Static Magnetic Field Section 29.

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Presentation transcript:

Static Magnetic Field Section 29

Microscopic magnetic field equations Current density

Spatial average over microscopic length scales “Magnetic induction” This is the macroscopic magnetic field: B. Not H. Zero, since <e>r = E = constant in electrostatics Generally can be non-zero in either dielectrics or conductors

Dielectrics: No net current density, even though <rv>r might be locally non-zero Some cross section

Conductors: Suppose (for now) that I = 0 through any cross section. Then also holds, and we must have M = some vector, which is zero outside the body

M = “magnetization” Proof. Net current through some cross section By hypothesis By Stokes Thm Boundary of cross section, which needs to be outside of body. M = zero outside body The hypothesis gives the required condition of no net current through any cross section. M = “magnetization”

Macroscopic Maxwell equation Definition of H-field Magnetic induction = Macroscopic magnetic field. Magnetization H-field Analog of Definition of D Electric induction Macroscopic electric field. Polarization

Magnetic induction is the macroscopic magnetic field. Electric induction is not the macroscopic magnetic field. In vacuum (v.2), H was the magnetic field because M = 0 there: H = B = <h>r

Integrate over any volume that includes all of the body = Total magnetic moment Integrate over any volume that includes all of the body = Homework = 0 outside body Homework Magnetization = magnetic moment per unit volume

Equations of magnetostatics in matter These are insufficient to solve for B and H. For weak fields in non-ferromagnetic isotropic media “permeability” “susceptibility”

m is always positive, but not always >1. can be positive or negative. Usually the magnetic susceptibility << dielectric susceptibility Magnetism is a relativistic effect, ~ v2/c2, v = electron velocity Anisotropic body: symmetric

Boundary conditions Magnetic scalar potential

Bt is discontinuous Surface current at interface Unit length in the surface Integrate along Dl crossing the normal = Charge passing per unit time through unit length in the surface

Interface Choose coordinates Lim Dl->0 y Surface current density 1st integral is finite at homogenous interface, and the same on both sides

= Bt2 – Bt1 Second integral Thus, the discontinuity in Bt is Unit normal into region 2 = Bt2 – Bt1 and so