Publications (from 2006 to present)
  1. V.L. Katkov, V.A. Osipov, Tunneling-based graphene electronics: Methods and examples, Journal of Vacuum Science & Technology B, Nanotechnology and Microelectronics: Materials, Processing, Measurement, and Phenomena 35 (5), 050801 (2017)
    DOI: https://doi.org/10.1116/1.4995380
  2. A.A. Glebov, V.L. Katkov, V.A. Osipov, Effect of edge vacancies on performance of planar graphene tunnel field-effect transistor, EPL (Europhysics Letters) 118 (2), 27003 (2017) DOI: 10.1209/0295-5075/118/27003
  3. D. V. Kolesnikov, O. G. Sadykova, and V. A. Osipov Enhancement of thermoelectric figure of merit in zigzag graphene nanoribbons with periodic edge vacancies Int. J. Mod. Phys. B 31, 1750124 (2017) DOI: https://doi.org/10.1142/S0217979217501247
  4. A.A. Glebov, V.L. Katkov, V.A. Osipov, Effect of edge vacancies on localized states in a semi-infinite zigzag graphene sheet, JETP letters 104 (12), 842-846 (2016) DOI: https://doi.org/10.1134/S0021364016240024
  5. S. Sahling, G. Remenyi, J.E. Lorenzo, P. Monceau, V.L. Katkov, V.A. Osipov, Relaxation time spectrum of low-energy excitations in one-and two-dimensional materials with charge or spin density waves, Physical Review B 94 (14), 144107 (2016) DOI: https://doi.org/10.1103/PhysRevB.94.144107
  6. D.V.Kolesnikov, D.A.Lobanov, V.A.Osipov, The effect of electron–phonon interaction on the thermoelectric properties of defect zigzag nanoribbons Solid State Communications 248 (2016), 83-87 http://www.sciencedirect.com/science/article/pii/S0038109816302538
  7. J. Smotlacha, R. Pincak, Electronic Properties of Carbon Nanostructures. Chapter in book: "2D Materials", ISBN 978-953-51-4813-5, Intech (2016)
  8. R. Pincak, J. Smotlacha, Green Function Approach to the Calculation of the Local Density of States in the Graphitic Nanocone. Conference on Mathematical Modeling and Computational Physics (MMCP) Location: Acad Congress Ctr, Stara Lesna, Slovakia Date: Jul 13-17, 2015. In EPJ Web of Conferences, vol. 108, 02043 (2016)
  9. R. Pincak, J. Smotlacha, V.A. Osipov, Electronic states of zigzag graphene nanoribbons with edges re- constructed with topological defects, Physica B, 475, Pages 61-65 (2015). doi:10.1016/j.physb.2015.06.025
  10. R. Pincak, J. Smotlacha The chiral massive fermions in the graphitic wormhole, Quantum Matter, 4, pp. 1-11 (2015) [pdf]
  11. R. Pincak, J. Smotlacha, M. Pudlak Spin-orbit interaction in the graphitic nanocone, Eur. Phys. J. B 88:17 (2015) DOI: 10.1140/epjb/e2014-50413-9
  12. O.G. Isaeva, V. L. Katkov, V. A. Osipov, DNA sequencing through graphene nanogap: a model of sequential electron transport, The European Physical Journal B 87, 272 (2014) DOI: 10.1140/epjb/e2014-50400-2
  13. S. Sahling, M. Kolac, V. L. Katkov, V. A. Osipov, Anomalous Tunneling Systems in Amorphous Organic Materials, Journal of Low Temperature Physics V. 176, 1-2, pp 64-81 (2014) DOI: 10.1007/s10909-014-1162-0
  14. V.L. Katkov and V.A. Osipov, Planar graphene tunnel field-effect transistor, Appl. Phys. Lett. 104, 053102 (2014) DOI: http://dx.doi.org/10.1063/1.4863820 [preprint]
  15. R. Pincak, J. Smotlacha, M. Pudlak Calculation of the electronic structure near the tip of a graphitic nano cone, Physica B 441, pp. 58-61 (2014) doi:10.1016/j.physb.2014.02.012
  16. M. Pudlak and R. Pincak, Effect of the magnetic field on the edge states of zig-zag single wall carbon nanotubes, Physics Letters A (2013) 377 2384 [pdf]
  17. R. Pincak, J. Smotlacha, Analogies in electronic properties of graphene wormhole and perturbed nanocylinder, Eur. Phys. J. B (2013) 86: 480 [pdf]
  18. R. Pincak, J. Smotlacha, M. Pudlak, Electronic properties of disclinated nanostructured cylinders, 2013, NanoMMTA, Vol. 2, 81-95 DOI: 10.2478/nsmmt-2013-0005
  19. D. V. Kolesnikov and V. A. Osipov, Low-temperature thermal conductivity in polycrystalline graphene, Europhysics letters 100, 26004 (2012) [preprint]
  20. R. Pincak and M. Pudlak, The electronic properties of double wall carbon nanotubes, 2012, J. of Phys.: Conf. Ser. 393 012028 [pdf]
  21. R. Pincak, J. Smotlacha and M. Pudlak, Electronic properties of perturbed cylinder, 2012, J. of Phys.: Conf. Ser. 393 012029 [pdf]
  22. J.Smotlacha, R. Pincak, M. Pudlak, Electronic structure of disordered graphene with Green's function approach, Physics Letters A 376, Issue 45 (2012) 3256 [pdf]
  23. R.Pincak, M.Pudlak, J.Smotlacha, Electronic properties of single and double wall carbon nanotubes Carbon Nanotubes:Synthesis, Properties and Applications (NOVA Science Publisher, NY, 2012), ISBN: 978-1-62081-914-2 [pdf]
  24. J. Smotlacha, R. Pincak, M. Pudlak, Electronic Structure of Disclinated Graphene in an Uniform Magnetic Field, Eur.Phys.J. B 84,255-264 (2011) [pdf]
  25. M.Pudlak, K.N. Pichugin, R.G. Nazmitdinov and R. Pincak, Quantum nonequilibrium approach for fast electron transport in open systems: Photosynthetic reaction centers, Physical Review E 84, 051912 (2011) [pdf]
  26. M. Pudlak, R. Pincak, Influence of the electric field on the electron transport in photosynthetic reaction centers, Eur. Phys. J. E 34 (2011) 22 [pdf]
  27. M. Pudlak, R. Pincak, The electronic spectra of double-wall zig-zag carbon nanotube affected by the magnetic field, 2010, J. Phys.: Conf. Ser. 248 012008 [pdf]
  28. V.L. Katkov and V.A. Osipov, Energy distributions of field emitted electrons from few-layer graphene sheets with AB and ABC stacking, Physics of Particles and Nuclei, 41(7), 1027-1030 DOI: 10.1134/S1063779610070105
  29. D.V. Kolesnikov and V.A. Osipov. Conductance through the disclination dipole defect in metallic carbon nanotubes. J. Phys.: Conf. Ser. 248 012009 (2010) doi: 10.1088/1742-6596/248/1/012009
  30. S. Sahling, S. Abens, V. L. Katkov, and V. A. Osipov, Anomalous isotopic effect of tunneling states in NbTi-H/D. Phys. Rev. B, 82(17) (2010)
    DOI: 10.1103/PhysRevB.82.174204
  31. E.A. Kochetov, V.A. Osipov and R. Pincak, Electronic properties of disclinated flexible membrane beyond the inextensional limit: application to graphene, J. Phys.: Condens. Matter 22 (2010) 395502 [pdf]
  32. M.Pudlak and R.Pincak, Electronic pathway in reaction centers from Rhodobacter sphaeroides and Chloroflexus aurantiacus,
    Journal of Biological Physics, 36 (2010), 273-289. [pdf]
  33. V.L. Katkov and V.A. Osipov, Influence of tip geometry on the field emission law from axisymmetric and wall-like emitters. EPL, 89 (2010) 17002
  34. V.L. Katkov and V.A. Osipov,
    Energy distributions of field emitted electrons from carbon nanosheets: manifestation of the quantum size effect.
    JETP Letters, 90(4) (2009) 304 [preprint]
  35. M.Pudlak and R.Pincak,
    Energy gap between highest occupied molecular orbital and lowest unoccupied molecular orbital in multiwalled fullerenes.
    Physical Review A 79 (2009) 033202 [pdf]
  36. M.Pudlak and R.Pincak,
    Electronic properties of double-layer carbon nanotubes,
    European Physical Journal B 67 (2009) 565.
    [pdf]
  37. O.G. Isaeva and V.A. Osipov,
    Different strategies for cancer treatment: mathematical modeling
    Computational and Mathematical Methods in Medicine. 10(4) (2009) 253-272 [preprint]
  38. O.G. Isaeva and V.A. Osipov,
    Modeling of interleukin-2 mediated anti-tumor immune response immunocorrective effect of centimeter electromagnetic waves
    Computational and Mathematical Methods in Medicine 10(3) (2009) 185-201 [preprint]
  39. M. Pudlak, R. Pincak and V.A.Osipov,
    How the spheroidal deformation changes the spectra of fullerenes,
    Journal of Physics, Conf. Ser. 129 (2008) 012009 [pdf]
  40. M. Pudlak, R. Pincak and V.A.Osipov,
    Electronic structures of double-layer zig-zag carbon nanotubes,
    Journal of Physics, Conf. Ser. 129 (2008) 012011[pdf]
  41. D.V. Kolesnikov and V.A. Osipov,
    Electronic structure of negatively curved graphene,
    JETP Letters, 87(8) (2008) [preprint]
  42. V.L. Katkov and V.A. Osipov,
    Effect of band structure on field emission of crystalline graphite,
    Journal of Physics: Condensed Matter, 20 035204 (6pp) (2008) [preprint]
  43. M. Pudlak, R. Pincak, V. A. Osipov,
    Effect of symmetry on the electronic structure of spheroidal fullerenes in a weak uniform magnetic field,
    Physical Review A 75, 065201 (2007) [preprint]
  44. D.V.Kolesnikov and V.A.Osipov,
    Geometry-induced smoothing of van Hove singularities in capped carbon nanotubes,
    EPL 78 (2007) 47002 [preprint]
  45. R. Pincak, M. Pudlak, Chapter in book Progress in Fullerene Research, with title
    Electronic structure of spheroidal fullerenes,
    ed. F. Columbus, Nova Science Publishers, New York, 2007, ISBN: 1-60021-841-5 [pdf]
  46. M. Pudlak, R. Pincak and V.A. Osipov,
    Electronic structure of spheroidal fullerenes in a weak uniform magnetic field: a continuum field-theory model,
    Physical Review A, 75 (2007) 025201 [preprint]
  47. M. Pudlak, R. Pincak and V. A. Osipov,
    Low energy electronic states in spheroidal fullerenes,
    Physical Review B 74 (2006) 235435 [preprint]
  48. V.A. Osipov,
    Topological Defects in Carbon Nanocrystals,
    book chapter in: Topology in Condensed Matter (ed. M.I. Monastyrsky, Springer series in Solid State Science, Springer-Verlag, Berlin Heidelberg 2006), pp. 93--116 [pdf]
  49. D. V. Kolesnikov and V.A. Osipov,
    The continuum gauge field-theory model for low-energy electronic states of icosahedral fullerenes,
    European Physical Journal B 49, 465 (2006) [pdf]
   
 
Updated on November, 2 2017