Superconductor classification

Superconductors can be classified in accordance with several criteria that depend on physical properties, current understanding, and the expense of cooling them or their material.

By their magnetic properties

Type I superconductors: those having just one critical field, H_c, and changing abruptly from one state to the other when it is reached.
Type II superconductors: having two critical fields, H_c1 and H_c2, being a perfect superconductor under the lower critical field (H_c1) and leaving completely the superconducting state to a normal conducting state above the upper critical field (H_c2), being in a mixed state when between the critical fields.
Type-1.5 superconductor – Multicomponent superconductors characterized by two or more coherence lengths

By the understanding we have about them

Conventional superconductors: those that can be fully explained with the BCS theory or related theories.
Unconventional superconductors: those that failed to be explained using such theories, e.g.:
- Heavy fermion superconductors

This criterion is important, as the BCS theory has explained the properties of conventional superconductors since 1957, yet there have been no satisfactory theories to explain unconventional superconductors fully. In most cases, type I superconductors are conventional, but there are several exceptions such as niobium, which is both conventional and type II.

By their critical temperature

Low-temperature superconductors, or LTS: those whose critical temperature is below 77 K.
High-temperature superconductors, or HTS: those whose critical temperature is above 77 K.
- Room-temperature superconductors: those whose critical temperature is above 273 K.

77 K is used as the split to emphasize whether or not superconductivity in the materials can be achieved with liquid nitrogen (whose boiling point is 77K), which is much more feasible than liquid helium (an alternative to achieve the temperatures needed to get low-temperature superconductors).

By material constituents and structure

Some pure elements, such as lead or mercury (but not all pure elements, as some never reach the superconducting phase).
- Some allotropes of carbon, such as fullerenes, nanotubes, or diamond.

Most superconductors made of pure elements are type I (except niobium, technetium, vanadium, silicon, and the above-mentioned Carbon allotropes)

Alloys, such as
- Niobium-titanium (NbTi), whose superconducting properties were discovered in 1962.
Ceramics (often insulators in the normal state), which include
- Cuprates i.e. copper oxides (often layered, not isotropic)
  - The YBCO family, which are several yttrium-barium-copper oxides, especially YBa₂Cu₃O₇. They are the most famous high-temperature superconductors
- Nicklates (RNiO₂ R=Rare earth ion) where Sr-doped infinite-layer nickelate NdNiO₂[1] undergo a superconducting transition at 9-15 K. In the family of Ruddlesden-Popper phase analogon Nd₆Ni₅O₁₂ (n=5) becomes superconducting at 13 K[2] This is not a complete list and topic of current research.
- Iron-based superconductors, including the oxypnictides
- Magnesium diboride (MgB₂), whose critical temperature is 39K,[3] being the conventional superconductor with the highest known temperature.
- non-cuprate oxides such as BKBO
Palladates – palladium compounds.[4][5]
other

e.g. the "metallic" compounds Hg
₃NbF
₆ and Hg
₃TaF
₆ are both superconductors below 7 K (−266.15 °C; −447.07 °F).[6]

References

Li, Danfeng; Lee, Kyuho; Wang, Bai Yang; Osada, Motoki; Crossley, Samuel; Lee, Hye Ryoung; Cui, Yi; Hikita, Yasuyuki; Hwang, Harold Y. (August 2019). "Superconductivity in an infinite-layer nickelate". Nature. 572 (7771): 624–627. doi:10.1038/s41586-019-1496-5. ISSN 1476-4687.
Pan, Grace A.; Ferenc Segedin, Dan; LaBollita, Harrison; Song, Qi; Nica, Emilian M.; Goodge, Berit H.; Pierce, Andrew T.; Doyle, Spencer; Novakov, Steve; Córdova Carrizales, Denisse; N’Diaye, Alpha T.; Shafer, Padraic; Paik, Hanjong; Heron, John T.; Mason, Jarad A. (February 2022). "Superconductivity in a quintuple-layer square-planar nickelate". Nature Materials. 21 (2): 160–164. arXiv:2109.09726. doi:10.1038/s41563-021-01142-9. ISSN 1476-4660.
Jun Nagamatsu, Norimasa Nakagawa, Takahiro Muranaka, Yuji Zenitani and Jun Akimitsu (March 1, 2001). "Superconductivity at 39 K in magnesium diboride". Nature. 410 (6824): 63–64. Bibcode:2001Natur.410...63N. doi:10.1038/35065039. PMID 11242039. S2CID 4388025.{{cite journal}}: CS1 maint: multiple names: authors list (link)
Kitatani, Motoharu; Si, Liang; Worm, Paul; Tomczak, Jan M.; Arita, Ryotaro; Held, Karsten (2023). "Optimizing Superconductivity: From Cuprates via Nickelates to Palladates". Physical Review Letters. Vol. 130, no. 16. doi:10.1103/PhysRevLett.130.166002.
"Palladium-based compounds may be the superconductors of the future, scientists say".
W.R. Datars, K.R. Morgan and R.J. Gillespie (1983). "Superconductivity of Hg₃NbF₆ and Hg₃TaF₆". Phys. Rev. B. 28 (9): 5049–5052. Bibcode:1983PhRvB..28.5049D. doi:10.1103/PhysRevB.28.5049.

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[1] Li, Danfeng; Lee, Kyuho; Wang, Bai Yang; Osada, Motoki; Crossley, Samuel; Lee, Hye Ryoung; Cui, Yi; Hikita, Yasuyuki; Hwang, Harold Y. (August 2019). "Superconductivity in an infinite-layer nickelate". Nature. 572 (7771): 624–627. doi:10.1038/s41586-019-1496-5. ISSN 1476-4687.

[2] Pan, Grace A.; Ferenc Segedin, Dan; LaBollita, Harrison; Song, Qi; Nica, Emilian M.; Goodge, Berit H.; Pierce, Andrew T.; Doyle, Spencer; Novakov, Steve; Córdova Carrizales, Denisse; N’Diaye, Alpha T.; Shafer, Padraic; Paik, Hanjong; Heron, John T.; Mason, Jarad A. (February 2022). "Superconductivity in a quintuple-layer square-planar nickelate". Nature Materials. 21 (2): 160–164. arXiv:2109.09726. doi:10.1038/s41563-021-01142-9. ISSN 1476-4660.

[3] Jun Nagamatsu, Norimasa Nakagawa, Takahiro Muranaka, Yuji Zenitani and Jun Akimitsu (March 1, 2001). "Superconductivity at 39 K in magnesium diboride". Nature. 410 (6824): 63–64. Bibcode:2001Natur.410...63N. doi:10.1038/35065039. PMID 11242039. S2CID 4388025.{{cite journal}}: CS1 maint: multiple names: authors list (link)

[4] Kitatani, Motoharu; Si, Liang; Worm, Paul; Tomczak, Jan M.; Arita, Ryotaro; Held, Karsten (2023). "Optimizing Superconductivity: From Cuprates via Nickelates to Palladates". Physical Review Letters. Vol. 130, no. 16. doi:10.1103/PhysRevLett.130.166002.

[5] "Palladium-based compounds may be the superconductors of the future, scientists say".

[6] W.R. Datars, K.R. Morgan and R.J. Gillespie (1983). "Superconductivity of Hg₃NbF₆ and Hg₃TaF₆". Phys. Rev. B. 28 (9): 5049–5052. Bibcode:1983PhRvB..28.5049D. doi:10.1103/PhysRevB.28.5049.