{"id":2102,"date":"2019-03-13T13:10:55","date_gmt":"2019-03-13T12:10:55","guid":{"rendered":"http:\/\/websrv.saske.sk\/uef\/?page_id=2102"},"modified":"2020-02-04T14:47:59","modified_gmt":"2020-02-04T13:47:59","slug":"2019-2","status":"publish","type":"page","link":"https:\/\/websrv.saske.sk\/uef\/oddelenia-a-laboratoria\/oddelenie-teoretickej-fyziky\/publikacie-2\/2019-2\/","title":{"rendered":"2019"},"content":{"rendered":"

Publik\u00e1cie pracovn\u00edkov oddelenia za rok 2019<\/h2>\n
    \n
  1. H. \u010cEN\u010cARIKOV\u00c1<\/strong> and J. STRE\u010cKA, Conventional and rotating magnetoelectric effect of a half-filled\u00a0spin-electron model on a doubly decorated square lattice, Physics Letters A 383 (2019) 125957<\/strong><\/a>\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>2.087<\/span><\/strong>\/1.575=1.325]\u00a0<\/strong>(5 pages).<\/li>\n
  2. P. FARKA\u0160OVSK\u00dd<\/strong>,\u00a0The Influence of Long-Range Hopping on Ferromagnetism in the Hubbard Model on the Generalized Shastry-Sutherland Lattice,\u00a0Journal of Superconductivity and Novel Magnetism\u00a032 (2019)\u00a01007<\/strong><\/a>\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>1.13<\/span><\/strong>\/2.242=0.504]\u00a0<\/strong>(5 pages).<\/li>\n
  3. P. FARKA\u0160OVSK\u00dd<\/strong>, Pressure induced valence and metal-insulator transitions in the Falicov-Kimball model\u00a0with nonlocal hybridization, Solid State Communications 287 (2019)<\/strong>\u00a068<\/strong><\/a>\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>1.433<\/span><\/strong>\/2.242=0.639]\u00a0<\/strong>(4 pages).<\/li>\n
  4. P. FARKA\u0160OVSK\u00dd<\/strong> and \u013d. REGECIOV\u00c1<\/strong>,\u00a0Magnetization plateaus and phase diagrams of the extended Ising model on the Shastry-Sutherland lattice: effects of long-range interactions, The European Physical Journal B 92 (2019) 33<\/a>\u00a0<\/strong>[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>1.44<\/span><\/strong>\/2.242=0.642]\u00a0<\/strong>(6 pages).<\/li>\n
  5. P. FARKA\u0160OVSK\u00dd<\/strong>, The infuence of nonlocal interactions on valence\u00a0transitions and formation of excitonic bound states in the generalized Falicov Kimball model,\u00a0The European Physical Journal B 92 (2019) 141<\/a><\/b>\u00a0<\/b>[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>1.44<\/span><\/strong>\/2.242=0.642]\u00a0<\/strong><\/b>(5 pages).<\/li>\n
  6. L. REGECIOV\u00c1<\/strong>\u00a0and P. FARKA\u0160OVSK\u00dd<\/strong>, Magnetic phase diagram of the Ising model with the long-range RKKY interaction, The European Physical Journal B 92 (2019) 184<\/strong><\/a>\u00a0<\/b>[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>1.44<\/span><\/strong>\/2.242=0.642]<\/strong> (6 pages).<\/li>\n
  7. M. HNATI\u010c<\/strong>, J. HONKONEN, and T. LU\u010cIVJANSK\u00dd, Symmetry Breaking in Stochastic Dynamics and Turbulence, Symmetry MDPI 11(10) (2019) 1193<\/strong><\/a>\u00a0<\/b>[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>2.143<\/span><\/strong>\/1.622=1.321]\u00a0<\/strong>(52 pages).<\/li>\n
  8. \u0160. BIRN\u0160TEINOV\u00c1, M. HNATI\u010c<\/strong>, T. LU\u010cIVJANSK\u00dd, L. MI\u017dI\u0160IN, and V. \u0160KULT\u00c9TY, Passive advection in percolation process: Two-loop approximation, Theoretical and Mathematical Physics, 200 (2019)\u00a01335<\/strong><\/a>\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>0.901<\/span><\/strong>\/1.231=0.732]\u00a0<\/strong>(13 pages).<\/li>\n
  9. E. JUR\u010cI\u0160INOV\u00c1<\/strong> and M. JUR\u010cI\u0160IN<\/strong>, Applicability of effective field theory cluster approximations for investigation of geometrically frustrated magnetic systems: Antiferromagnetic model on kagome lattice, Physica A 514 (2019) 644<\/strong><\/a>\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>2.5<\/span><\/strong>\/1.575=1.587]\u00a0<\/strong>(14 pages).<\/li>\n
  10. A. BOB\u00c1K, E. JUR\u010cI\u0160INOV\u00c1<\/strong>,\u00a0M. JUR\u010cI\u0160IN<\/strong>, M. \u017dUKOVI\u010c, and T. BALCERZAK, An investigation of the\u00a0 transverse Ising antiferromagnet on the honeycomb lattice with frustration,\u00a0Physica A 518 (2019) 13<\/strong><\/a>\u00a0\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>2.5<\/span><\/strong>\/1.575=1.587]\u00a0<\/strong>(9 pages).<\/li>\n
  11. E. JUR\u010cI\u0160INOV\u00c1<\/strong> and M. JUR\u010cI\u0160IN<\/strong>, Relevance of recursive lattice approximations for description of frustrated magnetic systems: Star kagome-like recursive lattice approximation, Physica A 521 (2019) 330<\/strong><\/a>\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>2.5<\/span><\/strong>\/1.575=1.587]\u00a0<\/strong>(22 pages).<\/li>\n
  12. E. JUR\u010cI\u0160INOV\u00c1<\/strong> and M. JUR\u010cI\u0160IN<\/strong>, A general view on the critical behavior in the effective field theory approximation of the Ising model with arbitrary coordination number, Physica A 525 (2019) 1399<\/b><\/a>\u00a0\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>2.5<\/span><\/strong>\/1.575=1.587]\u00a0<\/strong>(6 pages).<\/li>\n
  13. E. JUR\u010cI\u0160INOV\u00c1<\/strong> and M. JUR\u010cI\u0160IN<\/strong>,\u00a0Consequences of residual-entropy hierarchy violation for behavior of the specific heat capacity in frustrated magnetic systems: An exact theoretical analysis, Physical Review E 99 (2019) 042151<\/strong><\/a>\u00a0\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>2.353<\/span><\/strong>\/1.231=1.911]\u00a0<\/strong>(16 pages).<\/li>\n
  14. E. JUR\u010cI\u0160INOV\u00c1<\/strong> and M. JUR\u010cI\u0160IN<\/strong>,\u00a0Entropy properties of antiferromagnetic model on kagome lattice: Effective-field theory approach, Physica A 535 (2019) 122430<\/strong><\/a>\u00a0\u00a0\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>2.5<\/span><\/strong>\/1.575=1.587]\u00a0<\/strong>(10 pages).<\/li>\n
  15. E. JUR\u010cI\u0160INOV\u00c1<\/strong> and M. JUR\u010cI\u0160IN<\/strong>,\u00a0Influence of dilution on magnetization properties of geometrically frustrated magnetic systems: Effective-field theory cluster approximations on kagome lattice, Physics Letters A 383 (2019) 125972<\/strong><\/a>\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>2.087<\/span><\/strong>\/1.575=1.325]\u00a0<\/strong>(9 pages).<\/li>\n
  16. E. JUR\u010cI\u0160INOV\u00c1<\/strong>, M. JUR\u010cI\u0160IN<\/strong>, and R. REMECK\u00dd<\/strong>,\u00a0Turbulent Prandtl Number in Two Spatial Dimensions: Two-loop Renormalization Group Analysis,\u00a0 Theor. Math. Phys. 200 (2019) 1139<\/strong><\/a>\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>0.901<\/span><\/strong>\/1.231=0.732]\u00a0<\/strong>(8 pages).<\/li>\n
  17. E. JUR\u010cI\u0160INOV\u00c1<\/strong>, M. JUR\u010cI\u0160IN<\/strong>, and M. MENKYNA<\/strong>,\u00a0Influence of Finite-Time Velocity Correlations on Scaling Properties of Magnetic Field in the Kazantsev-Kraichnan Model: Two-Loop Renormalization Group Analysis,
    \n    Theor. Math. Phys. 200 (2019) 1126<\/strong><\/a>\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>0.901<\/span><\/strong>\/1.231=0.732]\u00a0<\/strong>(13 pages).<\/li>\n
  18. M. \u010cLOVE\u010cKO, E. GA\u017dO, M. KUPKA<\/strong>, and P. SKYBA, Magnonic Analog of Black- and White-Hole Horizons in Superfluid 3He-B, Physical Review Letters 123 (2019) 161302<\/strong><\/a>\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>9.227<\/span><\/strong>\/1.575=5.858]\u00a0<\/strong>(5 pages).<\/li>\n
  19. J. \u010cEPILA, J. NEM\u010c\u00cdK<\/strong>, M. KRELINA, and R. PASECHNIK, Theoretical uncertainties in exclusive electroproduction of S-wave heavy quarkonia, European Physical Journal C 79 (2019) 495\u00a0<\/strong><\/a>[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>4.843<\/span><\/strong>\/2.165=2.237]\u00a0<\/strong>(29 pages).<\/li>\n
  20. A. SEPEHRI, R. PIN\u010c\u00c1K<\/strong>, and T. GHAFFARY, Information loss in black hole due to transition point, International Journal of Geometric Methods in Modern Physics 16 (2019) 1950026<\/a><\/strong>\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>1.022<\/span><\/strong>\/1.231=0.83]\u00a0<\/strong>(7 pages).<\/li>\n
  21. R. PIN\u010c\u00c1K<\/strong>, K. KANJAMAPORNKUL, and E. BARTO\u0160, Forecasting Laurent Polynomial in the Chern\u2013Simons Current of V3 Loop Time Series, Annalen der Physik 531 (2019) 1800375<\/strong>\u00a0<\/a>\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>3.276<\/span><\/strong>\/1.575=2.08]\u00a0<\/strong>(23 pages).<\/li>\n
  22. R. PIN\u010c\u00c1K <\/strong>and\u00a0K. KANJAMAPORNKUL,\u00a0GARCH in spinor field,\u00a0International Journal of Geometric Methods in Modern Physics 16 (2019) 1950099<\/strong><\/a>\u00a0[<\/strong>IF<\/strong>\/MedIF(2018)=<\/strong>1.022<\/span><\/strong>\/1.231=0.83]\u00a0<\/strong>(48 pages).<\/li>\n<\/ol>\n

    \"\"<\/h4>\n

    Publik\u00e1cie v\u00a0<\/strong>registrovan\u00fdch\u00a0<\/strong>zahrani\u010dn\u00fdch karentovan\u00fdch neimpaktovan\u00fdch \u010dasopisoc<\/strong>h a zborn\u00edkoch:<\/strong><\/h4>\n
      \n
    1. M. HNATI\u010c<\/strong>, G. KALAGOV, T. LU\u010cIVJANSK\u00dd, and P. ZALOM, Mirror symmetry breaking in toy models of developed turbulence, J. Phys.: Conference Series 1194 (2019) 012044<\/a>\u00a0 <\/strong>(9 pages).<\/li>\n
    2. B.Z. KOPELIOVICH, J. NEM\u010c\u00cdK<\/strong>, I.K. POTASHNIKOVA, and I.SCHMIDT, Novel mechanism for suppression of heavy flavored mesons in heavy ion collisions, Journal of Physics: Conference Series 1137 (2019) 012047<\/strong><\/a> (5 pages).<\/li>\n
    3. J. NEM\u010c\u00cdK<\/strong>, B.Z. KOPELIOVICH, I.K. POTASHNIKOVA, and I. SCHMIDT, Universal suppression of high-p(T) hadrons in heavy-ion collisions, Acta Physica Polonica B – Proceedings Supplement 12 (2019) 991<\/strong><\/a> (8 pages).<\/li>\n<\/ol>\n

      <\/h4>\n

       <\/p>\n

      Publik\u00e1cie v\u00a0registrovan\u00fdch\u00a0zahrani\u010dn\u00fdch nekarentovan\u00fdch neimpaktovan\u00fdch \u010dasopisoch a zborn\u00edkoch:<\/strong><\/h4>\n
        \n
      1. \u0160. BIRN\u0160TEINOV\u00c1, M. HNATI\u010c<\/strong>, T. LU\u010cIVJANSK\u00dd, and L. MI\u017dI\u0160IN, Percolation process in the presence of velocity fluctuations: two-loop approximation, Springer Proceedings in Complexity (2019) 27-36<\/strong>.<\/li>\n
      2. M. HNATI\u010c<\/strong>, G. KALAGOV, T. LU\u010cIVJANSK\u00dd, and P. ZALOM, Large scale behavior of generalized stochastic magnetohydrodynamic turbulence with mirror symmetry breaking, Springer Proceedings in Complexity (2019) 95-111<\/strong>.<\/li>\n
      3. N. M. GULITSKIY, M. HNATI\u010c<\/strong>, T. LU\u010cIVJANSK\u00dd, L. MI\u017dI\u0160IN, and V. \u0160KULT\u00c9TY, Stochastic navier-stokes equation for a compressible fluid: two-loop approximation, Springer Proceedings in Complexity (2019) 175-187<\/strong>.<\/li>\n
      4. L. Ts. ADZHEMYAN, M. HNATI\u010c,<\/strong> M. V. KOMPANIETS, T. LU\u010cIVJANSK\u00dd, and L. MI\u017dI\u0160IN, Renormalization group approach of directed percolation: three-loop approximation, Springer Proceedings in Complexity (2019) 195-204<\/strong>.<\/li>\n<\/ol>\n

        <\/h4>\n

         <\/p>\n

        Publik\u00e1cie v dom\u00e1cich\u00a0nekarentovan\u00fdch neimpaktovan\u00fdch \u010dasopisoch a zborn\u00edkoch:<\/strong><\/h4>\n
          \n
        1. \u0160. BIRN\u0160TEINOV\u00c1, M. HNATI\u010c<\/strong>, T. LU\u010cIVJANSK\u00dd, L. MI\u017dI\u0160IN, and V. \u0160KULT\u00c9TY, Turbulent advection of directed percolation process: the effect of compressibility, Proceedings of „The 20th Small Triangle Meeting on Theoretical Physics“, October 7-10, 2018, Pt\u00edcie, Slovakia; IEP SAS Ko\u0161ice, 2019, s. 9\u201314, ISBN 978-80-8143-233-0<\/strong><\/li>\n
        2. M. HNATI\u010c<\/strong> and G. KALAGOV, Fluctuation induced first order phase transition in an SU (N) field model, Proceedings of „The 20th Small Triangle Meeting on Theoretical Physics“, October 7-10, 2018, Pt\u00edcie, Slovakia; IEP SAS Ko\u0161ice, 2019, s. 45\u201356, ISBN 978- 80-8143-233-0<\/strong><\/li>\n
        3. M. HNATI\u010c<\/strong>, T. LU\u010cIVJANSK\u00dd, and L. MI\u017dI\u0160IN, Tricritical directed percolation: Field theoretic formulation, Proceedings of „The 20th Small Triangle Meeting on Theoretical Physics“, October 7-10, 2018, Pt\u00edcie, Slovakia; IEP SAS Ko\u0161ice, 2019, s. 57\u201364, ISBN 978-80-8143-233-0<\/strong><\/li>\n<\/ol>\n

           <\/p>\n

          Odborn\u00e9 publik\u00e1cie vydan\u00e9 na \u00dastave experiment\u00e1lnej fyziky SAV:<\/strong><\/p>\n

            \n
          1. H. \u010cEN\u010cARIKOV\u00c1,\u00a0<\/strong>Po\u010d\u00edta\u010dov\u00e1 Fyzika a Modelovanie, <\/strong>\u00daEF SAV (2019), ISBN: 978-80-89656-24-0<\/strong><\/li>\n<\/ol>\n","protected":false},"excerpt":{"rendered":"

            Publik\u00e1cie pracovn\u00edkov oddelenia za rok 2019 H. \u010cEN\u010cARIKOV\u00c1 and J. STRE\u010cKA, Conventional and rotating magnetoelectric effect of a half-filled\u00a0spin-electron model on a doubly decorated square…<\/p>\n","protected":false},"author":10,"featured_media":0,"parent":883,"menu_order":50,"comment_status":"closed","ping_status":"closed","template":"","meta":{"footnotes":""},"_links":{"self":[{"href":"https:\/\/websrv.saske.sk\/uef\/wp-json\/wp\/v2\/pages\/2102"}],"collection":[{"href":"https:\/\/websrv.saske.sk\/uef\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/websrv.saske.sk\/uef\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/websrv.saske.sk\/uef\/wp-json\/wp\/v2\/users\/10"}],"replies":[{"embeddable":true,"href":"https:\/\/websrv.saske.sk\/uef\/wp-json\/wp\/v2\/comments?post=2102"}],"version-history":[{"count":68,"href":"https:\/\/websrv.saske.sk\/uef\/wp-json\/wp\/v2\/pages\/2102\/revisions"}],"predecessor-version":[{"id":3851,"href":"https:\/\/websrv.saske.sk\/uef\/wp-json\/wp\/v2\/pages\/2102\/revisions\/3851"}],"up":[{"embeddable":true,"href":"https:\/\/websrv.saske.sk\/uef\/wp-json\/wp\/v2\/pages\/883"}],"wp:attachment":[{"href":"https:\/\/websrv.saske.sk\/uef\/wp-json\/wp\/v2\/media?parent=2102"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}