Staff
 
 
 
   

Arkady V. Kim
Head of laboratory “Extreme nonlinear optics”
Ph.D.

Education:
Nizhny Novgorod State University, graduated in 1974, radiophysics, PhD thesis “Ionization instabilities of nonequilibrium high-frequency discharges in wave fields”, supervisor - prof. V.B.Gildenburg.

Scope of professional interests:
Superstrong laser matter interactions, laser particle acceleration, extreme nonlinear and fibre optics

Publications:
~100

Most significant papers and results:

  1. A.V. Bashinov and A.V. Kim, On the electrodynamic model of ultra-relativistic laser-plasma interactions caused by radiation reaction effects, Phys. Plasmas 20, 113111 (2014).
  2. A. Gonoskov,  I. Gonoskov, C. Harvey, A. Ilderton, A. Kim, M. Marklund, G. Mourou, A. Sergeev, Probing Nonperturbative QED with Optimally Focused Laser Pulses, Phys. Rev. Lett. 111, 060404 (2013).
  3. F. Cattani, A. Kim, D. Anderson, M. Lisak, Interactions of electromagnetic radiation with Bose Einstein condensates: manipulating ultra–cold atoms with light, Int. J. of Modern Physics B 27, No. 6, 1330003 (2013).
  4. A. Pipahl, E. A. Anashkina, M. Toncian, T. Toncian, S. A. Skobelev, A. V. Bashinov, A. A. Gonoskov, O. Willi, A. V. Kim, High-intensity few-cycle laser-pulse generation by the plasma-wakefield self-compression effect, Phys. Rev. E 87, 033104 (2013).
  5. A. Pipahl, E. A. Anashkina, M. Toncian, T. Toncian, S. A. Skobelev, A. V. Bashinov, A. A. Gonoskov, O. Willi, A. V. Kim, Towards high intensity few-cycle pulses using plasma wakefield self-compression effect, J. Phys.: Conf. Ser. 414,  012011 (2013).
  6. A.V. Korzhimanov, E.S. Efimenko, A.V. Kim, S.V. Golubev, “Production of multiply charged ion beams with an energy of tens of MeV/nucleon by ultrahigh-power laser radiation for nuclear physics problems”,  Quantum Electronics 43 (3), 217 – 225 (2013).
  7. E.A. Anashkina, A.V. Andrianov, A.V. Kim, "Nonlinear frequency up-conversion of femtosecond pulses from an erbium fibre laser to the range of 0.8 – 1 µm in silica fibres", Quantum Electronics 43 (3), 263 – 270 (2013).
  8. A.V. Andrianov, E.A. Anashkina, S.V. Muravyev, A.V. Kim, "Hybrid Er/Yb fibre laser system for generating few-cycle 1.6 to 2.0 µm pulses optically synchronised with high-power pulses near 1 µm", Quantum Electronics 43 (3), 256 – 262 (2013).
  9. A.V. Bashinov, A.A. Gonoskov, A.V. Kim, M. Marklund, G. Mourou, A.M. Sergeev, “Electron acceleration and emission in a field of a plane and converging dipole wave of relativistic amplitudes with the radiation reaction force taken into account”, Quantum Electronics 43 (4), 291 – 299 (2013).
  10. A.V. Korzhimanov, E. S. Efimenko, S.V. Golubev, and A.V. Kim, Generating High-Energy Highly Charged Ion Beams from Petawatt-Class Laser Interactions, Phys. Rev. Lett. 109, 245008 (2012).
  11. E.A. Anashkina,A.V. Andrianov, M.Yu. Koptev, V.M. Mashinsky, S.V. Muravyev, and A.V. Kim, Generating tunable optical pulses over the ultrabroad range of 1.6-2.5 μm in GeO2-doped silica fibers with an Er:fiber laser source,  Opt. Express 24, 207102 (2012). 
  12. S. A. Skobelev, A.V. Kim, and O. Willi, Generation of High-Energy Few-Cycle Laser Pulses by Using the Ionization-Induced Self-Compression Effect, Phys. Rev. Lett. 108, 123904 (2012).
  13. E.A. Anashkina∗, A.V. Andrianov, S.V. Muravyev, and A.V. Kim, All-fiber design of erbium-doped laser system for tunable two-cycle pulse generation,  Opt. Express 19, 20141 (2011). 
  14. E. S. Efimenko and A. V. Kim, Strongly coupled regime of ionization-induced scattering in ultrashort laser-matter interactions, Phys. Rev. E 84, 036408 (2011).
  15. A. A. Gonoskov, A. V. Korzhimanov, A. V. Kim, M. Marklund, and A. M. Sergeev, Ultrarelativistic nanoplasmonics as a route towards extreme-intensity attosecond pulses, Phys. Rev. E 84, 046403 (2011).
  16. A.A. Soloviev, K.F.Burdonov, V.N.Ginzburg, A.A.Gonoskov, E.V.Katin, A.V.Kim et al., Fast electron generation using PW-class PEARL facility, Nuclear Instruments and Methods in Physics Research A 653, 35-41 (2011).
  17. F. Cattani, A. Kim, T. Hansson, D. Anderson and M. Lisak, Multihump soliton-like structures in interactions of lasers and Bose-Einstein condensates, Europhys. Lett. 94, 53003 (2011).
  18. A.V. Kim and S.A. Skobelev, Few-cycle vector solitons of light, Phys. Rev. A 83, 063832 (2011)
  19. F. Cattani, A. Kim, D. Anderson, and M. Lisak, Co-propagating Bose-Einstein condensates and electromagnetic radiation: Emission of mutually localized structures, Phys. Rev. A 83, 013608 (2011). 
  20. E.S. Efimenko, A.V. Kim, and M. Quiroga-Teixeiro, Ionization-induced dynamics of laser-matter interaction in a focused faser pulse: A comparative analysis, Phys. Plasmas 18, (2011).
  21. F. Cattani, V. Geyko, A. Kim, D. Anderson, and M. Lisak, Interacting laser and Bose-Einstein-condensate atomic beams: Mutual guiding structures,  Phys. Rev. A 81, 043623 (2010). 
  22. F. Cattani, A. Kim, D. Anderson and M. Lisak, Co-propagating Bose–Einstein condensates and electromagnetic radiation: formation of mutually localized structures, J. Phys. B: At. Opt. Mol. Phys. 43, 085301 (2010).
  23. A. Andrianov, E. Anashkina, S. Muravyev, and A. Kim, All-fiber design of hybrid Er-doped laser/Yb-doped amplifier system for high-power ultrashort pulse generation, Opt. Lett. 35, 3805 (2010).
  24. V.I. Eremin, A.V. Korzhimanov, and A.V. Kim, Relativistic self-induced transparency effect during ultraintense laser interaction with overdense plasmas: Why it occurs and its use for ultrashort electron bunch generation, Phys. Plasmas 17, 043102 (2010).   
  25. A. Andrianov, A. Kim, S. Muraviov, and A. Sysoliatin, Wavelength-tunable few-cycle optical pulses directly from an all-fiber Er-doped laser setup,  Opt. Lett. 34, 3193 (2009).
  26. A.A. Gonoskov, A.V. Korzhimanov, V.. Eremin, A.V. Kim, and A.M. Sergeev, Multicascade Proton Acceleration by a Superintense Laser Pulse in the Regime of Relativistically Induced Slab Transparency, Phys. Rev. Lett. 102, 184801 (2009).
  27. E.S. Efimenko, A.V. Kim, and M. Quiroga-Teixeiro, Ionization-Induced Small-Scaled Plasma Structures in Tightly Focused Ultrashort Laser Pulses, Phys. Rev. Lett. 102, 015002 (2009).
  28. A.V. Andrianov, S.V. Muraviev, A.V. Kim, and A.A. Sysoliatin, Widely-Wavelength-Tunable Few-Cycle Optical Pulse Generation from an All-Fiber Erbium-Doped Laser System, Laser Physics 19, 2014 (2009).
  29. S.A. Skobelev, D.I. Kulagin, A.N. Stepanov, A.V. Kim, A.M. Sergeev, N.E. Andreev, Ionization Self-Compression of Intense Femtosecond Pulses Propagating through Gas-Filled Dielectric Capillaries, JETP Lett. 89, 540-546 (2009).
  30. A.V. Kim, S.A. Skobelev, D. Anderson, T. Hansson, and M. Lisak, Extreme nonlinear optics in a Kerr medium: Exact soliton solutions for a few cycles, Phys. Rev. A 77, 043823 (2008).
  31. S.A. Skobelev, D.V. Kartashov, and A.V. Kim, Few-Optical-Cycle Solitons and Pulse Self-Compression in a Kerr Medium, Phys. Rev. Lett. 99, 203902 (2007).
  32. À.V. Korzhimanov, À.À. Gonoskov, À.V. Kim, À.Ì. Sergeev, Proton and Light-Ion Acceleration to Relativistic GeV Energies by the Superstrong Laser Radiation Interacting with a Structured Plasma Target, JETP Lett. 86, 577-583 2007).
  33. A.V. Andrianov, S.V. Muraviov, À.V. Kim, À.À. Sysoliatin, Generation of Optical Soliton Pulses Smoothly Tunable in a Wide Frequency Range in Silica Fibers with Variable Dispersion, JETP Lett. 85, 364-368 (2007).
  34. A.V. Andrianov, S.V. Muraviev, A.V. Kim, and A.A. Sysoliatin, DDF-Based All-Fiber Optical Source of Femtosecond Pulses Smoothly Tuned in the Telecommunication Range, Laser Physics 17, 1296 (2007).
  35. S.I. Krasheninnikov, A.V. Kim, B.K. Frolov, and R. Stephens, Intense electron beam propagation through insulators: Ionization front structures and stability, Phys. Plasmas 12, 073105 (2005).
  36. F. Cattani, D. Anderson, A.V. Kim, M. Lisak, Formation of Bose-Einstein Condensate Structures in Laser Fields: Semiclassical Approach and Electrodynamic Effects, Ïèñüìà â ÆÝÒÔ 81, 693 (2005).
  37. S.À. Skobelev, À.Â. Kim, On the dynamic Properties of “Elastic” Interactions between Wave Solitons Consisting of a Few Field Oscillation Cycles, JETP Lett. 80, 623-627 (2004).
  38. U. Jordan, D. Anderson, A. Kim et al., Microwave Breakdown in Slots, IEEE Trans. Plasma Sci. 32, 2250 (2004).
  39. D.V. Kartashov, A.V. Kim, S.À. Skobelev, Soliton Structures of a Wave Field with an Arbitrary Number of Oscillations in Nonresonance Media, JETP Lett. 78, 276-280 (2003).
  40. D.V. Kartashov, A.V. Kim, S.À. Skobelev, Nonlinear dynamics of wave fields in nonresonant media: from envelope solitons toward video solitons, Radiophysics and Quantum Electronics, 45, 374-385 (2003).
  41. A. Kim et al., Axial Magnetic Fields in Relativistic Self-Focusing Channels, Phys. Rev. Lett. 89, 095003 (2002).
  42. A. Kim et al., Axisymmetric relativistic self-channeling of laser light in plasmas, Phys. Rev. E 65, 036416 (2002). 
  43. M. Tushentsov, A. Kim et al., Electromagnetic Energy Penetration in the Self-Induced Transparency Regime of Relativistic Laser-Plasma Interactions, Phys. Rev. Lett. 87, 275002 (2001).
  44. F. Cattani, A. Kim et al., Multifilament structures in relativistic self-focusing, Phys. Rev. E 64, 016412 (2001).
  45. A. Kim et al., New Regime of Anomalous Penetration of Relativistically Strong Laser Radiation into an Overdense Plasma, JETP Lett. 72, 241-244 (2000).
  46. F. Cattani, A. Kim et al., Threshold of induced transparency in the relativistic interaction of an electromagnetic wave with overdense plasmas, Phys. Rev. E 62, 1234 (2000).
  47. A.M. Sergeev, M. Lontano, A.V. Kim et al., Ionization-induced leaking-mode channeling short laser pulse in gases, Laser Part Beams 17, 129-138, 1999.
  48. À.V. Kim, M.Yu. Ryabikin, A.M. Sergeev, From femtosecond to attosecond pulses, Physics-Uspekhi 42, 54-61 (1999).
  49. M. Lontano, G. Lampis, A.V. Kim, et al., Intense laser pulse dynamics in dense gases, Physica  Scripta T63, 141-147 (1996).
  50. D. Anderson, M. Lisak, A.V. Kim et al., Self-sustained plasma waveguide structures produced by ionizing laser radiation in a dense gas, Phys. Rev. E 52, 4564 (1995).
  51. E.V. Vanin, Ì.Ñ. Downer, A.V. Kim, A.M. Sergeev, Excitation of ultrashot bursts of harmonics of the radiation during ionization of a gas by an intense light pulses, JETP Lett. 58, 900-906 (1993). 
  52. V.B. Gildenburg, A.V. Kim, V.A. Krupnov, V.E. Semenov, A.M. Sergeev, N.A. Zharova, Adiabatic frequency conversion of powerful electromagnetic pulses producing gas ionization, IEEE Trans. Plasma Sci. 21, 34, (1993). 
  53. A.V. Kim, S.F. Lirin, A.M. Sergeev, E.V. Vanin, L. Stenflo, Compression and frequency up-conversion of an ultrashort ionizing pulse in a plasma, Phys. Rev. 42, R2493 (1990).
  54. V.G.Avetisov, S.I.Gritsinin, A.V.Kim et al., Ionization collapse of RF plasma filament in dense gas, JETP Lett. 51, 348 (1990).
  55. V.B.Gildenburg, I.S.Guschin, S.A.Dvinin, A.V.Kim, Dynamics of high-frequency streamer, Sov. Phys. JETP 70, 654 (1990).
  56. V.B.Gildenburg, A.V.Kim, A.M.Sergeev, Possibility of sharp increase in the frequency of the radiation of ionizing laser pulse in gas, JETP Lett. 51, 104 (1990).
  57. A.V.Kim, G.M.Fraiman, Nonlinear stage of the thermal-ionization instability in a high-pressure rf discharge, Sov. J. Plasma Phys. 9, 358 (1983).
  58. V.B.Gildenburg, A.V.Kim, Ionization-thermal instability of a RF discharge in an electromagnetic wave, Sov. J. Plasma Phys. 6, 496 (1980).
  59. V.B.Gildenburg, A.V.Kim, Ionization instabilities of an electromagnetic wave, Sov. Phys. JETP 47, 72 (1978).