The Phenomenon of Superconductivity
The Phenomenon of Superconductivity
The electrical resistivity of a metal arises from the interactions of the conduction electrons with impurities, defects and the vibrating ions of the lattice. As the temperature is lowered, the amplitudes of the lattice vibrations diminish, so one would expect the resistivity also to decrease gradually toward a small, but finite, value determined by the impurities and defects. This behavior is manifested by many materials.
In 1911 H. Kamerlingh Onnes discovered that as the temperature of mercury was reduced, its resistance suddenly dropped to an extremely small value at 4.15 K. The metal had made a transition to a new superconducting state. The resistivity of a superconductor is at least a factor of 10-12 less than that for an ordinary conductor. We can usually take it to be zero. In superconductors electrical energy can be transported without resistive losses, provided the temperature is maintained below the critical temperature, Tc.
�High temperature superconductors’ are such that remains superconductors in relatively high temperatures (for example 77K).
In addition to their obvious use in electromagnets, there are other applications