PACS numbers

74.20.Mn Nonconventional mechanisms 74.25.−q Properties of superconductors 74.70.Xa Pnictides and chalcogenides
  1. S.I. Vedeneev “Pseudogap problem in high-temperature superconductors64 (9) (2021)
    74.20.Mn, 74.25.−q, 74.25.Jb, 74.72.−h (all)
  2. V.V. Val’kov, D.M. Dzebisashvili et alSpin-polaron concept in the theory of normal and superconducting states of cuprates64 641–670 (2021)
    71.10.−w, 71.10.Fd, 71.27.+a, 74.20.−z, 74.20.Mn, 74.25.N−, 74.72.−h (all)
  3. K.V. Mitsen, O.M. Ivanenko “Superconducting phase diagrams of cuprates and pnictides as a key to understanding the HTSC mechanism60 402–411 (2017)
    74.20.Mn, 74.25.Dw, 74.72.−h, 74.70.−b (all)
  4. T.E. Kuzmicheva, A.V. Muratov et alOn the structure of the superconducting order parameter in high-temperature Fe-based superconductors60 419–429 (2017)
    74.25.−q, 74.25.nd, 74.25.Ha, 74.45.+c, 74.70.Xa (all)
  5. V.P. Mineev “Superconductivity in uranium ferromagnets60 121–148 (2017)
    74.20.Mn, 74.20.Rp, 74.25.Dw, 74.70.Tx, 75.40.Gb (all)
  6. M.M. Korshunov, Yu.N. Togushova, O.V. Dolgov “Impurities in multiband superconductors59 1211–1240 (2016)
    74.20.Rp, 74.25.−q, 74.62.Dh (all)
  7. M.V. Sadovskii “High-temperature superconductivity in monolayers FeSe59 947–967 (2016)
    74.20.−z, 74.20.Fg, 74.20.Mn, 74.20.Rp, 74.25.Jb, 74.62.−c, 74.70.−b (all)
  8. M.Yu. Kagan, V.A. Mitskan, M.M. Korovushkin “Anomalous superconductivity and superfluidity in repulsive fermion systems58 733–761 (2015)
    67.85.−d, 74.20.−z, 74.20.Mn, 74.20.Rp, 74.25.Dw, 74.78.Fk, 81.05.ue (all)
  9. Superconductivity in iron-based compounds (Scientific session of the Physical Sciences Division of the Russian Academy of Sciences, 29 January 2014)57 807–832 (2014)
    01.10.Fv, 74.25.−q, 74.70.Xa (all)
  10. I.M. Eremin “Antiferromagnetism in iron-based superconductors: magnetic order in the model of delocalized electrons57 807–813 (2014)
    74.20.Mn, 74.25.−q, 74.70.Xa (all)
  11. M.M. Korshunov “Superconducting state in iron-based materials and spin-fluctuation pairing theory57 813–819 (2014)
    74.20.Rp, 74.25.−q, 74.62.Dh (all)
  12. T.E. Kuzmicheva, S.A. Kuzmichev et alAndreev spectroscopy of iron-based superconductors: temperature dependence of the order parameters and scaling of ⊿L, S with TC57 819–827 (2014)
    74.25.−q, 74.45.+c, 74.62.Dh, 74.70.Xa (all)
  13. Yu.F. Eltsev, K.S. Pervakov et alMagnetic and transport properties of single crystals of Fe-based superconductors of 122 family57 827–832 (2014)
    74.25.−q, 74.45.+c, 74.70.−b (all)
  14. N.B. Brandt “The best years of my life56 192–198 (2013)
    01.60.+q, 01.65.+g, 74.25.−q (all)
  15. The 100th anniversary of the birth of N E Alekseevskii (Scientific session of the Physical Sciences Division of the Russian Academy of Sciences, 23 May 2012)56 192–210 (2013)
    01.10.Fv, 01.60.+q, 01.65.+g, 07.55.Db, 71.18.+y, 72.20.My, 74.25.−q, 84.71.Ba (all)
  16. E.P. Krasnoperov “At the origins of applied superconductivity56 202–204 (2013)
    01.60.+q, 01.65.+g, 74.25.−q (all)
  17. V.M. Pudalov, O.E. Omel’yanovskii et alV L Ginzburg and the development of experimental work on high-temperature superconductivity at LPI: ’iron superconductors’54 648–653 (2011)
    74.25.−q, 74.45.+c, 74.70.−b (all)
  18. Celebrating the 65th anniversary of the Russian Federal Nuclear Center — All-Russian Research Institute of Experimental Physics (Scientific session of the Physical Sciences Division of the Russian Academy of Sciences, 6 October 2010)54 387–427 (2011)
    01.10.Fv, 01.65.+g, 05.70.Ce, 07.35.+k, 07.55.Db, 28.52.−s, 28.70.+y, 42.55.−f, 42.62.−b, 47.20.−k, 47.27.wj, 47.40.−x, 52.57.−z, 61.05.C−, 64.30.−t, 74.25.−q, 84.30.Ng, 84.70.+p, 85.70.−w (all)
  19. G.V. Boriskov, A.I. Bykov et alResearch in ultrahigh magnetic field physics54 421–427 (2011)
    07.55.Db, 64.30.−t, 74.25.−q (all)
  20. E.G. Maksimov “About Ginzburg — Landau, and a bit about others53 1185–1190 (2010)
    01.65.+g, 74.20.−z, 74.25.−q (all)
  21. M.V. Sadovskii “High-temperature superconductivity in iron-based layered compounds51 1201–1227 (2008)
    74.20.−z, 74.25.−q, 74.62.−c, 74.70.−b (all)
  22. A.L. Ivanovskii “New high-temperature superconductors based on rare-earth and transition metal oxyarsenides and related phases: synthesis, properties, and simulations51 1229–1260 (2008)
    74.10.+v, 74.20.−z, 74.25.−q, 74.70.Dd (all)
  23. Yu.A. Izyumov, E.Z. Kurmaev “FeAs systems: a new class of high-temperature superconductors51 1261–1286 (2008)
    74.20.−z, 74.25.−q, 74.62.−c, 74.70.−b (all)
  24. Yu.V. Kopaev, V.I. Belyavskii, V.V. Kapaev “With cuprate luggage to room-temperature superconductivity51 191–198 (2008)
    74.20.Mn, 74.72.−h (all)
  25. V.I. Belyavskii, Yu.V. Kopaev “Ginzburg-Landau equations for high-temperature superconductors50 540–545 (2007)
    01.10.Fv, 74.20.De, 74.20.Mn, 74.72.-b (all)
  26. I.N. Askerzade “Ginzburg-Landau theory: the case of two-band superconductors49 1003–1016 (2006)
    74.20.De, 74.25.−q, 74.70.Ad (all)
  27. V.I. Belyavskii, Yu.V. Kopaev “Superconductivity of repulsive particles49 441–467 (2006)
    74.20.−z, 74.20.Mn, 74.72.−h (all)
  28. V.I. Belyavskii, Yu.V. Kopaev “Generalizing considerations about the nature of high-temperature superconductivity (based on the proceedings of M2S-HTSC-VII)47 409–416 (2004)
    74.20.Mn, 74.72.−h (all)
  29. V.F. Khirnyi, A.A. Kozlovskii “Nonlinear effects and domain instability in oxide ceramics46 657–663 (2003)
    72.15.−v, 74.25.−q, 74.72.−h (all)
  30. O.V. Misochko “Electronic Raman scattering in high-temperature superconductors46 373–392 (2003)
    74.25.−q, 74.25.Gz, 74.72.−h (all)
  31. Yu.V. Kopaev “Errata to the paper by Yu V Kopaev ’High-temperature superconductivity models’ [Physics-Uspekhi, June 2002, 45 (6) 655-659]45 791–791 (2002)
    74.20.Mn, 74.20.Rp, 74.62.Dh (all)
  32. Yu.V. Kopaev “High-temperature superconductivity models45 655–659 (2002)
    74.20.Mn, 74.20.Rp, 74.62.Dh (all)
  33. M.V. Sadovskii “Pseudogap in high-temperature superconductors44 515–539 (2001)
    74.20.Mn, 74.72.−h, 74.25.−q, 74.25.Jb (all)
  34. V.L. Ginzburg “Superconductivity: the day before yesterday — yesterday — today — tomorrow43 573–583 (2000)
    74.20.−z, 74.25.−q, 74.72.−h, 74.90.+n (all)
  35. A.I. Golovashkin, A.P. Rusakov “Experimental studies of the thermal and electronic properties of Ba1-xKxBiO3 and other perovskite-like oxide HTSC systems43 184–187 (2000)
    74.25.−q, 74.72.−h (all)
  36. E.G. Maksimov, Yu.I. Shilov “Hydrogen at high pressure42 1121–1138 (1999)
    64.30.+t, 71.20.−b, 71.30.+h, 74.25.−q (all)
  37. A.F. Andreev “Superfluidity, superconductivity and magnetism in mesoscopics41 581–588 (1998)
    11.30.−j, 73.23.−b, 74.25.−q, 75.45.+j (all)
  38. A.A. Abrikosov “Resonant tunneling in high-Tc superconductors41 605–616 (1998)
    74.25.−q, 74.50.+r, 74.72.−h (all)
  39. V.M. Pudalov “The metal-insulator transition in a two-dimensional system at zero magnetic field41 211–214 (1998)
    71.30.+h, 74.20.Mn (all)
  40. V.F. Gantmakher “Superconductor-insulator transitions and insulators with localized pairs41 214–217 (1998)
    71.30.+h, 74.20.Mn (all)
  41. A. Gold “Superconductor-insulator transition in the disordered Bose condensate: a discussion of the mode-coupling approach41 217–220 (1998)
    71.30.+h, 74.20.Mn (all)
  42. A. Frydman, E.P. Price, R.C. Dynes “Mesoscopic phenomena in disordered superconductors41 220–223 (1998)
    71.30.+h, 74.20.Mn (all)
  43. A.N. Lavrov, V.F. Gantmakher “Low-temperature resistivity of underdoped cuprates41 223–226 (1998)
    71.30.+h, 74.20.Mn (all)
  44. A.D. Zaikin, D.S. Golubev et alQuantum fluctuations and dissipation in thin superconducting wires41 226–230 (1998)
    71.30.+h, 74.20.Mn (all)
  45. N.V. Anshukova, A.I. Golovashkin et alHTSCs with apical oxygen replaced by halogens40 843–847 (1997)
    74.20.Mn, 74.25.−q, 74.72.−h, 74.90.+n (all)
  46. A.A. Slutskin “’Frozen’ electronic phase and high-temperature superconductivity38 669–672 (1995)
    01.10.Fv, 73.20.Dx, 74.20.Mn, 74.72.−h (all)
  47. A.P. Protogenov “Anyon superconductivity in strongly-correlated spin systems35 (7) 535–571 (1992)
    74.20.Mn, 71.27.+a (all)
  48. A.F. Andreev, A.S. Borovik-Romanov et alNikolai Evgen’evich Alekseevskii (on his eightieth birthday)35 (6) 531–532 (1992)
    01.60.+q, 74.10.+v, 74.70.Ad, 74.25.−q (all)
  49. A.F. Andreev, Yu.A. Bychkov et alGerasim Matveevich Eliashberg (on his sixtieth birthday)33 (10) 874–875 (1990)
    01.60.+q, 74.25.Kc, 74.20.Mn (all)
  50. D.I. Khomskii “Advances in superconductivity33 (10) 879–879 (1990)
    01.30.Cc, 01.30.Vv, 74.25.−q, 84.71.Mn, 74.78.−w, 74.72.Jt (all)
  51. A.A. Abrikosov “Magnetic impurities in nonmagnetic metals12 168–181 (1969)
    75.30.Hx, 75.30.Mb, 72.10.Fk, 74.25.−q (all)
  52. L.V. Keldysh, E.V. Shpol’skii “Lenin prizes for 19669 641–641 (1967)
    01.10.Cr, 74.20.De, 74.70.Ad, 74.25.−q, 71.35.−y (all)
  53. M.I. Kaganov, I.F. Mikhaĭlov, E.I. Rashba “VIII All-Union conference on low temperature physics (Kiev, October 13-20, 1961)5 532–545 (1962)
    01.10.Fv, 71.35.−y, 67.55.−s, 74.25.−q, 72.20.My, 76.80.+y (all)
  54. R. Chentsov “Seventh All-Union conference on low temperature physics3 949–958 (1961)
    01.10.Fv, 67.40.Vs, 74.20.Mn, 74.25.Ld, 72.15.Gd, 71.18.+y (all)
  55. M.V. Sadovskii “Limits of Eliashberg theory and bounds for superconducting transition temperatur”, accepted
    71.10.Fd, 74.20.−z, 74.20.Mn (all)
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