{"id":4196,"date":"2020-06-02T09:51:03","date_gmt":"2020-06-02T07:51:03","guid":{"rendered":"http:\/\/websrv.saske.sk\/uef\/?page_id=4196"},"modified":"2021-10-27T11:43:46","modified_gmt":"2021-10-27T09:43:46","slug":"2020-2","status":"publish","type":"page","link":"https:\/\/websrv.saske.sk\/uef\/oddelenia-a-laboratoria\/oddelenie-teoretickej-fyziky\/publikacie-2\/2020-2\/","title":{"rendered":"2020"},"content":{"rendered":"
    \n
  1. H. \u010cEN\u010cARIKOV\u00c1<\/strong>, J. STRE\u010cKA, and A. GENDIAR, Influence of applied electric and magnetic fields on a thermally-induced reentrance of a coupled spin-electron model on a decorated square lattice, Physica E 115 (2020) 113717<\/strong><\/a> [<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>3.570<\/strong><\/span>\/2.361=1.512]\u00a0<\/strong>(8 pages).<\/li>\n
  2. H. \u010cEN\u010cARIKOV\u00c1<\/strong> and N. TOMA\u0160OVI\u010cOV\u00c1, Comparative Study of a Critical Behavior of a Coupled Spin-Electron Modelon a Doubly Decorated Square Lattice in the Canonical and Grand-Canonical Ensemble,\u00a0Acta Physica Polonica A 137 (2020) 607<\/strong>\u00a0<\/a>\u00a0[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>0.579<\/strong><\/span>\/1.807=0.320] <\/strong>(3 pages).<\/li>\n
  3. H. \u010cEN\u010cARIKOV\u00c1 <\/strong>and J. STRE\u010cKA, Unconventional strengthening of the bipartite entanglement of a mixed spin-(1\/2,1) Heisenberg dimer achieved through Zeeman splitting, Physical Review B 102 (2020) 184419<\/strong><\/a>\u00a0[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>3.575<\/strong><\/span>\/2.361=1.514]\u00a0<\/strong>(14 pages).<\/li>\n
  4. * P. FARKA\u0160OVSK\u00dd,<\/strong>\u00a0Enhancement of superconducting correlations by spin ordering in the spin-one-half Falicov-Kimball model with Hund and Hubbard coupling: Quantum Monte-Carlo study, European Physical Journal B 93 (2020) 217\u00a0<\/a>[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>1.347<\/strong><\/span>\/2.361=0.571]<\/strong>\u00a0<\/strong>(5 pages).<\/li>\n
  5. * P. FARKA\u0160OVSK\u00dd<\/strong>, DMRG study of exciton condensation in the extended Falicov-Kimball model, Condensed Matter Physics 23\u00a0(2020) 43709<\/strong><\/a>\u00a0[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>0.581<\/strong><\/span>\/2.361=0.246]<\/strong>\u00a0<\/strong>(12 pages).<\/li>\n
  6. P. FARKA\u0160OVSK\u00dd<\/strong> and L. REGECIOV\u00c1<\/strong>, Influence of Interplane Interactions on Formation of Magnetization Plateaus in Generalized 3D Ising Models with Magnetically Coupled Shastry-Sutherland Layers, Journal of Superconductivity and Novel Magnetism 33 (2020) 2219<\/strong><\/a>\u00a0[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>1.244<\/strong><\/span>\/2.361=0.527]\u00a0<\/strong>(7 pages).<\/li>\n
  7. L. REGECIOV\u00c1<\/strong> and P. FARKA\u0160OVSK\u00dd<\/strong>, Formation of magnetization plateaus in the 3D Ising model with the long-range RKKY interaction: application to rare-earth tetraborides, European Physical Journal B 93 (2020) 110<\/strong><\/a> [<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>1.347<\/strong><\/span>\/2.361=0.571]\u00a0<\/strong>(6 pages).<\/li>\n
  8. L. REGECIOV\u00c1<\/strong> and P. FARKA\u0160OVSK\u00dd<\/strong>, Influence of the Long-Range RKKY Interaction on a Formation of Magnetization Plateaus in the Generalised Ising Model on the Shastry-Sutherland Lattice, Acta Physica Polonica A 137 (2020) 625<\/strong><\/a>\u00a0[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>0.579<\/strong><\/span>\/1.807=0.320]\u00a0<\/strong>(3 pages).<\/li>\n
  9. M. OREND\u00c1\u010c, P. FARKA\u0160OVSK\u00dd<\/strong>, L. REGECIOV\u00c1<\/strong>, K. FLACHBART, S. GAB\u00c1NI, E. GA\u017dO, G. PRIST\u00c1\u0160, A. DUKHNENKO, N. SHITSEVALOVA and K. SIEMENSMEYER, Microscopic Description of Rotating Magnetocaloric Effect in Frustrated Antiferromagnetic System TmB4, Acta Physica Polonica A 137 (2020) 764<\/strong><\/a>\u00a0[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>0.579<\/strong><\/span>\/1.807=0.320]\u00a0<\/strong>(3 pages).<\/li>\n
  10. M. OREND\u00c1\u010c, P. FARKA\u0160OVSK\u00dd<\/strong>, L. REGECIOV\u00c1<\/strong>,\u00a0 S. GAB\u00c1NI, G. PRIST\u00c1\u0160,\u00a0 E. GA\u017dO, J. BA\u010cKAI, P.DIKO, A. DUKHNENKO,\u00a0N. SHITSEVALOVA and K. SIEMENSMEYER, and\u00a0K. FLACHBART,\u00a0Tuning the magnetocaloric effect in the Lu-doped frustrated Shastry-Sutherland system TmB4,\u00a0Physical Review B 102\u00a0 (2020)\u00a0<\/b>174422<\/strong><\/a>\u00a0[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>3.575<\/strong><\/span>\/2.361=1.514]\u00a0<\/strong>(7 pages).<\/li>\n
  11. P. FARKA\u0160OVSK\u00dd<\/strong> and L. REGECIOV\u00c1<\/strong>, Formation of Magnetization Plateaus in Rare Earth Tetraborides: Exact Diagonalization and Quantum Monte Carlo Studies, Journal of Superconductivity and Novel Magnetism 33 (2020) 3463<\/strong><\/a>\u00a0[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>1.244<\/strong><\/span>\/2.361=0.527]\u00a0<\/strong>(5 pages).<\/li>\n
  12. M. DAN\u010cO, M. HNATI\u010c<\/strong>, T. LU\u010cIVJANSKY, and L. MI\u017dI\u0160IN<\/strong>, Renormalization group study of superfluid phase transition: Effect of compressibility, PHYSICAL REVIEW E 102 (2020) 022118<\/strong><\/a>\u00a0\u00a0[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=2.296<\/strong>\/1.292=1.777]\u00a0<\/strong> (18 pages).<\/li>\n
  13. M. HNATI\u010c<\/strong>, G. A. KALAGOV, and M. Y. NALIMOV, On the first-order phase transition in SU(N) matrix models, NUCLEAR PHYSICS B 955 (2020) 115060<\/strong><\/a>\u00a0\u00a0[<\/strong>IF<\/strong>\/MedIF(2019)=2.817<\/strong>\/2.176=1.295]\u00a0<\/strong> (20 pages).<\/li>\n
  14. * E. JUR\u010cI\u0160INOV\u00c1\u00a0<\/strong>and M. JUR\u010cI\u0160IN<\/strong>,\u00a0Presence of the weak ferromagnetism in pure antiferromagnetic systems with octahedral structure: Effective field theory analysis, Europhysics Letters 132 (2020) 37004<\/strong><\/a>\u00a0[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>1.958<\/strong><\/span>\/1.807=1.084]\u00a0<\/strong>(5 pages).<\/li>\n
  15. E. JUR\u010cI\u0160INOV\u00c1\u00a0<\/strong>and M. JUR\u010cI\u0160IN<\/strong>, Critical temperatures and critical concentrations in diluted magnetic systems: General solution\u00a0of the Ising model in effective-field theory approach, Physica A 540 (2020) 123160<\/strong><\/a> [<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>2.924<\/strong><\/span>\/1.807=1.618]\u00a0<\/strong>(9 pages).<\/li>\n
  16. E. JUR\u010cI\u0160INOV\u00c1\u00a0<\/strong>and M. JUR\u010cI\u0160IN<\/strong>, Ground states, residual entropies, and specific heat capacity properties of frustrated Ising system on pyrochlore lattice in effective field theory cluster approximations, Physica A 554 (2020) 124671<\/strong><\/a> [<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>2.924<\/strong><\/span>\/1.807=1.618]\u00a0<\/strong>(13 pages).<\/li>\n
  17. E. JUR\u010cI\u0160INOV\u00c1\u00a0<\/strong>and M. JUR\u010cI\u0160IN<\/strong>, Evidence for weak ferromagnetism and metamagnetic phase transitions in frustrated antiferromagnetic systems with octahedral structure,\u00a0Journal of Magnetism and Magnetic Materials 513 (2020) 167085<\/strong>\u00a0<\/a>\u00a0[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>2.717<\/strong><\/span>\/2.361=1.151] <\/strong>(8 pages).<\/li>\n
  18. E. JUR\u010cI\u0160INOV\u00c1\u00a0<\/strong>and M. JUR\u010cI\u0160IN<\/strong>, Prediction of the existence of a spin-liquid-like phase in the antiferromagnetic J1-J2 spin-1\/2\u00a0system on the body-centered cubic lattice,\u00a0Physical Review B 101 (2020) 214443\u00a0<\/strong><\/a>[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>3.575<\/strong><\/span>\/2.361=1.514]\u00a0<\/strong>(10 pages). <\/strong><\/li>\n
  19. E. JUR\u010cI\u0160INOV\u00c1<\/strong>,\u00a0M. JUR\u010cI\u0160IN<\/strong>, and\u00a0 R. REMECK\u00dd<\/strong>, Anomalous Dimensions of Leading Composite\u00a0 Operators in the Kinematic MHD Turbulence: Two-Loop Renormalization Group Analysis, Phys. Part. Nucl. 51 (2020) 812 \u00a0<\/strong><\/a>[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>0.318<\/strong><\/span>\/2.176=0.146] <\/strong>(4 pages).<\/li>\n
  20. M. MENKYNA<\/strong>,\u00a0Influence of compressibility on scaling regimes of Kraichnan model with finite time correlations: two-loop RG analysis,\u00a0European Physical Journal B<\/strong>\u00a093 (2020) 71<\/strong><\/a>\u00a0[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>1.347<\/strong><\/span>\/2.361=0.571]\u00a0<\/strong>(15 pages).<\/li>\n
  21. M. KRELINA, J. NEMCHIK<\/strong>, and R. PASECHNIK, D-wave effects in diffractive electroproduction of heavy quarkonia from the photon-like V \u2013 Q(Q)over-bar transition, European Physical Journal C 80 (2020) 92<\/a>\u00a0<\/strong>[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=4.389<\/span><\/strong>\/2.176=2.017]\u00a0<\/strong>(12 pages).<\/li>\n
  22. M. KRELINA and J. NEMCHIK<\/strong>, Nuclear shadowing in DIS at electron-ion colliders, European Physical Journal Plus 135 (2020) 444\u00a0<\/a>\u00a0<\/strong>[<\/strong>IF<\/span><\/strong>\/MedIF(2019)=3.228<\/span><\/strong>\/1.807=1.786]\u00a0<\/strong>(26 pages).<\/li>\n
  23. *<\/strong> M. KRELINA and J. NEMCHIK<\/strong>, D-wave effects in heavy quarkonium production in ultraperipheral nuclear collisions, Physical Review D 102 (2020) 114033<\/strong><\/a>\u00a0[<\/strong>IF<\/span><\/strong>\/MedIF(2019)=4.833<\/span><\/strong>\/2.176=2.221]\u00a0<\/strong>(10 pages).<\/li>\n
  24. R. PIN\u010c\u00c1K<\/strong>, K. KANJAMAPORNKUL, and E. BARTO\u0160, A theoretical investigation on the predictability of genetic patterns, Chemical Physics 535 (2020) 110764<\/strong><\/a> [<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>1.771<\/strong><\/span>\/2.090=0.847]\u00a0<\/strong>(9 pages).<\/li>\n
  25. R. PIN\u010c\u00c1K<\/strong> and E. BARTO\u0160, Chemical evolution of protein folding in amino acids, Chemical Physics 537 (2020) 110856<\/strong> \u00a0<\/a>[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>1.771<\/strong><\/span>\/2.090=0.847]\u00a0<\/strong>(11 pages).<\/li>\n
  26. S. CAPOZZIELLO, R. PIN\u010c\u00c1K<\/strong>, and E. BARTO\u0160, Chern-Simons Current of Left and Right Chiral Superspace in Graphene Wormhole, Symmetry 12 (2020) 774<\/a>\u00a0<\/strong>[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>2.645<\/strong><\/span>\/1.866=1.417]\u00a0<\/strong>(25 pages).<\/li>\n
  27. S. CAPOZZIELLO, R. PIN\u010c\u00c1K<\/strong>, and E. BARTO\u0160, A Supersymmetry and Quantum Cryptosystem with Path Integral Approach in Biology, Symmetry 12 (2020) 12<\/a><\/strong>14<\/a>\u00a0<\/strong>[<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>2.645<\/strong><\/span>\/1.866=1.417]\u00a0<\/strong>(33\u00a0pages).<\/li>\n
  28. R. PIN\u010c\u00c1K<\/strong>, K. KANJAMAPORNKUL, and E. BARTO\u0160, Cohomology theory for biological time series, Mathematical Methods in the Applied Sciences 43 (2020) 552<\/strong><\/a>\u00a0 [<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>1.626<\/strong><\/span>\/1.172=1.387]\u00a0<\/strong>(28 pages).<\/li>\n
  29. K. KANJAMAPORNKUL, R. PIN\u010c\u00c1K<\/strong>, and E. BARTO\u0160, Cohomology theory for financial time series, Physica A 546 (2020) 122212<\/strong><\/a> [<\/strong>IF<\/strong><\/span>\/MedIF(2019)=<\/strong>2.924<\/strong><\/span>\/1.807=1.618]\u00a0<\/strong>(28 pages).<\/li>\n<\/ol>\n

    <\/h4>\n

    \"\"<\/h4>\n

     <\/p>\n

    Publik\u00e1cie v\u00a0registrovan\u00fdch\u00a0zahrani\u010dn\u00fdch karentovan\u00fdch neimpaktovan\u00fdch \u010dasopisoch a zborn\u00edkoch:<\/strong><\/h4>\n
      \n
    1. JUR\u010cI\u0160INOV\u00c1<\/strong>,\u00a0M. JUR\u010cI\u0160IN<\/strong>, and\u00a0 R. REMECK\u00dd<\/strong>, Anomalous Scaling in the Kinematic Magnetohydrodynamic Turbulence,\u00a0EPJ Web of Conferences 226 (2020) 02012<\/strong><\/a> (4 pages).<\/li>\n
    2. M. MENKYNA<\/strong>, Finite Time Correlations and Compressibility Effects in the Three-Dimensional Kraichnan Model, EPJ Web of Conferences 226 (2020)\u00a002016<\/strong><\/a> (4 pages).<\/li>\n<\/ol>\n

      <\/h4>\n

       <\/p>\n

      Publik\u00e1cie v zahrani\u010dn\u00fdch neimpaktovan\u00fdch \u010dasopisoch registrovan\u00fdch v datab\u00e1zach
      \nWeb of Science Core Collection alebo SCOPUS:<\/strong><\/h4>\n
        \n
      1. Z. KR\u00c1LOV\u00c1, Z. ORS\u00c1GOV\u00c1, M. KUPKOV\u00c1, M. HRUBOV\u010c\u00c1KOV\u00c1, A. ZELE\u0147\u00c1K, R. ORI\u0147AKOV\u00c1, TURO\u0147OV\u00c1 A. MOROVSK\u00c1, K. \u017d\u00c1KOV\u00c1, M. KUPKA<\/strong>, K. KOVA\u013d, and I. \u0160I\u0160OL\u00c1KOV\u00c1,
        \nMechanical and corrosion properties of iron-mangan materials sintered in the presence of plasma,         Koroze a ochrana materi\u00e1lu 64<\/strong><\/a> (2020) 1<\/strong><\/a>\u00a0\u00a0<\/strong>(10 pages).<\/li>\n
      2. M. KUPKOV\u00c1, M. KUPKA<\/strong>, R. ORI\u0147\u00c1KOV\u00c1, R. GOREJOV\u00c1, Kor\u00f3zne charakteristiky spekan\u00fdch heterog\u00e9nnych materi\u00e1lov pozost\u00e1vaj\u00facich zo \u017eeleza a jeho oxidov = Corrosion characteristics of sintered heterogeneous materials composed of iron and iron oxides, Koroze a ochrana materi\u00e1lu 64 (2020) 72<\/strong> <\/a>(7 pages).<\/li>\n
      3. M. KUPKOV\u00c1, M. KUPKA<\/strong>, R. ORI\u0147\u00c1KOV\u00c1, and R. GOREJOV\u00c1, Microstructure, stiffness and corrosion of bare and phosphated specimens made by sintering of structured iron-iron oxide spheres, Defect and Diffusion Forum 405 (2020) 411<\/strong><\/a> (6 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. JUR\u010cI\u0160INOV\u00c1<\/strong>,\u00a0M. JUR\u010cI\u0160IN<\/strong>, and\u00a0 R. REMECK\u00dd<\/strong>, Anisotropic MHD Turbulence Near Two Spatial Dimensions: General Field Theoretic Renormalization Group Analysis, Springer Proceedings in Complexity (2020) <\/strong>111-122.<\/li>\n
        2. M. KRELINA, J. NEMCHIK<\/strong>, R. PASECHNIK, and J. CEPILA, The onset of spin rotation effects in electroproduction of heavy quarkonia, Proceedings of Science 364 (EPS-HEP2019) 496<\/strong><\/a> (5 pages).<\/li>\n<\/ol>\n

           <\/p>\n

          Kapitoly v kni\u017en\u00fdch publik\u00e1ci\u00e1ch:<\/strong><\/p>\n

            \n
          1. R. PIN\u010c\u00c1K<\/strong> and E. BARTO\u0160, Application of Spin-Orbit Coupling in Exotic Graphene Structures and Biology, Chapter in „Solid State Physics – Metastable, Spintronics Materials and Mechanics of Deformable Bodies – Recent Progress (2020)“<\/strong><\/a>,\u00a0ISBN: 978-1-83881-165-5.<\/li>\n<\/ol>\n","protected":false},"excerpt":{"rendered":"

            H. \u010cEN\u010cARIKOV\u00c1, J. STRE\u010cKA, and A. GENDIAR, Influence of applied electric and magnetic fields on a thermally-induced reentrance of a coupled spin-electron model on a…<\/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\/4196"}],"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=4196"}],"version-history":[{"count":71,"href":"https:\/\/websrv.saske.sk\/uef\/wp-json\/wp\/v2\/pages\/4196\/revisions"}],"predecessor-version":[{"id":5697,"href":"https:\/\/websrv.saske.sk\/uef\/wp-json\/wp\/v2\/pages\/4196\/revisions\/5697"}],"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=4196"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}