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Type II superconductors are found to have much higher critical magnetic fields and therefore can carry much higher current densities while remaining in the superconducting state. A collection of various ceramics containing barium-copper-oxide have much higher critical temperatures for the transition into a superconducting state. Superconducting materials that belong to this subcategory of the Type II superconductors are often categorized as high-temperature superconductors.
Type I superconductors, along with some Type II superconductors can be modeled using the BCS theory , proposed by John Bardeen , Leon Cooper , and Robert Schrieffer . Although the theory is beyond the scope of this chapter, a short summary of the theory is provided here. (More detail is provided in Condensed Matter Physics .) The theory considers pairs of electrons and how they are coupled together through lattice-vibration interactions. Through the interactions with the crystalline lattice, electrons near the Fermi energy level feel a small attractive force and form pairs ( Cooper pairs ), and the coupling is known as a phonon interaction. Single electrons are fermions, which are particles that obey the Pauli exclusion principle. The Pauli exclusion principle in quantum mechanics states that two identical fermions (particles with half-integer spin) cannot occupy the same quantum state simultaneously. Each electron has four quantum numbers . The principal quantum number ( n ) describes the energy of the electron, the orbital angular momentum quantum number ( l ) indicates the most probable distance from the nucleus, the magnetic quantum number describes the energy levels in the subshell, and the electron spin quantum number describes the orientation of the spin of the electron, either up or down. As the material enters a superconducting state, pairs of electrons act more like bosons, which can condense into the same energy level and need not obey the Pauli exclusion principle. The electron pairs have a slightly lower energy and leave an energy gap above them on the order of 0.001 eV. This energy gap inhibits collision interactions that lead to ordinary resistivity. When the material is below the critical temperature, the thermal energy is less than the band gap and the material exhibits zero resistivity.
Material | Symbol or Formula | Critical Temperature
T c (K) |
Critical
Magnetic Field H c (T) |
Type |
---|---|---|---|---|
Elements | ||||
Lead | Pb | 7.19 | 0.08 | I |
Lanthanum | La | ( ) 4.90 − ( ) 6.30 | I | |
Tantalum | Ta | 4.48 | 0.09 | I |
Mercury | Hg | ( ) 4.15 − ( ) 3.95 | 0.04 | I |
Tin | Sn | 3.72 | 0.03 | I |
Indium | In | 3.40 | 0.03 | I |
Thallium | Tl | 2.39 | 0.03 | I |
Rhenium | Re | 2.40 | 0.03 | I |
Thorium | Th | 1.37 | 0.013 | I |
Protactinium | Pa | 1.40 | I | |
Aluminum | Al | 1.20 | 0.01 | I |
Gallium | Ga | 1.10 | 0.005 | I |
Zinc | Zn | 0.86 | 0.014 | I |
Titanium | Ti | 0.39 | 0.01 | I |
Uranium | U | ( ) 0.68 − ( ) 1.80 | I | |
Cadmium | Cd | 11.4 | 4.00 | I |
Compounds | ||||
Niobium-germanium | Nb 3 Ge | 23.20 | 37.00 | II |
Niobium-tin | Nb 3 Sn | 18.30 | 30.00 | II |
Niobium-nitrite | NbN | 16.00 | II | |
Niobium-titanium | NbTi | 10.00 | 15.00 | II |
High-Temperature Oxides | ||||
HgBa 2 CaCu 2 O 8 | 134.00 | II | ||
Tl 2 Ba 2 Ca 2 Cu 3 O 10 | 125.00 | II | ||
YBa 2 Cu 3 O 7 | 92.00 | 120.00 | II |
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