Michal Pudlak
Department of Theoretical Physics, Institute of Experimental Physics,
Slovak Academy of Sciences,
Watsonova 47, 043 53 Kosice, Slovakia

Bogoliubov Laboratory of Theoretical Physics, Joint Institute for Nuclear Research,
141980, Dubna, Moscow region, Russia
E-mail : pudlak@saske.sk
Date of birth: 6 December 1958  
Marital status: married  

CURRENT TOPICS
PROFESSIONAL EXPERIENCE
RESEARCH AND ACADEMIC POSITIONS
PROJECTS
LIST OF SELECTED PUBLICATIONS

 
 
   
CURRENT TOPICS

biophysics: electron transfer in biological objects;
condensed matter theory: low energy spectra of carbon composition;
PROFESSIONAL EXPERIENCE

1996

PhD condensed matter physics, Faculty of Sciences,
Safarik University, Kosice, Slovakia;
Visiting scientist, Bogoliubov Laboratory of Theoretical Physics,
Joint Institute for Nuclear Research, Dubna, Russia

1987-1991

 PhD student at Moscow State University, Faculty of Biology,
Department of Biophysics

1983

 M.Sc. biophysics and chemical physics, Faculty of Mathematics and Physics,
Charles University Prague, Czechoslovakia (now Czech Republic)
RESEARCH AND ACADEMIC POSITIONS
2004-present
 
 teaching at the UPJS Kosice, Differential Geometry for Physicist
1999-present
senior research scientist at the Department of Theoretical Physics, Institute of Experimental Physics, Slovak Academy of Sciences, Kosice, Slovakia
1991-1999
 research scientist at the Biophysical Department of the Institute of Experimental Physics,
Slovak Academy of Sciences, Kosice, Slovakia
1986-1987
 research scientist at the Biophysical Department of the Institute of Experimental Physics,
Slovak Academy of Sciences, Kosice, Slovakia
1984-1986
 teaching at the Veterinarian University, Kosice, Slovakia
PROJECTS
  • VEGA 2/7043/12 Electron-Conformational Transition in Biosystems, Principal investigator
  • VEGA 2/3197/23 Electron Transfer in Biosystems, Principal investigator
LIST OF SELECTED PUBLICATIONS
  1. 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
  2. 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
  3. 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]
  4. J. Smotlacha, R. Pincak, Application of greens function approach to electronic structure of carbon nanocylinders, NANOSYSTEMS: PHYSICS, CHEMISTRY, MATHEMATICS (2013) 4 (4) 490 [pdf]
  5. R. Pincak, J. Smotlacha, Analogies in electronic properties of graphene wormhole and perturbed nanocylinder, Eur. Phys. J. B (2013) 86: 480 [pdf]
  6. M. Pudlak and R. Pincak, Edge states of graphene bilayer strip, Eur. Phys. J. B (2013) 86: 107 [pdf]
  7. R. Pincak, J. Smotlacha, M. Pudlak, Electronic properties of disclinated nanostructured cylinders, 2013, NanoMMTA, Vol. 2, 81-95 DOI: 10.2478/nsmmt-2013-0005
  8. R. Pincak and M. Pudlak, The electronic properties of double wall carbon nanotubes, 2012,
    J. of Phys.: Conf. Ser. 393 012028 [pdf]
  9. R. Pincak, J. Smotlacha and M. Pudlak, Electronic properties of perturbed cylinder, 2012,
    J. of Phys.: Conf. Ser. 393 012029 [pdf]
  10. 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]
  11. 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]
  12. 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]
  13. 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]
  14. 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]
  15. M. Pudlak and 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]
  16. 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]
  17. 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]
  18. M.Pudlak and R.Pincak, Electronic properties of double-layer carbon nanotubes,
    European Physical Journal B 67 (2009) 565.     [pdf]
  19. 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]
  20. 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]
  21. 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 (2007) 065201
    DOI: 10.1103/PhysRevA.75.065201 [preprint]
  22. 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]
  23. 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,
    DOI: 10.1103/PhysRevA.75.025201 [preprint]
  24. M. Pudlak, R. Pincak and V. A. Osipov, Low energy electronic states in spheroidal fullerenes, Physical Review B 74 (2006) 235435
    cond-mat/0602520, DOI: 10.1103/PhysRevB.74.235435 [preprint]
  25. M.Pudlak: Effect of the conformational transitions on electron transfer in biological
    systems    . Physica A 341, 444 (2004). [pdf]
  26. M.Pudlak,R.Pincak: Modeling charge transfer in the photosynthetic reaction center.
    Phys.Rev.E 68, 061901 (2003). [pdf]
  27. V.A.Osipov, E.A.Kochetov, M.Pudlak. Electronic structure of carbon
    nanoparticles    . JETP 123, N1, 161 (2003). [pdf]
  28. M.Pudlak. Primary charge separation in the bacterial reaction center:
    Validity of incoherent sequential model    . J.Chem.Phys. 118, 1876 (2003). [pdf]
  29. M.Pudlak.R.Pincak. The role of accessory bacteriochlorophylls
    in the primary charge transfer in the photosynthetic reaction centers    .
    Chem.Phys.Lett. 342, 587 (2001). [pdf]
  30. R.Pincak, M.Pudlak. Noise breaking the twofold symmetry of
    photosynthetic reaction centers: Electron transfer    .
    Phys.Rev.E 64, 031906 (2001). [pdf]
  31. M.Pudlak,V.A.Osipov. Disclination vortices in elastic media.
    Nonlinearity 13, 459 (2000). [pdf]
  32. M.Pudlak. Electron transfer driven by conformational variations.
    J.Chem.Phys. 108, 5621 (1998). [pdf]
  33. M.Pudlak. Effect of the molecular dynamics of exchanging groups on electron
    transport. Stochastic Lioville equation approach.
    Chem.Phys.Lett. 235, 126 (1995). [pdf]
  34. M.Pudlak, K.V.Shaitan. The influence of energy level fluctuation and acceptor
    local diffusion on electron transport in biological system    .
    J.Biological Physics 19, 39 (1993). [pdf]

Other:

International collaboration: JINR Dubna,Bogoliubov Laboratory of Theoretical Physics
Updated on 12 January 2015