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Magnetic Fields01:27

Magnetic Fields

A moving charge or a current creates a magnetic field in the surrounding space, in addition to its electric field. The magnetic field exerts a force on any other moving charge or current that is present in the field. Like an electric field, the magnetic field is also a vector field. At any position, the direction of the magnetic field is defined as the direction in which the north pole of a compass needle points.
A magnetic field is defined by the force that a charged particle experiences...
The Hall Effect01:30

The Hall Effect

Edwin H. Hall, in the year 1879, devised an experiment that could be used to identify the polarity of the predominant charge carriers in a conducting material. From a historical perspective, this experiment was the first to demonstrate that the charge carriers in most metals are negative.
Potential Due to a Magnetized Object01:24

Potential Due to a Magnetized Object

Magnetic dipoles in magnetic materials are aligned when placed under an external magnetic field. For paramagnets and ferromagnets, dipole alignment occurs in the direction of the magnetic field. However, the dipoles align opposite to the field in the case of diamagnets. This state of magnetic polarization due to the external field is called magnetization. Magnetization is defined as the dipole moment per unit volume. It plays a similar role to polarization in electrostatics.
The vector...
Magnetic Damping01:17

Magnetic Damping

Eddy currents can produce significant drag on motion, called magnetic damping. For instance, when a metallic pendulum bob swings between the poles of a strong magnet, significant drag acts on the bob as it enters and leaves the field, quickly damping the motion.
If, however, the bob is a slotted metal plate, the magnet produces a much smaller effect. When a slotted metal plate enters the field, an emf is induced by the change in flux; however, it is less effective because the slots limit the...
Magnetic Susceptibility and Permeability01:31

Magnetic Susceptibility and Permeability

In linear magnetic materials, like paramagnets and diamagnets, magnetization is proportional to the magnetic field intensity. The constant of proportionality, a dimensionless number, is called magnetic susceptibility. The value of the susceptibility depends on the type of material.
When diamagnetic materials are placed under an external magnetic field, the moments opposite to the field are induced. Hence, the susceptibility for diamagnets has a minimal negative value of 10-5–10-6. Since...
Diamagnetism01:26

Diamagnetism

Materials consisting of paired electrons have zero net magnetic moments. However, when these materials are placed under an external magnetic field, the moments opposite to the field are induced. Such materials are called diamagnets. Diamagnetism is the response of the diamagnets when placed in an external magnetic field.
Diamagnetism was discovered by Anton Brugmans in 1778 when he observed that bismuth gets repelled by magnetic fields, thus theorizing that diamagnets get repelled by magnets.

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Related Experiment Video

Updated: May 8, 2026

Chemical Vapor Deposition of an Organic Magnet, Vanadium Tetracyanoethylene
08:25

Chemical Vapor Deposition of an Organic Magnet, Vanadium Tetracyanoethylene

Published on: July 3, 2015

Evidence for a magnetic Seebeck effect.

Sylvain D Brechet1, Francesco A Vetro, Elisa Papa

  • 1Institute of Condensed Matter Physics, Station 3, Ecole Polytechnique Fédérale de Lausanne-EPFL, CH-1015 Lausanne, Switzerland.

Physical Review Letters
|September 10, 2013
PubMed
Summary

A temperature gradient induces a magnetic induction field, the magnetic Seebeck effect. This phenomenon affects magnetization waves, attenuating those opposing the gradient and external field.

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Last Updated: May 8, 2026

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Area of Science:

  • Thermodynamics
  • Magnetism
  • Condensed Matter Physics

Background:

  • Irreversible thermodynamics governs continuous media with magnetic dipoles.
  • The Seebeck effect describes thermoelectric phenomena.

Purpose of the Study:

  • To explore the magnetic analog of the Seebeck effect.
  • Investigate the influence of temperature gradients on magnetization waves.

Main Methods:

  • Applying principles of irreversible thermodynamics.
  • Analyzing the behavior of magnetic dipoles in a continuous medium.
  • Modeling the interaction of temperature gradients with magnetization waves.

Main Results:

  • A temperature gradient induces a magnetic induction field.
  • This thermal gradient modulates magnetic precession and relaxation.
  • Magnetization waves aligned with the temperature gradient and external field show reduced attenuation.

Conclusions:

  • The magnetic Seebeck effect is a valid thermodynamic prediction.
  • Temperature gradients significantly impact magnetic wave propagation.
  • Understanding this effect is crucial for magnetic materials and devices.