Superconductor

A superconductor is a material that has no electrical resistance and magnetic flux fields are expelled from it. Such a material exhibits superconductivity. It can store electrical energy indefinitely and is capable of lossless energy transmission.

An ordinary metallic conductor's resistance decreases as its temperature is lowered towards absolute zero, but a superconductor has a critical temperature below which the resistance is zero.

Superconductor materials include mercury, lead, niobium alloys, ceramics, pnictides, fullerenes and carbon nanotubes.

Initially wires and cables allowed electric power in the form of supercurrents to flow without losing energy to resistance or heating the wires. In time they were replaced by superconductive ribbons for use in inductors, transformers, motors and generators.

Energy storage
If a superconductive path forms a complete loop, a supercurrent can flow around the loop forever. A device that produces a strong magnetic field will store large amounts of energy. A superconductive ribbon wound tightly around a tube creates an electromagnet, creating a superconductive solenoid can discharge all of its energy instantly if needed. This effect can be harnessed in the manufacture of explosives.

Solenoids are competitive with other forms of consumer energy storage such as torsion batteries and flywheels and have the highest specific electrical power of any energy storage device. Vehicles make use of solenoidal tubes and tension cable/sheet construction for their chassis. This leads to cars that can be deflated and easily stored in a compact volume, useful in Type I where there could be a premium of parking space.

Magnetic Levitation
When superconductors expels all magnetic fields from their interior, it will be repelled from all sources of a magnetic field, and the field sources will likewise be repelled from the superconductor. This levitates magnets over a superconductive surface, or a superconductor over a magnet. This effect has many uses, including maglev trains, vactrains and frictionless bearings.

Electromagnetism
Superconductors reflect electromagnetic waves. This allows powerful sources of radio waves, microwaves, and far infrared to be produced. These have applications ranging from radar beams to mass drivers to free electron lasers.

Sensors and computing
If two superconducting regions are placed closely adjacent to each other, a current flows between them. This produces sensitive magnetic field detectors called Superconducting Quantum Interference Devices (SQUIDs) which enable a wide range of sensor and detector technologies such as medical and MRI scanners. Their high switching rate, low energy per switch, and low energy dissipation makes them ideal for quantum computers.

Other uses:

 * force fields and where magnetic confinement is needed
 * high-performance smart electric grid
 * enhancing spintronic devices
 * magnetic refrigeration
 * Superconducting magnetic energy storage (SMES) systems store energy in the magnetic field created by the flow of direct current in a superconducting coil. This is used for improving the quality and stability of power grids.