Cutting a FeBa Magnet for a Bloch Wall

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To cut a FeBa magnet for a Bloch wall, it's essential to ensure the cut aligns with the desired orientation of the magnetic domains. The magnet's dimensions are 152 x 102 x 52 mm, and the Bloch wall should run along the 152 mm length and 52 mm height. There is some confusion about the continuity of the Bloch wall, with discussions highlighting that magnetic domains can be disordered. Visual aids, such as diagrams or images, are requested to clarify the cutting process. Understanding the nature of Bloch walls and magnetic domains is crucial for achieving the correct cut.
Sveral
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Hello,
could someone explain to me, how I should cut a FeBa magnet, if it has one pole facing upward and the other downward so that the bloch wall would be across the entire length of the magnet. The dimensions of the magnet at hand are 152 x 102 x 52 mm. The bloch wall runs across the entire length of the sides (152 length, 52 height) and the side with a length of 102 mm and height of 52 mm, just to make it as clear as possible. Just don`t want to cut them the wrong way, that`s all.
Thanks to anyone in advance.
 
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Sveral said:
bloch wall would be across the entire length of the magnet

I don't understand this ?please show a photo of what you are talking about
 
@davenn, have you tried looking up Bloch walls? It's the rather common term for the walls between magnetic domains.

@Sveral, are you entirely certain that the Bloch wall is that continuous? From my experiments in my EE studies back in the day, magnetic domains were pretty haphazard and all over the place.
 
@Sveral, are you entirely certain that the Bloch wall is that continuous? From my experiments in my EE studies back in the day, magnetic domains were pretty haphazard and all over the place.
About the domains I agree, yes, they disorientated under normal conditions. But this was about the bloch wall and cutting magnets, but I will get through it, don`t worry.
 
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It may be shown from the equations of electromagnetism, by James Clerk Maxwell in the 1860’s, that the speed of light in the vacuum of free space is related to electric permittivity (ϵ) and magnetic permeability (μ) by the equation: c=1/√( μ ϵ ) . This value is a constant for the vacuum of free space and is independent of the motion of the observer. It was this fact, in part, that led Albert Einstein to Special Relativity.
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