Relationship between remanence (B_r) and Magnetization (M)

AI Thread Summary
The discussion centers on the relationship between remanence (B_r) and magnetization (M) in NdFeB magnets. It highlights the challenge of finding a definitive value for magnetization corresponding to a given remanence, specifically B_r = 1.3 T. The conversation clarifies that while some sources conflate magnetization with remanence, they are distinct properties. It is noted that in closed-shaped magnets, the remanence field equals the product of the permeability of free space (μ0) and the magnetization, whereas in open magnets, the B field is lower than B_r. Understanding this relationship is crucial for accurate magnetic property assessments.
sgsawant
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Hi,

I have scoured through scores of websites but haven't found a reasonable solution. The thought problem goes like this. Take any NdFeB magnet which is saturated say to B_r =1.3 T. Is there a magnetization (M) value that corresponds to the this remanence. I have been able to find a few relations but then in the end I am still left with unknowns. For example χm (perhaps read as "Ki"). And even those are not easy to find for materials like NdFeB.

So the question is, is there a linear relationship between remanent field and magnetization? Many websites refer to magnetization as if it is the same as remanence. That I know for sure it is not.

Regards,

-sgsawant
 
Physics news on Phys.org
If the magnet has a closed shape, like a torus, then the remanence field Br equals mu0 times the magnetization because the H field is null. In an open magnet the B field is less than Br.
 

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