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§5.3: Magnetic Multipole Expansion

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1 §5.3: Magnetic Multipole Expansion
Christopher Crawford PHY 417

2 Outline Motivation – electric vs. magnetic dipole
Torque and force, dipole potential/field Biot-Savart calculation of current loop General derivation of axisymmetric multipoles Boundary value problem – azimuthal currents New orthogonal function basis Multipole expansion – electric vs. magnetic Derivation of Helmholtz coil

3 Motivation – magnetic dipole
Original definition of B-field τ = m × B compare: τ = p × E we need to relate this to Ampère’s law – next slide Definition of magnetic multipole m=I a compare: p=q d Dipole field – small current loop

4 Torque on magnetic dipole
Electric dipole Remember pure spherical surface charge dipole Torque Potential Magnetic dipole – Gilbert vs Ampere dipole We will solve same BVP: spherical surface current dipole today

5 Electric vs. magnetic dipole force
Electric dipole Magnetic dipole

6 Expansion of vector potential
From Griffiths

7 Dipole field From Griffiths – calculate the derivative
Coordinate-free notation – same tensor as in quadrupole!

8 General multipole expansion
Electric multipoles No external monopole – just a constant potential offset Magnetic multipoles Derivatives P’(x) –> there is NO monopole at all

9 Review – setting up B.V.P.

10 A new orthogonal function basis
Derivative of Legendre polynomial – associated Legendre function

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