2 Grammar
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The electromagnetic induction of a moving charge in a magnetic field is based on the electron’s magnetic moment. The magnetic field turns the magnetic dipole moment of the electron in the direction of the magnetic field. The motion of the electron undergoes a - predictable and perpendicular on the two vectors of the velocity and the magnetic field - acceleration according to the cross product of this two vectors. This acceleration leads out to the emission of a photon from the electron (Bremsstrahlung).

As theThe photon has a pulse, and this pulse reduces the velocity of the electron, and also acts against the momentum change of the electron’s magnetic moment by the external magnetic field gyroscope effect too. This process is repeated periodically until the kinetic energy of the electron is consumed.

To give the shortes possible answer I add a second answer.

The electromagnetic induction of a moving charge in a magnetic field is based on the electron’s magnetic moment. The magnetic field turns the magnetic moment of the electron in the direction of the magnetic field. The motion of the electron undergoes a - predictable and perpendicular on the two vectors of the velocity and the magnetic field - acceleration according to the cross product of this two vectors. This acceleration leads out to the emission of a photon from the electron (Bremsstrahlung).

As the photon has a pulse, this pulse reduces the velocity of the electron, and also acts against the momentum change of the electron’s magnetic moment by the external magnetic field gyroscope effect. This process is repeated periodically until the kinetic energy of the electron is consumed.

To give the shortes possible answer I add a second answer.

The electromagnetic induction of a moving charge in a magnetic field is based on the electron’s magnetic moment. The magnetic field turns the magnetic dipole moment of the electron in the direction of the magnetic field. The motion of the electron undergoes a - predictable and perpendicular on the two vectors of the velocity and the magnetic field - acceleration according to the cross product of this two vectors. This acceleration leads out to the emission of a photon from the electron (Bremsstrahlung).

The photon has a pulse and this pulse reduces the velocity of the electron and acts against the momentum change of the electron’s magnetic moment by the external magnetic field gyroscope effect too. This process is repeated periodically until the kinetic energy of the electron is consumed.

1
source | link

To give the shortes possible answer I add a second answer.

The electromagnetic induction of a moving charge in a magnetic field is based on the electron’s magnetic moment. The magnetic field turns the magnetic moment of the electron in the direction of the magnetic field. The motion of the electron undergoes a - predictable and perpendicular on the two vectors of the velocity and the magnetic field - acceleration according to the cross product of this two vectors. This acceleration leads out to the emission of a photon from the electron (Bremsstrahlung).

As the photon has a pulse, this pulse reduces the velocity of the electron, and also acts against the momentum change of the electron’s magnetic moment by the external magnetic field gyroscope effect. This process is repeated periodically until the kinetic energy of the electron is consumed.