Electrodynamics : Oscillating Quadrupole

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Homework Statement


Find E for a quadrupole, oscillating sinusoidally. The method suggested is to take two Hertzian dipoles, a distance 'a' apart, and find the superposition of the two. They both have an equal dipole moment, and angular velocity, but have a phase difference of pi between them.

Homework Equations


Oscillating E field for a dipole;

a06d3b8afae0ef96396586732f895e1d.png


The Attempt at a Solution


I'm just having difficulty trying to visualise how the two out of phase Hertzian dipoles will superpose together. I can kind of see how after doing the correct expansion, terms will disappear as the 1/r and sin terms in the denominator will be negligible compared to those in the phase of the exponent. I just need a more basic outline of how to set the problem up. Any help is much appreciated.
 
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do I just start off saying that the magnetic quadrupole moment is;

p = (Coswt + Sinwt) z?

Edit - made a silly mistake, the angle between them is pi and not pi/2, so it's not sine and cosine, it's just a linear combination of sines.
 
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This problem has been confusing me too.
 
Thread 'Need help understanding this figure on energy levels'

Thread 'Need help understanding this figure on energy levels'

This figure is from "Introduction to Quantum Mechanics" by Griffiths (3rd edition). It is available to download. It is from page 142. I am hoping the usual people on this site will give me a hand understanding what is going on in the figure. After the equation (4.50) it says "It is customary to introduce the principal quantum number, ##n##, which simply orders the allowed energies, starting with 1 for the ground state. (see the figure)" I still don't understand the figure :( Here is...
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Thread 'Understanding how to "tack on" the time wiggle factor'

Thread 'Understanding how to "tack on" the time wiggle factor'

The last problem I posted on QM made it into advanced homework help, that is why I am putting it here. I am sorry for any hassle imposed on the moderators by myself. Part (a) is quite easy. We get $$\sigma_1 = 2\lambda, \mathbf{v}_1 = \begin{pmatrix} 0 \\ 0 \\ 1 \end{pmatrix} \sigma_2 = \lambda, \mathbf{v}_2 = \begin{pmatrix} 1/\sqrt{2} \\ 1/\sqrt{2} \\ 0 \end{pmatrix} \sigma_3 = -\lambda, \mathbf{v}_3 = \begin{pmatrix} 1/\sqrt{2} \\ -1/\sqrt{2} \\ 0 \end{pmatrix} $$ There are two ways...
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