Magnetic_flux, Magnetic_flux Information, Magnetic


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Electromagnetism

Electricity · Magnetism

Electrostatics
Electric charge · Coulomb\'s law Electric field · Gauss\' law Electric potential Electric dipole moment

Magnetostatics
Ampère\'s law · Electric current Magnetic field · Magnetic flux Biot-Savart law Magnetic dipole moment

Electrodynamics
Free space Lorentz force law EMF · Electromagnetic induction Faraday\'s law · Displacement current Maxwell\'s equations · EM field Electromagnetic radiation Eddy current · Maxwell tensor

Covariant formulation
Liénard-Wiechert Potentials Electromagnetic tensor EM Stress-energy tensor

Scientists
Coulomb · Ampere · Maxwell · others

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Magnetic flux, represented by the Greek letter Φ (phi), is a measure of quantity of magnetism, taking into account the strength and the extent of a magnetic field. The SI unit of magnetic flux is the weber (in derived units: volt-seconds), and the unit of magnetic field is the weber per square meter, or tesla.

Description

The flux through an element of area perpendicular to the direction of magnetic field is given by the product of the magnetic field and the area element. More generally, magnetic flux is defined by a scalar product of the magnetic field and the area element vector. Gauss\'s law for magnetism, which is one of the four Maxwell\'s equations, states that the total magnetic flux through a closed surface is zero. This law is a consequence of the empirical observation that magnetic monopoles do not exist or are not measurable.

The magnetic flux is defined as the integral of the magnetic field over an area:

\Phi_m = \int \!\!\! \int \mathbf{B} \cdot d\mathbf S\,

where

\Phi_m \

is the magnetic flux

B is the magnetic field

S is the surface (area).

We know from Gauss\'s law for magnetism that

\nabla \cdot \mathbf{B}=0.\,

The volume integral of this equation, in combination with the divergence theorem, provides the following result:

\int \!\!\! \int \!\!\! \int_V \nabla \cdot \mathbf{B} \, d\tau = \oint \!\!\! \oint_{\partial V} \mathbf{B} \cdot d\mathbf{S}=0.

In other words, the magnetic flux through any closed surface must be zero; there are no "magnetic charges".

By way of contrast, Gauss\'s law for electric fields, another of Maxwell\'s equations, is

\nabla \cdot \mathbf{E} = {\rho \over \epsilon_0},

where

E is the electric field,

\rho

is the free electric charge density, (not including dipole charges bound in a material),

\epsilon_0

is the electric constant which is permittivity of free space.

Note that this indicates the presence of electric monopoles, that is, free positive or negative charges.

The direction of the magnetic field vector $\mathbf{B}$ is by definition from the south to the north pole of a magnet (within the magnet). Outside of the magnet, the field lines will go from north to south.

A change of magnetic flux through a loop of conductive wire will cause an electromotive force, and therefore an electric current, in the loop. The relationship is given by Faraday\'s law:

$\mathcal{E} = \oint \mathbf{E} \cdot d\mathbf{s} = -{d\Phi_m \over dt}.$

This is the principle behind an electrical generator.

External articles

Patents

Vicci, U.S. Patent 6,720,855 , Magnetic-flux conduits

This article is licensed under the GNU Free Documentation License. It uses material from Wikipedia

Magnetic_flux

Description

See also

External articles