Superconductors
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Presented By: Rohit Kumar 1101216103
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Transcript of Superconductors
Presented By:Rohit Kumar1101216103
WHAT IS SUPERCONDUCTIVITY??
For some materials, the resistivity vanishes at some low temperature: they become superconducting.
Superconductivity is the ability of certain materials to conduct electrical current with no resistance. Thus, superconductors can carry large amounts of current with little or no loss of energy.
Type I superconductors: pure metals, have low critical field
Type II superconductors: primarily of alloys or intermetallic compounds.
MEISSNER EFFECT
B
T >Tc T < Tc
B
When you place a superconductor in a magnetic field, the field is expelled below TC.
Magnet Currents i appear, to cancel B.
i x B on the superconductorproduces repulsion.
Superconductor
A superconductor displaying the MEISSNER EFFECT
Superconductors have electronic and magnetic properties. That is, they have a negative susceptibility, and acquire a polarization OPPOSITE to an applied magnetic field. This is the reason that superconducting materials and magnets repel one another.
If the temperature increases the sample will lose its superconductivity and the magnet cannot float on the superconductor.
Record TC versus Year Discovered
0
20
40
60
80
100
120
140
160
180
1900 1910 1920 1930 1940 1950 1960 1970 1980 1990 2000
Year
TC (
K)
Hg
NbNNb3Ge
La-Ba-Cu-O
La-Sr-Cu-O
YBa2Cu3O7
Bi2Sr2Ca2Cu3O8
Tl-Ba-Ca-Cu-O
HgBa2Ca2Cu2O8
HgBa2Ca2Cu2O8 Pressure
1986
APPLICATIONS
Superconducting Magnetic Levitation Medical(Magnetic Resonance Imaging) Power Particle Accelerators( like SSC)
APPLICATIONS: Power
Superconducting Transmission CableFrom American Superconductor
The cable configuration features a conductor made from HTS wires wound around a flexible hollow core. Liquid nitrogen flows through the core, cooling the HTS wire to the zero resistance state.
The conductor is surrounded by conventional dielectric insulation. The efficiency of this design reduces losses.
APPLICATIONS: Superconducting Magnetic Levitation
The track are walls with a continuous series of vertical coils of wire mounted inside. The wire in these coils is not a superconductor.
As the train passes each coil, the motion of the superconducting magnet on the train induces a current in these coils, making them electromagnets.
The electromagnets on the train and outside produce forces that levitate the train and keep it centered above the track. In addition, a wave of electric current sweeps down these outside coils and propels the train forward.
The Yamanashi MLX01MagLev Train
FUTURE APPLICATIONS
SOLAR POWER GENERATION HIGH EFFCIENCY WIND TURBINES ENERGY STORAGE DEVICES
ANY QUERIES??
