Magnetic induction: Difference between revisions

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In [[physics]], and more in particular in the theory of [[electromagnetism]], '''magnetic induction''' (commonly denoted by '''B''') is a vector field closely related to the [[magnetic field]] '''H'''.  
In [[physics]], and more in particular in the theory of [[electromagnetism]], '''magnetic induction''' (commonly denoted by '''B''') is a vector field closely related to the [[magnetic field]] '''H'''.  


The SI unit measuring the strength of '''B''' is T (tesla), and the Gaussian unit is gauss. One tesla is 10 000 gauss. To indicate the order of magnitude: the magnetic field (or better magnetic induction) of the Earth is about 0.5 gauss = 50 μT. A medical MRI diagnostic machine typically supports a field of 2 T. The strongest magnets in laboratories are presently about 30 T.
==Relation between '''B''' and '''H'''==
In vacuum, that is, in the absence of a ponderable, continuous, and magnetizable medium, the fields '''B''' and '''H''' are related as follows,
In vacuum, that is, in the absence of a ponderable, continuous, and magnetizable medium, the fields '''B''' and '''H''' are related as follows,
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The material constant &mu;, which expresses the "ease" of magnetization of the medium, is called the [[magnetic permeability]] of the medium.
The material constant &mu;, which expresses the "ease" of magnetization of the medium, is called the [[magnetic permeability]] of the medium.
The SI unit measuring the strength of '''B''' is T (tesla), and the Gaussian unit is gauss. One tesla is 10&thinsp;000 gauss. To indicate the order of magnitude: the magnetic field (or better magnetic induction) of the Earth is about 0.5 gauss = 50 &mu;T. The strongest magnets in laboratories are about 30 T.

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In physics, and more in particular in the theory of electromagnetism, magnetic induction (commonly denoted by B) is a vector field closely related to the magnetic field H.

The SI unit measuring the strength of B is T (tesla), and the Gaussian unit is gauss. One tesla is 10 000 gauss. To indicate the order of magnitude: the magnetic field (or better magnetic induction) of the Earth is about 0.5 gauss = 50 μT. A medical MRI diagnostic machine typically supports a field of 2 T. The strongest magnets in laboratories are presently about 30 T.

Relation between B and H

In vacuum, that is, in the absence of a ponderable, continuous, and magnetizable medium, the fields B and H are related as follows,

where μ0 is the magnetic constant (equal to 4π⋅10−7 N/A2).

In a continuous magnetizable medium the relation between B and H contains the magnetization M of the medium,

which expresses the fact that B is modified by the induction of a magnetic moment (non-zero magnetization) in the medium.

In almost all media, the magnetization M is linear in H,

For a magnetically isotropic medium the magnetic susceptibility tensor χ is a constant times the identity 3×3 matrix, χ = χm 1. For an isotropic medium we obtain for SI and Gaussian units, respectively, the relation between B and H,

The material constant μ, which expresses the "ease" of magnetization of the medium, is called the magnetic permeability of the medium.