Matthias rules explained

In physics, the Matthias rules refers to a historical set of empirical guidelines on how to find superconductors. These rules were authored Bernd T. Matthias who discovered hundreds of superconductors using these principles in the 1950s and 1960s. Deviations from these rules have been found since the end of the 1970s with the discovery of unconventional superconductors.

History

Superconductivity was first discovered in solid mercury in 1911 by Heike Kamerlingh Onnes and Gilles Holst, who had developed new techniques to reach near-absolute zero temperatures.^{[1] [2] [3]}

In subsequent decades, superconductivity was found in several other materials; In 1913, lead at 7 K, in 1930's niobium at 10 K, and in 1941 niobium nitride at 16 K.

In 1933, Walther Meissner and Robert Ochsenfeld discovered that superconductors expelled applied magnetic fields, a phenomenon that has come to be known as the Meissner effect.

Bernd T. Matthias and John Kenneth Hulm were encouraged by Enrico Fermi to start a systematic experimental investigation in the 1950s, looking for superconductors in different elements and compounds. For this reason, they developed a technique based on the Meissner effect.^[4]

In collaboration with Theodore H. Geballe, Matthias broke the record in 1954, with the discovery of superconductivity in niobium–tin (Nb₃Sn) which had the highest known transition temperature of about 18 K.^[5] Later Matthias would try to come up with general empirical properties to find superconducting alloys. In the same year he published a first version of his famous guidelines which came to be known, as the "Mathias rules".^{[6] [7]} Matthias was able to show in 1962 that some deviations from his rules where due to impurities or defects in the materials. Using his rules, Matthias and collaborators found in 1965 that niobium–germanium (Nb₃Sn) with a record critical temperature above 20 K.^[8]

Matthias published a first outline his rules in 1957. A successful microscopic theory of superconductivity would no come up until the same year, with the development of the BCS theory by John Bardeen, Leon Cooper, and John Robert Schrieffer.^[9]

Geballe and Matthias won the Oliver E. Buckley Condensed Matter Prize in 1970 for "For their joint experimental investigations of superconductivity which have challenged theoretical understanding and opened up the technology of high field superconductors."^[10]

One of the first deviations of Matthias' rules was found with the discovery of superconductivity in molybdenum sulfide and selenides. Matthias postulated an additional criterion in 1976 at the Rochester Conference on superconductivity to include these materials.

Another violation of Matthias rules appeared in 1979, with the discovery of heavy fermion superconductors by Frank Steglich^[11]

Notes and References

1. Sengers, Johanna Levelt: How Fluids Unmix: Discoveries by the School of Van der Waals and Kamerlingh Onnes. (Edita—the Publishing House of the Royal, 2002, 318 pp)
2. van Delft, Dirk (2007) Freezing physics, Heike Kamerlingh Onnes and the quest for cold, Edita, Amsterdam, .
3. Blundell, Stephen: Superconductivity: A Very Short Introduction. (Oxford University Press, 1st edition, 2009, p. 20)
4. Book: Rogalla . Horst . 100 Years of Superconductivity . Kes . Peter H. . 2011-11-11 . Taylor & Francis . 978-1-4398-4948-4 . en.
5. Matthias . B. T. . Geballe . T. H. . Geller . S. . Corenzwit . E. . 1954-09-15 . Superconductivity of Nb 3 Sn . Physical Review . en . 95 . 6 . 1435 . 10.1103/PhysRev.95.1435 . 1954PhRv...95.1435M . 0031-899X.
6. Book: Geballe . T. H. . Bernd Theodor Matthias 1918–1990 . Hulm . J. K. . National Academy of Science . 1996.
7. Matthias . B. T. . 1955-01-01 . Empirical Relation between Superconductivity and the Number of Valence Electrons per Atom . Physical Review . en . 97 . 1 . 74–76 . 10.1103/PhysRev.97.74 . 1955PhRv...97...74M . 0031-899X.
8. Arrhenius . G. . Corenzwit . E. . Fitzgerald . R. . Hull . G. W. . Luo . H. L. . Matthias . B. T. . Zachariasen . W. H. . 1968 . SUPERCONDUCTIVITY OF NB ₃ (AL, GE) ABOVE 20.5°K . Proceedings of the National Academy of Sciences . en . 61 . 2 . 621–628 . 10.1073/pnas.61.2.621 . 0027-8424 . 225205 . 16591705 . free .
9. Bardeen . J. . Cooper, L. N. . Schrieffer, J. R. . December 1957 . Theory of Superconductivity . Physical Review . 108 . 5 . 1175–1204 . 1957PhRv..108.1175B . 10.1103/PhysRev.108.1175 . free.
10. Web site: Prize Recipient . 2023-08-09 . www.aps.org . en.
11. Book: Saunders . P. J. . The Rise of the Superconductors . Ford . G. A. . 2005 . CRC Press . 0-7484-0772-3 . Boca Raton, FL.
12. Bednorz . J. G. . Müller . K. A. . 1986 . Possible high _c superconductivity in the Ba-La-Cu-O system . . 64 . 2 . 189–193 . 1986ZPhyB..64..189B . 10.1007/BF01303701 . 118314311.
13. Book: Uchida, Shin-ichi . High Temperature Superconductivity: The Road to Higher Critical Temperature . 2014-11-20 . Springer . 978-4-431-55300-7 . en.
14. Mazin . Igor I. . 2010 . Superconductivity gets an iron boost . Nature . en . 464 . 7286 . 183–186 . 10.1038/nature08914 . 20220835 . 2010Natur.464..183M . 4391681 . 0028-0836.
15. Conder . K . 2016-08-01 . A second life of the Matthias's rules . Superconductor Science and Technology . 29 . 8 . 080502 . 10.1088/0953-2048/29/8/080502 . 2016SuScT..29h0502C . 123619400 . 0953-2048. free .
16. Book: Seidel, Paul . Applied Superconductivity: Handbook on Devices and Applications . 2015-01-22 . John Wiley & Sons . 978-3-527-67066-6 . en.
17. Book: Grimaldi, C. . https://books.google.com/books?id=vjCtzYfcfBQC&dq=grimaldi+superconductivity+matthias+rules&pg=PA30 . Superconducting Materials for High Energy Colliders: Proceedings of the 38th Workshop of the INFN Eloisatron Project, Erice, Italy, 19-25 October 1999 . 2001 . World Scientific . 978-981-02-4319-7 . Cifarelli . Luisa . en . Possible mechanisms of high T_C superconductivity.
18. Steglich . F. . Aarts . J. . Bredl . C. D. . Lieke . W. . Meschede . D. . Franz . W. . Schäfer . H. . 1979-12-17 . Superconductivity in the Presence of Strong Pauli Paramagnetism: Ce$_$$_$ |url=https://link.aps.org/doi/10.1103/PhysRevLett.43.1892 |journal=Physical Review Letters |volume=43 |issue=25 |pages=1892–1896 |doi=10.1103/PhysRevLett.43.1892|bibcode=1979PhRvL..43.1892S |hdl=1887/81461 |s2cid=123497750 |hdl-access=free }} where magnetism was expected to play a role, contrary to the Matthias rules.

    Matthias held the record of highest critical temperature superconductor found until the discovery of high-temperature superconductors were discovered in 1986 by Georg Bednorz and K. Alex Müller.^{[11] [12] [13]}

    Description

    The Matthias rules are a set of guidelines to find low temperature superconductors but were never provided in list form by Matthias.

    A popular summarized version of these rules reads:^{[14] [15] [16] [17]}

    1. High symmetry is good, cubic symmetry is the best.
    2. High density of electronic states is good.
    3. Stay away from oxygen.
       1. Stay away from magnetism Stay away from insulators.
    4. Stay away from theorists!

    Rule 2, rules out materials near metal-insulator transition like oxides. Rule 4, rules out material that are in close vicinity to ferromagnetism or antiferromagnetism. Rule 6 is not an official rule and is often added to indicate skepticism of the theories of the time.

    Other equivalent principles as stated by Matthias, indicate to work mainly with d-electron metals; with the average number of valence electrons, preferably odd numbers 3, 5, and 7 and high electron density or high electron density of state at the Fermi level.

    In 1976, Mattias added the criterion to include "elements which will not react at all with molybdenum alone form superconducting compounds with Mo₃S₄ and Mo₃Se₄, S or Se" due to deviations in molydenum compounds.

    Failure and extensions

    It has been argued that all of Matthias' rules have been shown to not be completely valid. Specially the rules are not valid for high-temperature superconductors, alternative rules for these materials have been suggested.

    References

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