magnetic field of a steady current
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Magnetic field of a steady current. Section 30. Boundary condition H 1t = H 2t still holds. Proof: J is finite everywhere, including boundaries. Piecewise homogeneous medium. Different parts have different m. HW: Also require continuity of ( curl A ) t / m. Diff. Eq. for A. - PowerPoint PPT PresentationTRANSCRIPT
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Magnetic field of a steady current
Section 30
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Previously supposed zero net current.Then
Now let the net current j be non-zero.Then
“Conduction” current density
No contribution to net current
Rate of energy dissipation per unit volume = E . j
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Distribution of j is determined by
The H-field generated by j is not included if
From section 21
Hence, H is determined from the given j.
Recipe: Find j. Then find H. Ignore the effect that H has on j.
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H determined from given j.
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Boundary condition H1t = H2t still holdsProof:
Homogeneous interface between conductors.
For homogeneous interface, Is finite
J is finite everywhere, including boundaries
finite
Hy is continuous. (Ht is continuous.)
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For the given j, we want to find H and B
These are the equations we need to solve.
Introduce the vector potential and find the equation for it.
Due to gauge invariance, we can place a condition on A, namely
Assume isotropic linear medium, or else there are too many unknowns
A differential equation for A with j as the source.Recipe: Solve for A, then find B, then H.
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Special case: homogeneous medium where m is spatially uniform
Differential equation for A with given j source termRecipe: Find A, then find B, then H.
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Special case: Piecewise homogeneous medium
Different parts have different m
holds in each part.
Boundary condition between the parts
is continuous.
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Special case.: 2D problems, i.e. systems with tranlational invariance along one axis, like a straight wire.
z
y
By assumption
One possibility for current:
Then we expect:
holds automaticallyCondition
Magnetic field likes in the xy plane
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What equation does A satisfy in this 2D problem?
Homework
But
Equation for scalar A when m = m(x,y) and j = j(xy)ez
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What if 2D problem is piecewise homogeneous?
holds in each region with own m
Boundary conditions are continuity of A, , and (curlA)t/m.
Homework
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Special case of 2D problem with current along axis: cylindrical symmetry.
If current is symmetrical about the z-axis, jz = j(r)Then magnetic field lines are circles (r = constant)(the field must have the same symmetry as its sources.
r = const Any surface bound by contour r = const
Stokes
Total current enclosed within radius r
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Solve for A, then
Another kind of 2D problem is the axially symmetric current distribution
We expect
Magnetic induction (field)
H-field
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Non magnetic media: m = 1
Now there are no conditions at interfaces or surfaces since all media are magnetically identical
(v.2 section 43)
Since m = 1, H = B
Acts on coordinates r of field point P
HW
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Thin wires, neglect internal regions of wire: “linear currents”
Total current in the conductor
R3 Biot-Savart law.
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If thin conducting material is surrounded by magnetic material of permeability m
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If j = 0 except for linear currents
Except for line singularities
ThenSome magnetic scalar potential
Contrast with electrostatics
gradf has same value at start and end of integralSame holds for f: f is single valued.
In all space
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