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Universal behavior of strongly correlated Fermi systems

 a,  b,  c
a B.P. Konstantinov St. Petersburg Institute of Nuclear Physics, Russian Academy of Sciences, Gatchina, Leningrad Region, Rusian Federation
b Ioffe Institute, ul. Polytekhnicheskaya 26, St. Petersburg, 194021, Russian Federation
c Komi Scientific Center, Ural Branch of the Russian Academy of Sciences, ul. Chernova 3a, Syktyvkar, Respublika Komi, 167982, Russian Federation

This review discusses the construction of а theory and the analysis of phenomena occurring in strongly correlated Fermi systems such as high-Тc superconductors, heavy-fermion metals, and quasi-two-dimensional Fermi systems. It is shown that the basic properties and the universal behavior of strongly correlated Fermi systems can be described in the framework of the Fermi-condensate quantum phase transition and the well-known Landau paradigm of quasiparticles and the order parameter. The concept of fermion condensation may be fruitful in studying neutron stars, finite Fermi systems, ultra-cold gases in traps, and quark plasma.

Fulltext pdf (507 KB)
Fulltext is also available at DOI: 10.1070/PU2007v050n06ABEH006288
PACS: 71.27.+a, 74.20.Fg, 74.25.Jb (all)
DOI: 10.1070/PU2007v050n06ABEH006288
URL: https://ufn.ru/en/articles/2007/6/a/
000249986100001
2-s2.0-35248871984
2007PhyU...50..563S
Citation: Shaginyan V R, Amusia M Ya, Popov K G "Universal behavior of strongly correlated Fermi systems" Phys. Usp. 50 563–593 (2007)
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Оригинал: Шагинян В Р, Амусья М Я, Попов К Г «Универсальное поведение сильнокоррелированных ферми-систем» УФН 177 585–618 (2007); DOI: 10.3367/UFNr.0177.200706a.0585

References (146) Cited by (45) ↓ Similar articles (20)

  1. Amusia M, Shaginyan V Springer Tracts In Modern Physics Vol. Strongly Correlated Fermi SystemsTopological Fermion-Condensation Quantum Phase Transition283 Chapter 4 (2020) p. 49
  2. Amusia M, Shaginyan V Springer Tracts In Modern Physics Vol. Strongly Correlated Fermi SystemsLandau Fermi Liquid Theory283 Chapter 2 (2020) p. 21
  3. Amusia M, Shaginyan V Springer Tracts In Modern Physics Vol. Strongly Correlated Fermi SystemsHeavy-Fermion Compounds as the New State of Matter283 Chapter 16 (2020) p. 235
  4. Amusia M, Shaginyan V Springer Tracts In Modern Physics Vol. Strongly Correlated Fermi SystemsQuantum Spin Liquid in Geometrically Frustrated Magnets and the New State of Matter283 Chapter 8 (2020) p. 125
  5. Amusia M, Shaginyan V Springer Tracts In Modern Physics Vol. Strongly Correlated Fermi SystemsIntroduction283 Chapter 1 (2020) p. 1
  6. Amusia M, Shaginyan V Springer Tracts In Modern Physics Vol. Strongly Correlated Fermi SystemsQuasi-classical Physics Within Quantum Criticality in HF Compounds283 Chapter 17 (2020) p. 247
  7. Amusia M, Shaginyan V Springer Tracts In Modern Physics Vol. Strongly Correlated Fermi SystemsAsymmetric Conductivity of Strongly Correlated Compounds283 Chapter 18 (2020) p. 271
  8. Amusia M, Shaginyan V Springer Tracts In Modern Physics Vol. Strongly Correlated Fermi SystemsTopological FCQPT in Strongly Correlated Fermi Systems283 Chapter 6 (2020) p. 89
  9. Shaginyan V R, Stephanovich V A et al J Mater Sci 55 2257 (2020)
  10. Amusia M, Shaginyan V Springer Tracts In Modern Physics Vol. Strongly Correlated Fermi SystemsQuantum Criticality of Heavy-Fermion Compounds283 Chapter 21 (2020) p. 311
  11. Amusia M, Shaginyan V Springer Tracts In Modern Physics Vol. Strongly Correlated Fermi SystemsThe Universal Behavior of the Archetypical Heavy-Fermion Metals $$mathrm YbRh_2Si_2$$283 Chapter 15 (2020) p. 225
  12. Shaginyan V R, Stephanovich V A et al J Low Temp Phys 189 410 (2017)
  13. Popov A V Crystallogr. Rep. 61 1 (2016)
  14. Amusia M Ya, Popov K G et al Springer Series In Solid-State Sciences Vol. Theory of Heavy-Fermion CompoundsIntroduction182 Chapter 1 (2015) p. 1
  15. Amusia M Ya, Popov K G et al Springer Series In Solid-State Sciences Vol. Theory of Heavy-Fermion CompoundsMetals with a Strongly Correlated Electron Liquid182 Chapter 8 (2015) p. 139
  16. Amusia M Ya, Popov K G et al Springer Series In Solid-State Sciences Vol. Theory of Heavy-Fermion CompoundsQuantum Criticality of Heavy-Fermion Compounds182 Chapter 18 (2015) p. 317
  17. Amusia M Ya, Popov K G et al Springer Series In Solid-State Sciences Vol. Theory of Heavy-Fermion CompoundsAsymmetric Conductivity of Strongly Correlated Compounds182 Chapter 13 (2015) p. 235
  18. Amusia M Ya, Popov K G et al Springer Series In Solid-State Sciences Vol. Theory of Heavy-Fermion CompoundsQuasi-classical Physics Within Quantum Criticality in HF Compounds182 Chapter 9 (2015) p. 155
  19. Amusia M Ya, Popov K G et al Springer Series In Solid-State Sciences Vol. Theory of Heavy-Fermion CompoundsLandau Fermi Liquid Theory and Beyond182 Chapter 2 (2015) p. 21
  20. Zinov’ev G M, Molodtsov S V J. Exp. Theor. Phys. 120 57 (2015)
  21. Amusia M Ya, Popov K G et al Springer Series In Solid-State Sciences Vol. Theory of Heavy-Fermion CompoundsAppearance of Fermion-Condensation Quantum Phase Transition in Fermi Systems182 Chapter 5 (2015) p. 61
  22. Amusia M Ya, Popov K G et al Springer Series In Solid-State Sciences Vol. Theory of Heavy-Fermion CompoundsBaryon Asymmetry Resulting from FCQPT in the Early Universe182 Chapter 16 (2015) p. 273
  23. Amusia M Ya, Popov K G et al Springer Series In Solid-State Sciences Vol. Theory of Heavy-Fermion CompoundsFermi Liquid with Fermion Condensate182 Chapter 3 (2015) p. 31
  24. Shaginyan V R, Popov K G, Khodel V A Phys. Atom. Nuclei 77 1063 (2014)
  25. Bobrov V B, Trigger S A, Zagorodny A G Progress Of Theoretical And Experimental Physics 2013 23I01 (2013)
  26. Zinovjev G M, Molodtsov S V Phys. Part. Nuclei 44 577 (2013)
  27. CLARK J W, KHODEL V A, ZVEREV M V Int. J. Mod. Phys. B 27 1347005 (2013)
  28. Shaginyan V R Phys. Atom. Nuclei 74 1107 (2011)
  29. Khodel V A, Clark J W, Zverev M V Jetp Lett. 94 73 (2011)
  30. Khodel V A, Clark J W, Zverev M V Phys. Atom. Nuclei 74 1237 (2011)
  31. Shaginyan V R, Japaridze G S et al EPL 94 69001 (2011)
  32. Shaginyan V R, Amusia M Ya, Popov K G Physics Letters A 374 659 (2010)
  33. Khodel V A, Clark J W et al Jetp Lett. 92 532 (2010)
  34. Zverev M V, Clark J W et al Jetp Lett. 91 529 (2010)
  35. Popov A V Tech. Phys. 55 188 (2010)
  36. Shaginyan V R, Amusia M Ya et al Jetp Lett. 90 47 (2009)
  37. Shaginyan V R, Msezane A Z et al Physics Letters A 373 3783 (2009)
  38. Shaginyan V R, Amusia M Ya, Popov K G Physics Letters A 373 2281 (2009)
  39. Shaginyan V R, Amusia M Ya et al Physics Letters A 373 686 (2009)
  40. Shaginyan V R, Amusia M Ya et al Physics Letters A 373 986 (2009)
  41. Khodel V A, Clark J W, Zverev M V Phys. Rev. B 78 (7) (2008)
  42. Shaginyan V R, Msezane A Z et al Phys. Rev. Lett. 100 (9) (2008)
  43. Khodel V A Jetp Lett. 86 721 (2008)
  44. Popov A V Phys. Solid State 50 1592 (2008)
  45. Shaginyan V R, Popov K G Jetp Lett. 88 183 (2008)

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