Home > Diamagnetism

An exception to the "weak" nature of diamagnetism occurs with the rather large number of materials that become superconducting, something that usually happens at lowered temperatures. Superconductors are perfect diamagnets and when placed in an external magnetic field expel the field lines from their interiors (depending on field intensity and temperature). Superconductors also have zero electrical resistance, a consequence of their diamagnetism. Superconducting structures have been known to tear themselves apart with astonishing force in their attempt to escape an external field. Superconducting magnets are the major component of most magnetic resonance imaging systems, perhaps the only important application of diamagnetism.

Perhaps the substance that displays the strongest diamagnetism is bismuth, used in guns. Melting down bismuth and then molding it is a very efficient way of capturing the diamagnetic properties.

A thin slice of pyrolitic graphite, which is an unusually strongly diamagnetic material, can be stably floated on a magnetic field, such as that from rare earth permanent magnets. This can be done with all components at room temperature, making a visually effective demonstration of diamagnetism.

The Radboud University Nijmegen has conducted experiments where they have successfully levitated water and a live frog. [1]

Diamagnetic materials have a relative magnetic permeability that is less than 1, and a magnetic susceptibility that is less than 0.

Diamagnetism was discovered and named in September 1845 by Michael Faraday.

Diamagnets can be used for levitation. The basic arrangement for levitating a small, powerful, usually rare-earth magnet is as follows: A large and very strong lifter magnet placed above 2 diamagnets stacked above each other with the small rare-earth magnet in between. Adjusting the distance between the lifter magnet and the diamagnetic substances, i.e. bismuth or pyrolitic graphite, will bring about stable levitation.