Griffiths, but I don't have my copy handy so I can't give a page reference.
 
Fine - but how does that answer OPs question?
You can have a dipole moment of 2 + charges?
 
Last edited:
of course you can't have a dipole of 2 positive charges, which is precisely why simon gave an ok answer the first time. dipoles are little blobs of two clouds of charges, of opposite sign necessarily. the definition can be extended to more numbers of charges but the general description requires the net charge be zero, so that there should be no electric field in the domain, but only polarization fields appear.

in the case of two neighbouring atoms, you find that the dipole exists as the oscillatory motion of the electrons in one shifts the orbitals on the other atoms' protons and electrons, thereby creating a dipole. the integral equation can be written, since the protons are very heavy, using the born-Oppenheimer approximation (feel free to google that one) we can assume they are pretty much stationary, and their charge distribution is therefore a Dirac delta function centred at the centre of mass in the continuous case. the equation then can describe the dipole moment matrix element describing the dipole interaction of an ion core on another identical nearby atom.
 
Last edited:
You can expand the long-distance fields of any charge distribution in terms of multipole moments.

If you have two positive charges, there's of course a net monopole component with the sum of the charges in the origin, which is arbitrary somewhere near the charge distribution, and you should choose cleverly such that the calculation of the multipole moments is as easy as possible. The next corrections are then the dipole and quadrupole moments, etc. Only the first non-vanishing multipole moment is independent of the choice of the origin. In this case with a non-zero net charge only the monopole moment is independent of the choice of the origin.
 
ardie said:
of course you can't have a dipole of 2 positive charges, which is precisely why simon gave an ok answer the first time. dipoles are little blobs of two clouds of charges, of opposite sign necessarily. the definition can be extended to more numbers of charges but the general description requires the net charge be zero, so that there should be no electric field in the domain, but only polarization fields appear.

I wouldn't put it that way. The dipole is the second term in a multipole expansion. Any distribution of charge can be characterized as a monopole plus a dipole plus a quadrupole plus an octopole etc. The dipole moment is mathematically orthogonal to the monopole and to the higher multipoles as well. Now, if you calculate the dipole moment of a system of two positive charges about the centroid you will get zero, but not if you use a different origin.
 
I was talking about something irrelevant, nevermind
 
Last edited:
Hi frinds,
I've a big confusion regarding the dipole.
Why we take the direction of dipole moment from negative charge to the positive charge?
Is it a convention only?
 
  • #10
Yes ... and no.
It is a convention chosen to be consistent with other conventions. i.e. not an arbitrary convention. If you extrapolate backwards from the definition of the dipole, assuming the direction is the opposite way around, you get a lot of extra minus signs or you use a left-handed reference frame (iirc).
 
  • #11
Hi everyone. I have a question about dipole moments and I think it is closely related to the OP's posts so I would just ask it here: is the dipole moment just a measure of the tendency of the dipole to rotate under an external electric field?
 
  • #12
I think, historically, it came from investigations into how electric currents affect magnets. It is called a "moment" because a magnetic dipole is set up by a circulating electric current. In mechanics, a "moment" is a circular/twisting force - a "torque".

However, the term has come to, also, be used to describe the property of being rotated by an external B field. Particularly of fundamental particles. I think it is useful to make a distinction between quantum mechanical magnetic moments and classical dipole moments.

So - the answer to your question is, yes and no.
 

Similar threads

I Instantaneous dipole moment and orbitals
Replies
1
Views
97
I Question regarding how to interpret dipole moment for bound charges
Replies
1
Views
2K
Dipole Moment of a Hollow Sphere, simplify calculation
Replies
1
Views
2K
Why is a current ring approx a magnetic dipole from very far off?
Replies
7
Views
2K
I Dipole moment of a cylinder of uniform polarization
Replies
10
Views
2K
Obtaining position in a dipole field
Replies
3
Views
4K
Can a dipole be modeled as a point charge?
Replies
10
Views
468
I Something about retarded potentials for oscillating electric dipole
Replies
1
Views
2K
Multipole Expansion for Two Charged Hemispheres
Replies
9
Views
2K
Image Theory for an Electric Dipole
Replies
14
Views
2K

Hot Threads

Recent Insights

Back
Top