Boundary condition for magnetic vector potential

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issacnewton
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Hi

I am studying magnetic vector potential from Griffiths book. The eq 5.76 in his book gives
the boundary condition for the magnetic vector potential.

[tex]\frac{\partial \vec{A_2} }{\partial n}- \frac{\partial \vec{A_1} }{\partial n}=-\mu_o \vec{K}[/tex]

where n is the vector perpendicular to the boundary surface and pointing from region
1 to region 2.

There is a problem in the book asking to prove this. So here's my attempt to do it. And I couldn't do it right. The book has eq 5.74 , which is

[tex]\vec{B_2}-\vec{B_1}=\mu_o(\vec{K}\times \hat{n})[/tex]

So I decided to use this for my purpose. Writing B in terms of the vector potential A, we have

[tex]\vec{\nabla}\times \vec{A_2}-\vec{\nabla}\times \vec{A_1}=\mu_o(\vec{K}\times \hat{n})[/tex]

Now writing in terms of the Cartesian components explicitly and collecting x,y,z components, we have

[tex]\hat{x}\left[\frac{\partial A_{2z} }{\partial y}- \frac{\partial A_{2y} }{\partial z}-<br /> \frac{\partial A_{1z} }{\partial y}+\frac{\partial A_{1y} }{\partial z}\right]<br /> -\hat{y}\left[\frac{\partial A_{2z} }{\partial x}-\frac{\partial A_{2x} }{\partial z}-<br /> \frac{\partial A_{1z} }{\partial x}+\frac{\partial A_{1x} }{\partial z}\right]<br /> +\hat{z}\left[\frac{\partial A_{2y} }{\partial x}-\frac{\partial A_{2x} }{\partial y}<br /> -\frac{\partial A_{1y} }{\partial x}+\frac{\partial A_{1x} }{\partial y}\right]<br /> =\mu_o(\vec{K}\times \hat{n})[/tex]lets call this equation 1where K is the surface current. Now I take

[tex]\vec{K} = K\hat{x}[/tex]

and

[tex]\hat{n}=\hat{z}[/tex]

so that

[tex]\mu_o(\vec{K}\times \hat{n}) = \mu_o K(-\hat{y})[/tex]

so I take the dot products of the equation 1 with [itex]\hat{x},\hat{y},\hat{z}[/itex].

There will be three equations in all.

[tex]\frac{\partial A_{2z} }{\partial y}+\frac{\partial A_{1y} }{\partial z}=<br /> \frac{\partial A_{2y} }{\partial z}+\frac{\partial A_{1z} }{\partial y}[/tex][tex]\frac{\partial A_{2y} }{\partial x}+\frac{\partial A_{1x} }{\partial y}=<br /> \frac{\partial A_{2x} }{\partial y}+\frac{\partial A_{1y} }{\partial x}[/tex]

[tex]\frac{\partial A_{2z} }{\partial x}-\frac{\partial A_{2x} }{\partial z}<br /> -\frac{\partial A_{1z} }{\partial x}+\frac{\partial A_{1x} }{\partial z}=<br /> \mu_o K[/tex]Now after this , I am totally lost. We actually know two more things about the vector
potential.

[tex]\vec{\nabla}\cdot \vec{A} = 0[/tex]and at the boundary, A is continuous.

[tex]\vec{A_2}=\vec{A_1}[/tex]

But I don't know how to use this information to prove the result I am seeking. Any guidance
will be appreciated.
 
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Hi, Griffith's fan too here,

you see from [tex]\mu_o(\vec{K}\times \hat{n}) = \mu_o K(-\hat{y})[/tex] automatically x and y component from eqn 1 will dissapear.


then, eqn 1 will become eqn 2 as below:


[tex]-\hat{y}\left[\frac{\partial A_{2z} }{\partial x}-\frac{\partial A_{2x} }{\partial z}-<br /> \frac{\partial A_{1z} }{\partial x}+\frac{\partial A_{1x} }{\partial z}\right]<br /> =\mu_o K(-\hat{y}[/tex]



at boundary condition [tex]\vec{A_2}=\vec{A_1}[/tex],

then eqn 2 will be:


[tex]\hat{y}\left[\frac{\partial A_{2x} }{\partial z}-\frac{\partial A_{1x} }{\partial z}\right]=-\mu_o K(\hat{y}[/tex]


or, another write in vector term:


[tex]\left[\frac{\partial \vec{A}_{2} }{\partial z}-\frac{\partial \vec{A}_{1} }{\partial z}\right]=-\mu_o \vec{K}[/tex]


with [tex]\hat{z}[/tex] is perpendicular to the boundary surface.
 
Hi Lepton

while deriving the following equation

[tex] \hat{y}\left[\frac{\partial A_{2x} }{\partial z}-\frac{\partial A_{1x} }{\partial z}\right]=-\mu_o K(\hat{y} )[/tex]

I think you assumed that

[tex]\frac{\partial A_{2z} }{\partial x}=\frac{\partial A_{1z} }{\partial x}[/tex]

why is that so ?

you could also have said,

[tex]\frac{\partial A_{2x} }{\partial z}=\frac{\partial A_{1x} }{\partial z}[/tex]

because [itex]A_{2x}=A_{1x}[/itex]

so what reasoning did you use ?

There is also another point. A is continuous at the boundary. But how can we say that
its derivatives also continuous ? Consider the following function.

[tex]f(x)=\lvert x \rvert[/tex]

This is continuous at the boundary x=0, but its not differentiable. So how did you do that ?
 
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for normal component, using the fact [tex]\nabla\cdot A = 0[/tex], or write it in integral form,

[tex]\oint \vec{A}\cdot d\vec{a} = 0[/tex], we will get [tex]A_{above}^{\perp} = A_{below}^{\perp}[/tex].


or we can write it in cartesian coordinate, [tex]A_{2z} = A_{1z}[/tex].

for tangential component, Griffith also said that A is continuous but not for its derivative. There is discontinuity in derivative of A in tangential component.

I think I can safely equate for normal component and find the derivative of A in tangential component as discontinuity in boundary.
 
Hi Lepton,

Thats what I am not convinced about. Griffiths usually doesn't give rigorous arguments. I am just trying to make sure that what he says is right from mathematical standpoint as well.
 
I just stumbled upon this problem in Griffiths, and I, too, have the same difficulty as the OP. The problem seems to require the tangental derivatives [itex]\frac{\partial \vec{A}}{\partial x}, \ \frac{\partial \vec{A}}{\partial y}[/itex] to be continuous across the current sheet. This link http://www.physics.sfsu.edu/~lea/courses/ugrad/360notes14.PDF claims between equations 10 and 11 that continuity of the tangental derivatives follows from continuity of [itex]\vec{A}[/itex]. If true, this would solve our problem.

But in general, if a function [itex]f(x, y)[/itex] is jointly continuous in [itex]x, \ y[/itex] and differentiable in [itex]x[/itex], it does not follow that [itex]\frac{\partial f}{\partial x}[/itex] is continuous in [itex]y[/itex]. For example, the function [itex]f(x, y) = \frac{x |y|^{3/2}}{x^2 + y^2}[/itex] is continuous but [itex]\frac{\partial f}{\partial x} = \frac{y^{3/2} (y^2 - x^2)}{(x^2 + y^2)^2}[/itex] is not continuous along the line [itex]x = 0[/itex]. Thus, without extra conditions on [itex]\vec{A}[/itex] I don't see why its tangental derivatives must be continuous.
 
hi, if you find an answer, post here...