Dr. Sergey Maksimenko
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Dr. Sergey Maksimenko

Research Director
Belarusian State University, Belarus

Highest Degree
D.Sc. in Physics from Belarus Academy of Science, Belarus

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Biography

Dr. Maksimenko Sergey Afanasievich is currently working as Professor and Director at Institute for Nuclear Problems, Belarus State University, Minsk, Belarus. He has completed his PhD in Physics from same University. He also served as Visiting Scientist at Institute fur Festkorperphysik, Technische Universitat Berlin, Berlin, Germany, and Max-Born Institut fur Nichtlineare Optik und Kurzzeitspektroskopie, Berlin, Germany, Eindhoven University of Technology, The Netherlands, and Frascati National Laboratory, National Institute of Nuclear Physics, Frascati, Italy, and Engineer-Researcher at Institute of Heat- and Mass Transfer, Belarus Ac. of Sci., Minsk, Belarus. He also delivered 40 invited talks at international conferences. He is guest editor for 3 issues of SPIE Proceedings, and for 2 special sections at the Journal of Nanophotonics. He has published 16 books and edited books, and 87 research articles in journals contributed as author/co-author.

Area of Interest:

Physical Science Engineering
100%
Electromagnetics
62%
Carbon Nanotubes
90%
Graphene
75%
Materials Science
55%

Research Publications in Numbers

Books
0
Chapters
0
Articles
226
Abstracts
0

Selected Publications

  1. Lobiak, E.V., D.S. Bychanok, E.V. Shlyakhova, P.P Kuzhir, S.A. Maksimenko, L.G. Bulusheva and A.V. Okotrub, 2016. One-step preparation of multiwall carbon nanotube/silicon hybrids for solar energy conversion. J. Nanophotonics, 10: 12507-12507.
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  2. Merijs-Meri, R., J. Zicans, T. Ivanova, J. Bitenieks and A. Paddubskaya et al., 2015. Carbon nanotubes and carbon onions for modification of styrene-acrylate copolymer nanocomposites. Polym. Composites, 36: 1048-1054.
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  3. Lobko, A., E. Golubeva, P. Kuzhir, S. Maksimenko and A. Paddubskaya et al., 2015. Nanodiamond targets for accelerator X-ray experiments. Nucl. Instrum. Methods Phys. Res., Sect. B, 355: 261-263.
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  4. Kotsilkova, R., E. Ivanov, D. Bychanok, A. Paddubskaya and M. Demidenko et al., 2015. Effects of sonochemical modification of carbon nanotubes on electrical and electromagnetic shielding properties of epoxy composites. Composites Sci. Technol., 106: 85-92.
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  5. Bellucci, S., S. Bistarelli, A. Cataldo, F. Micciulla and I. Kranauskaite et al., 2015. Broadband dielectric spectroscopy of composites filled with various carbon materials. IEEE Trans. Microwave Theory Tech., 63: 2024-2031.
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  6. Baryshevsky, V., N. Belous, A. Gurinovich, E. Gurnevich and P. Kuzhir et al., 2015. Study of nanometric thin pyrolytic carbon films for explosive electron emission cathode in high-voltage planar diode. Thin Solid Films, 581: 107-111.
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  7. Voronovich, S., A. Paddubskaya, K. Batrakov, P. Kuzhir, S. Maksimenko, T. Kaplas and Y. Svirko, 2014. Electromagnetic properties of graphene-like films in ka-band. Appl. Sci., 4: 255-264.
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  8. Plyushch, A., D. Bychanok, P. Kuzhir, S. Maksimenko and K. Lapko et al., 2014. Heat-resistant unfired phosphate ceramics with carbon nanotubes for electromagnetic application. Phys. status solidi A, 211: 2580-2585.
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  9. Macutkevic, J., A. Paddubskaya, P. Kuzhir, J. Banys and S. Maksimenko et al., 2014. Dielectric properties of polymer composites with carbon nanotubes of different diameters. J. nanosci. Nanotechnol., 14: 5430-5434.
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  10. Kranauskaite, I., J. Macutkevic, P. Kuzhir, N. Volynets and A. Paddubskaya et al., 2014. Dielectric properties of graphite-based epoxy composites. Phys. status solidi A, 211: 1623-1633.
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  11. Batrakov, K., P. Kuzhir, S. Maksimenko, A. Paddubskaya and A. Voronovich et al., 2014. Flexible transparent graphene/polymer multilayers for efficient electromagnetic field absorption. Sci. rep., .
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  12. Yerchak, Y., G.Y. Slepyan, S.A. Maksimenko, A. Hoffmann and F. Bass, 2013. Array of tunneling-coupled quantum dots as a terahertz range quantum nanoantenna. J. Nanophotonics, 7: 73085-73085.
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  13. Seliuta, D., L. Subacius, I. Kasalynas, M. Shuba and A. Paddubskaya et al., 2013. Electrical conductivity of single-wall carbon nanotube films in strong electric field. J. Appl. Phys., 113: 183719-183719.
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  14. Maffucci, A., S.A. Maksimenko, G. Miano and G.Y. Slepyan, 2013. Carbon Nanotubes: from electrodynamics to signal propagation models. In: Graphene, Carbon Nanotubes, and Nanostructures: Techniques and Applications. Morris J.E. and K. Iniewski, (Ed.). Taylor & Francis, CRC Press, New York, pp:1- 24.
  15. Macutkevic, J., P.P Kuzhir, A.G. Paddubskaya, J. Banys and S.A. Maksimenko et al., 2013. Broadband dielectric/electric properties of epoxy thin films filled with multiwalled carbon nanotubes. J. Nanophotonics, 7: 73593-73593.
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  16. Macutkevic, J., P. Kuzhir, A. Paddubskaya, S. Maksimenko and J. Banys et al., 2013. Epoxy resin/carbon black composites below the percolation threshold. J. nanosci. Nanotechnol., 13: 5434-5439.
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  17. Macutkevic, J., P. Kuzhir, A. Paddubskaya, S. Maksimenko and J. Banys et al., 2013. Electrical transport in carbon black-epoxy resin composites at different temperatures. J. Appl. Phys., 114: 33707-33707.
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  18. Macutkevic, J., P. Kuzhir, A. Paddubskaya, M. Shuba and J. Banys et al., 2013. Influence of carbon-nanotube diameters on composite dielectric properties. Phys. status solidi A, 210: 2491-2498.
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  19. Macutkevic, J., P. Kuzhir, A. Paddubskaya, J. Banys and S. Maksimenko et al., 2013. Onset of electrical percolation in onion-like carbon/poly (methyl methacrylate) composites. Nanosci. Nanotechnol. Lett., 5: 1201-1206.
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  20. Kuzhir, P.P., V.K. Ksenevich, A.G. Paddubskaya, S.A. Maksimenko, T. Kaplas and Y. Svirko, 2013. Transport and electromagnetic properties of ultrathin pyrolytic carbon films. J. Nanophotonics, 7: 73595-73595.
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  21. Kuzhir, P.P., A.G. Paddubskaya, S.A. Maksimenko, T. Kaplas and Y. Svirko, 2013. Microwave absorption properties of pyrolytic carbon nanofilm. Nanoscale res. Lett., 8: 1-6.
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  22. Kuzhir, P., N. Volynets, S. Maksimenko, T. Kaplas and Y. Svirko, 2013. Multilayered graphene in Ka-band: Nanoscale coating for aerospace applications. J. nanosci. Nanotechnol., 13: 5864-5867.
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  23. Kanygin, M.A., O.V. Sedelnikova, I.P. Asanov, L.G. Bulusheva and A.V. Okotrub et al., 2013. Effect of nitrogen doping on the electromagnetic properties of carbon nanotube-based composites. J. Appl. Phys., 113: 144315-144315.
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  24. De Vivo, B., P. Lamberti, V. Tucci, P.P. Kuzhir, S.A. Maksimenko and S. Bellucci, 2013. Equivalent electric circuits for the simulation of carbon nanotube-epoxy composites. IEEE Trans. Nanotechnol., 12: 696-703.
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  25. Bychanok, D.S., M.V. Shuba, P.P. Kuzhir, S.A. Maksimenko and V.V. Kubarev et al., 2013. Anisotropic electromagnetic properties of polymer composites containing oriented multiwall carbon nanotubes in respect to terahertz polarizer applications. J. Appl. Phys., 114: 114304-114304.
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  26. Bychanok, D.S., A.G. Paddubskaya, P.P. Kuzhir, S.A. Maksimenko, C. Brosseau, J. Macutkevic and S. Bellucci, 2013. A study of random resistor-capacitor-diode networks to assess the electromagnetic properties of carbon nanotube filled polymers. Appl. Phys. Lett., 103: 243104-243104.
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  27. Bychanok, D., P. Kuzhir, S. Maksimenko, S. Bellucci and C. Brosseau, 2013. Characterizing epoxy composites filled with carbonaceous nanoparticles from dc to microwave. J. Appl. Phys., 113: 124103-124103.
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  28. Batrakov, K., P. Kuzhir, S. Maksimenko, A, Paddubskaya, S. Voronovich, T. Kaplas and Y. Svirko, 2013. Enhanced microwave shielding effectiveness of ultrathin pyrolytic carbon films. Appl. Phys. Lett., 103: 73117-73117.
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  29. Avetissian, H.K., G.F. Mkrtchian, K.G. Batrakov, S.A. Maksimenko and A. Hoffmann, 2013. Nonlinear theory of graphene interaction with strong laser radiation beyond the dirac cone approximation: coherent control of quantum states in nano-optics. Phys. Rev. B, 88: 245411-245411.
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  30. Avetissian, H.K., G.F. Mkrtchian, K.G. Batrakov, S.A. Maksimenko and A. Hoffmann, 2013. Multiphoton resonant excitations and high-harmonic generation in bilayer graphene. Phys. Rev. B, 88: 165411-165411.
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  31. Slepyan, G.Y., Y.D. Yerchak, S.A. Maksimenko, A. Hoffmann and F.G. Bass, 2012. Mixed states in rabi waves and quantum nanoantennas. Phys. Rev. B, .
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  32. Shuba, M.V., D. Seliuta, P.P. Kuzhir, S.A. Maksimenko and V.K. Ksenevich et al., 2012. Antenna resonances in terahertz photoconductivity of single wall carbon nanotube fibers. Diamond Relat. Mater., 27: 36-39.
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  33. Shuba, M.V., A.G. Paddubskaya, P.P Kuzhir, S.A. Maksimenko and V.K. Ksenevich et al., 2012. Soft cutting of single-wall carbon nanotubes by low temperature ultrasonication in a mixture of sulfuric and nitric acids. Nanotechnol., .
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  34. Shuba, M.V., A.G. Paddubskaya, A.O. Plyushch, P.P Kuzhir and G.Y. Slepyan et al., 2012. Experimental evidence of localized plasmon resonance in composite materials containing single-wall carbon nanotubes. Phys. Rev. B, .
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  35. Mokhlespour, S., J.E.M. Haverkort, G. Slepyan, S. Maksimenko and A. Hoffmann, 2012. Collective spontaneous emission in coupled quantum dots: Physical mechanism of quantum nanoantenna. Phys. Rev. B, .
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  36. Macutkevic, J., D. Seliuta, G. Valusis, R. Adomavicius and A. Krotkus et al., 2012. Multi-walled carbon nanotubes/PMMA composites for THz applications. Diamond Relat. Mater., 25: 13-18.
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  37. Li, D., Y.S. Jung, H.K. Kim, J. Chen and D.A. Geller et al., 2012. The effect of sample holder geometry on electromagnetic heating of nanoparticle and NaCl solutions at 13. 56 MHz. IEEE Trans. Biomed. Eng., 59: 3468-3474.
  38. Kuzhir, P.P., K.N. Lapko, S.A. Maksimenko, V.A. Lomonosov and O.A. Ivashkevich et al., 2012. Heat-resistant phosphate composites modified by microstructure boron compounds and carbon nanotubes for nuclear physics applications. Dokl. Nat. Acad. Sci. Belarus, 56: 68-72.
  39. Kuzhir, P.P., A.G. Paddubskaya, S. Maksimenko, V.L. Kuznetsov and S. Moseenkov et al., 2012. Carbon onion composites for EMC applications. IEEE Trans. Electromagn. Compat., 54: 6-16.
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  40. Kuzhir, P.P., A.G. Paddubskaya, M.V. Shuba, S.A. Maksimenko and A. Celzardet al., 2012. Electromagnetic shielding efficiency in Ka-band: carbon foam versus epoxy/carbon nanotube composites. J. Nanophotonics, 6: 61715-61715.
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  41. Forestiere, C., A. Maffucci, S. Maksimenko, G. Miano and G.Y. Slepyan, 2012. Transmission-line model for multiwall carbon nanotubes with intershell tunneling. IEEE Trans. Nanotechnol., 11: 554-564.
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  42. Chiariello, A.G., C. Forestiere, A. Maffucci, S.A.M. Miano and G.Y. Slepyan, 2012. Electrical propagation models for single-and multi-wall carbon nanotubes. J. Nanoelectron. Optoelectron., 7: 12-16.
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  43. Batrakov, K.G., V.A. Saroka, S.A. Maksimenko and C. Thomsen, 2012. Plasmon polariton slowing down in graphene structures. J. Nanophotonics, .
  44. Shuba, M.V., G.Y. Slepyan, S.A. Maksimenko and G.W. Hanson, 2011. RF and microwave electrical response of carbon nanotube saline solutions for potential biomedical applications. Nanosci. Nanotechnol. Lett., 3: 885-888.
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  45. Miano, G., C. Forestiere, A. Maffucci, S.A. Maksimenko and G.Y. Slepyan, 2011. Signal propagation in carbon nanotubes of arbitrary chirality. IEEE Trans. Nanotechnol., 10: 135-149.
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  46. Kuzhir, P., A. Paddubskaya, D. Bychanok, A. Nemilentsau and M. Shuba et al., 2011. Microwave probing of nanocarbon based epoxy resin composite films: toward electromagnetic shielding. Thin Solid Films, 519: 4114-4118.
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  47. Bychanok, D.S., M.A. Kanygin, A.V. Okotrub, M.V. Shuba and A.G. Paddubskaya et al., 2011. Anisotropy of the electromagnetic properties of polymer composites based on multiwall carbon nanotubes in the gigahertz frequency range. JETP lett., 93: 607-611.
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  48. Slepyan, G.Y., M.V. Shuba, S.A. Maksimenko, C. Thomsen and A. Lakhtakia, 2010. Terahertz conductivity peak in composite materials containing carbon nanotubes: Theory and interpretation of experiment. Phys. Rev. B, .
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  49. Shuba, M.V., G.Y. Slepyan, S.A. Maksimenko and G.W. Hanson, 2010. Radiofrequency field absorption by carbon nanotubes embedded in a conductive host. J. Appl. Phys., .
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  50. Seliuta, D., I. Kasalynas, J. Macutkevic, G. Valusis and M.V. Shuba et al., 2010. Terahertz sensing with carbon nanotube layers coated on silica fibers: Carrier transport versus nanoantenna effects. Appl. Phys. Lett., .
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  51. Nemilentsau, A.M., M.V. Shuba, G.Y. Slepyan, P.P. Kuzhir, S.A. Maksimenko, P.N. D`yachkov and A. Lakhtakia, 2010. Substitutional doping of carbon nanotubes to control their electromagnetic characteristics. Phys. Rev. B, .
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  52. Nemilentsau, A.M., G.Y. Slepyan, S.A. Maksimenko, A. Lakhtakia and S.V. Rotkin, 2010. Spontaneous decay of the excited state of an emitter near a finite-length metallic carbon nanotube. Phys. Rev. B, .
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  53. Nemilentsau, A.M., G.Y. Slepyan, S.A. Maksimenko, A. Lakhtakia and S.V. Rotkin, 2010. Scattering of the near field of an electric dipole by a single-wall carbon nanotube. J. Nanophotonics, 4: 41685-41685.
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  54. Macutkevic, J., P. Kuzhir, D. Seliuta, G. Valusis and J. Banys et al., 2010. Dielectric properties of a novel high absorbing onion-like-carbon based polymer composite. Diamond Relat. Mater., 19: 91-99.
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  55. Burlaka, A., S. Lukin, S. Prylutska, O. Remeniak and Y. Prylutskyy et al., 2010. Hyperthermic effect of multi-walled carbon nanotubes stimulated with near infrared irradiation for anticancer therapy: in vitro studies. Exp. Oncol., 32: 48-50.
  56. Batrakov, K.G., O.V. Kibis, P.P Kuzhir, S.A. Maksimenko, M.R. da Costa and M.E. Portnoi, 2010. Mechanisms of terahertz emission from carbon nanotubes. Phys. B Condens. Matter, 405: 3054-3056.
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  57. Slepyan, G.Y., Y.D. erchak, S.A. Maksimenko and A. Hoffmann, 2009. Wave propagation of rabi oscillations in one-dimensional quantum dot chain. Phys. Lett. A, 373: 1374-1378.
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  58. Shuba, M.V., S.A. Maksimenko and G.Y. Slepyan, 2009. Absorption cross-section and near-field enhancement in finite-length carbon nanotubes in the terahertz-to-optical range. J. Comput. Theor. Nanosci., 6: 2016-2023.
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  59. Shuba, M.V., G.Y. Slepyan, S.A. Maksimenko, C. Thomsen and A. Lakhtakia, 2009. Theory of multiwall carbon nanotubes as waveguides and antennas in the infrared and the visible regimes. Phys. Rev. B, .
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  60. Mazov, I., V. Kuznetsov, S. Moseenkov, A. Usoltseva and A. Romanenko et al., 2009. Electromagnetic shielding properties of MWCNT/PMMA composites in Ka-band. Phys. status solidi B, 246: 2662-2666.
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  61. Kuzhir, P., S. Maksimenko, D. Bychanok, V. Kuznetsov and S. Moseenkov et al., 2009. Nano-scaled onion-like carbon: Prospective material for microwave coatings. Metamater., 3: 148-156.
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  62. Kibis, O.V., G.Y. Slepyan, S.A. Maksimenko and A. Hoffmann, 2009. Matter coupling to strong electromagnetic fields in two-level quantum systems with broken inversion symmetry. Phys. Rev. lett., .
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  63. Batrakov, K.G., S.A. Maksimenko, P.P Kuzhir and C. Thomsen, 2009. Carbon nanotube as a cherenkov-type light emitter and free electron laser. Phys. Rev. B, .
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  64. Slepyan, G.Y. and S.A. Maksimenko, 2008. Photon-statistics dispersion in excitonic composites. New J. Phys., .
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  65. Maksimenko, S.A., G.Y. Slepyan, K.G. Batrakov, A.A. Khrushchinsky, P.P. Kuzhir, A.M. Nemilentsau and M.V. Shuba, 2008. Electromagnetic waves in carbon nanostructures. In: Carbon Nanotubes and Related Structures. Blank V. and B. Kulnitskiy, (Ed.). Research Signpost, India, pp: 147-187.
  66. Maksimenko, S.A., G.Y. Slepyan, A.M. Nemilentsau and M.V. Shuba, 2008. Carbon nanotube antenna: far-field, near-field and thermal-noise properties. Physica E, 40: 2360-2364.
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  67. Macutkevic, J., R. Adomavicius, A. Krotkus, D. Seliuta and G. Valusis et al., 2008. Terahertz probing of onion-like carbon-PMMA composite films. Diamond Relat. Mater., 17: 1608-1612.
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  68. Langlet, R., P. Lambin, A. Mayer, P.P. Kuzhir and S.A. Maksimenko, 2008. Dipole polarizability of onion-like carbons and electromagnetic properties of their composites. Nanotechnol., .
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  69. Slepyan, G.Y., A. Magyarov, S.A. Maksimenko and A. Hoffmann, 2007. Microscopic theory of quantum dot interactions with quantum light: Local field effect. Phys. Rev. B, .
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  70. Shuba, M.V., S.A. Maksimenko and A. Lakhtakia, 2007. Electromagnetic wave propagation in an almost circular bundle of closely packed metallic carbon nanotubes. Phys. Rev. B, .
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  71. Nemilentsau, A.M., G.Y. Slepyan and S.A. Maksimenko, 2007. Thermal radiation from carbon nanotubes in the terahertz range. Phys. Rev. lett., .
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  72. Maksimenko, S.A., V.N. Rodionova, G.Y. Slepyan, V.A. Karpovich and O. Shenderova et al., 2007. Attenuation of electromagnetic waves in onion-like carbon composites. Diamond relat. Mater., 16: 1231-1235.
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  73. Slepyan, G.Y., M.V. Shuba, S.A. Maksimenko and A. Lakhtakia, 2006. Theory of optical scattering by achiral carbon nanotubes and their potential as optical nanoantennas. Phys. Rev. B, .
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  74. Nemilentsau, A.M., G.Y. Slepyan, A.A. Khrutchinskii and S.A. Maksimenko, 2006. Third-order optical nonlinearity in single-wall carbon nanotubes. Carbon, 44: 2246-2253.
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  75. Slepyan, G.Y., A. Magyarov, S.A. Maksimenko, A. Hoffmann and D. Bimberg, 2004. Rabi oscillations in a semiconductor quantum dot: Influence of local fields. Phys. Rev. B, .
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  76. Maksimenko S.A. and G.Y. Slepyan, 2004. Nanoelectromagnetics of low-dimensional structures. In: The Handbook of Na-notechnology: Nanometer Structure Theory, Modeling, and Simulation. Lakhtakia, A. (Ed.). SPIE Press, Washington USA, pp: 145-206.
  77. Lakhtakia, A. and S.A. Maksimenko, 2004. Nanomodeling. SPIE Press, Bellingham, Pages: 226.
  78. Maksimenko S.A. and G.Y. Slepyan, 2003. Electromagnetics of Carbon Nanotubes. In: Introduction to Complex Mediums for Optics and Electromagnetics. Weiglhofer W. and A. Lakhtakia, (Ed.). SPIE Press, Washington USA, pp: 507-546.
  79. Bondarev, I.V., S.A. Maksimenko, G.Y. Slepyan, I.L. Krestnikov and A. Hoffmann, 2003. Exciton-phonon interactions and exci-ton dephasing in semiconductor quantum-well heterostructures. Phys. Rev. B, .
  80. Stanciu, C., R. Ehlich, V. Petrov, O. Steinkellner and J. Herrmann et al., 2002. Experimental and theoretical study of third-order harmonic generation in carbon nanotubes. Appl. Phys. Lett., 81: 4064-4066.
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  81. Slepyan, G.Y., S.A. Maksimenko, A. Hoffmann and D. Bimberg, 2002. Quantum optics of a quantum dot: Local-field effects. Phys. Rev. A, .
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  82. Maksimenko, S.A. and G.Y. Slepyan, 2002. Electrodynamics of carbon nanotubes (review). J. Commun. Technol. Electron., 47: 235-252.
  83. Bondarev, I.V., G.Y. Slepyan and S.A. Maksimenko, 2002. Spontaneous decay of excited atomic states near a carbon nano- tube. Phys. Rev. Lett., .
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  84. Slepyan, G.Y., S.A. Maksimenko, V.P. Kalosha, A.V. Gusakov and J. Herrmann, 2001. High-order harmonic generation by conduction electrons in carbon nanotube ropes. Phys. Rev. A, .
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  85. Slepyan, G.Y., S.A. Maksimenko, V.P. Kalosha, A. Hoffmann and D. Bimberg, 2001. Effective boundary conditions for planar quantum dot structures. Phys. Re. B, .
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  86. Maksimenko, S.A., G.Y. Slepyan, V.P. Kalosha, S.V. Maly and N.N. Ledentsov et al., 2000. Electromagnetic response of 3D arrays of quantum dots. J. Electron. Mater., 29: 494-503.
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  87. Maksimenko S.A. and G.Y. Slepyan, 2000. Electrodynamic properties of carbon nanotubes. In: Electromagnetic Fields in Unconventional Structures and Materials. Singh O.N. and A. Lakhtakia, (Ed.). John Wiley & Sons, Inc., New York, pp: 217-255.

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