Boundary conditions for magnetic fields

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  • #1
lys04
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Homework Statement
Deriving the boundary conditions for the tangential and normal components of the magnetic field at a current sheet
Relevant Equations
Ampere's law: $$\oint \vec B \cdot d \vec l = \mu_{0} I_{enc}$$
In this diagram, why is the H vector/ B vector (They differ by a constant of $$ \mu_{0} $$) pointing in the same direction on opposite sides of the current sheet?
Also, I'm a bit confused on how did they go from $$ K \Delta w = H_{1,t} \Delta w - H_{2,t} \Delta w $$ to $$ (\vec H_{1} - \vec H_{2} ) \times \hat n_{12} = \vec K $$

The former is only got to do with magnitude whereas the latter involves directions right?
Any help is appreciated!!
1728699450680.png
 
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  • #2
lys04 said:
The former is only got to do with magnitude whereas the latter involves directions right?
Right.
 
  • #3
kuruman said:
Right.
So do you mind explaining how did they go from the one with magnitudes only to the one involving vectors?
And how how could they make the assumption that H points in the same direction both above and below the surface?

And also how does the magnitude version apply to an infinite sheet of current?
1728774980288.png

For example, if I have an infinite sheet with surface current flowing in the x-direction, the magnetic field above and below is going to point in the y-direction, although in opposite directions, they have the same magnitude.
When I take the difference then it'll give me 0.
 
  • #4
lys04 said:
So do you mind explaining how did they go from the one with magnitudes only to the one involving vectors?
Study the drawing where all the quantities and vectors are defined. ##H_{1t}## is the tangential component of ##\mathbf {H}_1##. What do you get when you take the cross product ##\mathbf {H}_1\times \mathbf {\hat n}_{12}##?
lys04 said:
And how how could they make the assumption that H points in the same direction both above and below the surface?
The point in the same general direction. That's because the normal component of ##\mathbf B## is continuous across the boundary.
lys04 said:
When I take the difference then it'll give me 0.
So what? The difference between the magnitudes of two vectors is not the difference between the two vectors.

Edited for LaTeX typo.
 
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  • #5
kuruman said:
What do you get when you take the cross product H1×n^12?
Get another vector thats perpendicular to both
 
  • #6
kuruman said:
normal component of B is continuous across the boundary.
Yeah I get this, but couldn't the H vector below the surface be pointing upwards but going to the left instead?
 
  • #7
kuruman said:
So what? The difference between the magnitudes of two vectors is not the difference between the two vectors.
But doesn't the equation $$ K \Delta w = H_{1,t} \Delta w - H_{2,t}\Delta w $$ also hold?
 
  • #8
lys04 said:
Get another vector thats perpendicular to both
And what is the name of that vector? Study the figure.
lys04 said:
Yeah I get this, but couldn't the H vector below the surface be pointing upwards but going to the left instead?
No, because the tangential component discontinuity is equal to the surface current density. That's what the equation is all about.
lys04 said:
But doesn't the equation $$ K \Delta w = H_{1,t} \Delta w - H_{2,t}\Delta w $$ also hold?
What makes you think it does not? It is another way to say what I just wrote above about the tangential component discontinuity of ##\mathbf H## at the interface.
 
  • #9
kuruman said:
And what is the name of that vector? Study the figure.
$$ (\vec H_{1} - \vec H_{2}) \times \hat n_{1,2} = \vec K $$
$$ (\vec H_{1,t} + \vec H_{1,n} - \vec H_{2,t} - \vec H_{2,n}) \times \hat n_{1,2} = \vec K $$
$$ \vec H_{1,t} \times \hat n_{1,2} + \vec H_{1,n} \times \hat n_{1,2} - \vec H_{2,t} \times \hat n_{1,2} - \vec H_{2,n} \times \hat n_{1,2} = \vec K $$

Since
$$\vec H_{1,n} $$ and $$\hat n_{1,2}$$ are in the same direction, their cross product is 0 so I'm left with

$$ \vec H_{1,t} \times \hat n_{1,2} - \vec H_{2,t} \times \hat n_{1,2} = \vec K $$

so

$$ (\vec H_{1,t} - \vec H_{2,t}) \times \hat n_{1,2} = \vec K $$

So $$ \vec H_{1} \times \hat n_{1,2} $$ gives a vector in the direction of K but not necessarily K?
 
  • #10
lys04 said:
So $$ \vec H_{1} \times \hat n_{1,2} $$ gives a vector in the direction of K but not necessarily K?
Yes, but you have to consider the difference between tangential components$$(\mathbf H_{1} - \mathbf H_{2}) \times \mathbf{\hat n}_{1,2} = \mathbf K. $$ It's the discontinuity (difference) of the tangential component at the interface that is equal to the surface current density.

This is analogous to the boundary condition for the electric displacement vector at a dielectric interface $$(\mathbf D_{1} - \mathbf D_{2}) \cdot \mathbf{\hat n}_{1,2} = \sigma$$ which says that the discontinuity of the normal of component of ##\mathbf D## at the interface is equal to the surface free charge density.

I think you got it.
 
  • #11
kuruman said:
Yes, but you have to consider the difference between tangential components(H1−H2)×n^1,2=K. It's the discontinuity (difference) of the tangential component at the interface that is equal to the surface current density.
Yeah alright, but I still don’t understand why this implies that the tangential component needs to point in the same direction?
 
  • #12
lys04 said:
Yeah alright, but I still don’t understand why this implies that the tangential component needs to point in the same direction?
The same direction as what? The boundary condition $$(\mathbf H_{1} - \mathbf H_{2}) \times \mathbf{\hat n}_{1,2} = \mathbf K$$ says that the tangential component of the difference ##~(\mathbf H_{1} - \mathbf H_{2})~## has the same magnitude and direction as the surface current density ##\mathbf K.## That's the only "same" direction implicit in the equation.
 
  • #13
kuruman said:
The same direction as what? The boundary condition
In the initial diagram both the tangential component is pointing to the right
 
  • #14
lys04 said:
In the initial diagram both the tangential component is pointing to the right
The boundary condition in scalar form $$H_{1t}-H_{2t}=K \tag{1}$$ is derived from the line integral around the closed loop abcda. The integration is clockwise which means that positive direction of the normal to the loop is into the screen. The positive direction of ##K## is also into the screen. In the limit ##\Delta h \rightarrow 0##, there are no contributions from the sides and the closed loop integral is $$\oint\mathbf H\cdot d\mathbf l=\int_a^b\mathbf H_1\cdot d\mathbf l_1+\int_c^d\mathbf H_2\cdot d\mathbf l_2. $$ Now let's define the positive ##x##-axis to the right, so that ##d\mathbf l_1=dx~\mathbf{\hat x}.## Then $$\mathbf H_1\cdot d\mathbf l_1=(H_1\cdot\mathbf{\hat x})~dx=H_{1t}~dx\implies \int_a^b\mathbf H_1\cdot d\mathbf l_1=H_{1t}\Delta w.$$ In this expression ##H_{1t}## is the x-component of ##\mathbf H_1## that can be positive or negative.

Noting that ##d\mathbf l_2=-dx~\mathbf{\hat x}##,$$\mathbf H_2\cdot d\mathbf l_2=-(H_2\cdot\mathbf{\hat x})~dx=-H_{2t}~dx\implies \int_c^d\mathbf H_2\cdot d\mathbf l_2=-H_{2t}\Delta w$$ where, as before, ##H_{2t}## is the x-component of ##\mathbf H_2## that can be positive or negative. Putting all this together gives equation (1).

In equation (1) ##H_{1t}## and ##H_{2t}## can be in any direction that pleases you and there are four choices. However, if you want to make a drawing, you have to choose one of the four. Once you make that choice and you want to draw in the direction of ##\mathbf K##, it better be consistent. If ##H_{1t}-H_{2t}>0##, the current should be into the screen and if ##H_{1t}-H_{2t}<0## the current should be out of the screen.

The drawing that you posted shows, as best as I can tell, that ##H_{1t}=H_{2t}## which means that ##K=0##, yet it shows a surface current into the screen. I didn't draw it, so don't ask me why it looks that way.
 
  • #15
kuruman said:
In equation (1) H1t and H2t can be in any direction that pleases you and there are four choices. However, if you want to make a drawing, you have to choose one of the four. Once you make that choice and you want to draw in the direction of K, it better be consistent. If H1t−H2t>0, the current should be into the screen and if H1t−H2t<0 the current should be out of the screen.
Oh alright that makes sense.
kuruman said:
The drawing that you posted shows, as best as I can tell, that H1t=H2t which means that K=0, yet it shows a surface current into the screen. I didn't draw it, so don't ask me why it looks that way.
Yeah I realised that too.

Oh by the way in vector form $$ (\vec H_{1} - \vec H_{2}) \times \hat n_{1,2} = \vec K $$, does the unit normal vector need to point in a specific direction? Like pointing from surface 1 to 2 or from surface 2 to 1?

By the way thanks so much for the long reply! Really appreciate it.
 
  • #16
lys04 said:
Oh by the way in vector form $$ (\vec H_{1} - \vec H_{2}) \times \hat n_{1,2} = \vec K $$, does the unit normal vector need to point in a specific direction? Like pointing from surface 1 to 2 or from surface 2 to 1?
There is only one surface, the interface between two different media. The normal needs to be consistent with the boundary condition and the sense of integration. In this case the sense of integration is clockwise. This makes ##\mathbf K## positive when it's into the screen. Now if you write $$(\mathbf H_{1} - \mathbf H_{2}) \times \mathbf{\hat n}_{1,2} = \mathbf K$$ this says that the vector on the left hand side must be equal to the vector on the right hand side. This happens if you choose the normal from medium 1 into medium 2 so that ##~\mathbf H_{1}\times \mathbf{\hat n}~## is in the same direction as ##\mathbf K## which puts, of course, ##-\mathbf H_{2}\times \mathbf{\hat n}~## in a direction opposite to ##\mathbf K##. If you choose the direction of the normal to be from medium 2 into medium 1, then you have to reverse the order of the difference in the left hand side of the boundary condition.
lys04 said:
By the way thanks so much for the long reply! Really appreciate it.
You are welcome.
 
  • #17
kuruman said:
There is only one surface, the interface between two different media.
O alright!
kuruman said:
In this case the sense of integration is clockwise. This makes K positive when it's into the screen. Now if you write (H1−H2)×n^1,2=K this says that the vector on the left hand side must be equal to the vector on the right hand side. This happens if you choose the normal from medium 1 into medium 2 so that H1×n^ is in the same direction as K which puts, of course, −H2×n^ in a direction opposite to K. If you choose the direction of the normal to be from medium 2 into medium 1, then you have to reverse the order of the difference in the left hand side of the boundary condition.
So I guess it depends on the direction of $$ \vec H_{1} - \vec H_{2}$$ ? If we go by the direction of $$ \vec K $$ given in the diagram, using the right hand rule gives me that if $$ \vec H_{1} - \vec H_{2}$$ points to the right then the normal vector has to point from medium 2 to medium 1 whereas if $$ \vec H_{1} - \vec H_{2}$$ points to the left then the normal vector needs to point from medium 1 to medium 2?
 
  • #18
You got it backwards. The direction of the cross product of the difference with the normal must be into the screen which is the known direction of ##\mathbf K##.

(Edited for clarity.)
 
Last edited:
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FAQ: Boundary conditions for magnetic fields

What are boundary conditions for magnetic fields?

Boundary conditions for magnetic fields are the constraints that must be satisfied at the interface between two different media where magnetic fields are present. These conditions ensure that the magnetic field behaves consistently across the boundary, accounting for changes in material properties, such as permeability.

Why are boundary conditions important in magnetostatics?

Boundary conditions are crucial in magnetostatics because they determine how magnetic fields behave at interfaces between different materials. They help in solving Maxwell's equations in regions with varying magnetic properties and are essential for accurately predicting the behavior of magnetic fields in practical applications, such as magnetic shielding and inductors.

What are the common types of boundary conditions for magnetic fields?

The common types of boundary conditions for magnetic fields include the continuity of the magnetic field lines across the boundary and the discontinuity of the magnetic field intensity. Specifically, the tangential component of the magnetic field (H) is continuous, while the normal component of the magnetic flux density (B) can change depending on the surface current density at the boundary.

How do boundary conditions affect electromagnetic simulations?

Boundary conditions significantly influence the accuracy and stability of electromagnetic simulations. Incorrectly defined boundary conditions can lead to erroneous results, such as unrealistic field distributions and inaccurate predictions of electromagnetic behavior. Properly implementing boundary conditions is essential for reliable simulation outcomes in engineering and physics applications.

Can boundary conditions change with frequency in electromagnetic problems?

Yes, boundary conditions can change with frequency, especially in electromagnetic problems involving materials that exhibit frequency-dependent properties, such as dielectric materials or plasmas. In such cases, the behavior of the magnetic fields at the boundaries may vary, necessitating a careful analysis of the material properties and their impact on the boundary conditions across different frequencies.

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