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Международный научно-образовательный центр физики наноструктур

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Сотрудник подразделения

Иван Дмитриевич Рухленко

доктор физико-математических наук

Центр Информационные Оптические Технологии

Рухленко И.Д. является известным специалистом в области нанофотонки, кремниевой фотоники и оптики квантовых наноструктур. Автор более 160 статей в рецензируемых научных журналах, одной монографии, двух глав в книгах и двух методических пособий. Основные направления его научной деятельности: нелинейные оптические процессы в кремниевых волноводах и волноводах с кремниевыми нанокристаллами; распространение электромагнитного излучения в плазмонных волноводах; физика и спектроскопия полупроводниковых нанокристаллов; оптические свойства двумерных и трехмерных суперкристаллов; искусственная оптическая активность неорганических наночастиц; и оптические методы разделения энантиомеров.


H-index: 41

i10-index: 115

Citations4669


(Источник: Google Scholar, 21 октября 2022 г.).


Монографии, главы в книгах и учебные пособия


  • И. А. Вовк, А. В. Баранов, М. Ю. Леонов, И. Д. Рухленко. Физика полупроводниковых нанокристаллов. — СПб: Университет ИТМО, 2021. — 87 с.
  • I. D. Rukhlenko, Modeling Nonlinear Optical Phenomena in Silicon-Nanocrystal Structures, in Silicon Nanophotonics: Basic Principles, Current Status and Perspectives, 2nd ed., L. Khriachtchev, ed., pp. 61–108, ISBN: 978-981-4669-76-4 (Pan Stanford, 2016).
  • H. T. Hattori, I. D. Rukhlenko, Z. Li, and M. Premaratne, Integrated Plasmonic Nanodevices, in Nanophotonics: Advanced Device Applications, K. Iniewski, ed., pp. 31–56, ISBN: 978-1-4665-1426-3 (CRC Press, 2013).
  • A. V. Fedorov, I. D. Rukhlenko, A. V. Baranov, and S. Yu. Kruchinin, Optical Properties of Semiconductor Quantum Dots, in Russian, ISBN: 978-5-02-025402-2 (Nauka, Saint Petersburg, 2011).
  • I. D. Rukhlenko, Scientific Revolutions in Physics and Cosmology (Tutorial), in Russian (published by the Saint Petersburg State University of Information Technologies, Mechanics and Optics, Saint Petersburg, 2008).

Публикации

  1. 185Natalin N.V., Kundelev E.V., Rukhlenko I.D., Tepliakov N.V. Optical Properties of Twisted Bilayer Graphene with Magnetic Defects // Electronic Structure - 2023, Vol. 5, No. 5, pp. 024008
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  2. 184Kundelev E.V., Strievich E.D., Tepliakov N.V., Murkina A.D., Dubavik A., Ushakova E.V., Baranov A.V., Fedorov A.V., Rukhlenko I.D., Rogach A.L. Structure-Optical Property Relationship of Carbon Dots with Molecular-like Blue-Emitting Centers // Journal of Physical Chemistry C - 2022, Vol. 126, No. 42, pp. 18170–18176 [IF: 4.536, SJR: 1.401]
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  3. 183Hajian H., Rukhlenko I.D., Hanson G., Ozbay E. Hybrid surface plasmon polaritons in graphene coupled anisotropic van der Waals material waveguides // Journal of Physics D: Applied Physics - 2021, Vol. 54, No. 45, pp. 455102 [IF: 2.588, SJR: 0.857]
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  4. 182Noskov R.E., Machnev A., Shishkin I.I., Novoselova M., Gayer A., Ezhov A.A., Shirshin E., German S., Rukhlenko I.D., Fleming S., Khlebtsov B., Gorin D., Ginzburg P. Golden Vaterite as a Mesoscopic Metamaterial for Biophotonic Applications // Advanced materials - 2021, Vol. 33, No. 25, pp. 2008484 [IF: 19.791, SJR: 10.707]
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  5. 181Ansari M.A., Kim I., Rukhlenko I.D., Zubair M., Yerci S., Tauqeer T., Mehmood M., Rho J. Engineering spin and antiferromagnetic resonances to realize an efficient direction-multiplexed visible meta-hologram // Nanoscale Horizons - 2020, Vol. 5, No. 1, pp. 57-64 [SJR: 2.992]
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  6. 180Ansari M.A., Kim I., Rukhlenko I.D., Zubair M., Yerci S., Tauqeer T., Mehmood M., Rho J. Erratum: Engineering spin and antiferromagnetic resonances to realize an efficient direction-multiplexed visible meta-hologram (Nanoscale Horizons (2020) 5 (57-64) DOI: 10.1039/C9NH00460B) // Nanoscale Horizons - 2020, Vol. 5, No. 2, pp. 373 [SJR: 2.992]
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  7. 179Hajian H., Ozbay E., Rukhlenko I.D., Hanson G.W., Low T., Butun B. Tunable plasmon-phonon polaritons in anisotropic 2D materials on hexagonal boron nitride // Nanophotonics - 2020, Vol. 9, No. 12, pp. 3909-3920 [IF: 4.492, SJR: 2.717]
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  8. 178Kundelev E.V., Tepliakov N.V., Leonov M.Y., Maslov V.G., Baranov A., Fedorov A.V., Rukhlenko I.D., Rogach A.L. Toward Bright Red-Emissive Carbon Dots through Controlling Interaction among Surface Emission Centers // Journal of Physical Chemistry Letters - 2020, Vol. 11, No. 19, pp. 8121-8127 [IF: 9.353, SJR: 2.563]
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  9. 177Peng Q., Akram M., Rukhlenko I.D., Zhu W. Highly transmissive bilayer Huygens’ metasurface with over 315° phase coverage // AEU - International Journal of Electronics and Communications - 2020, Vol. 124, pp. 153330 [IF: 1.147]
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  10. 176Tepliakov N.V., Orlov A.V., Kundelev E.V., Rukhlenko I.D. Twisted Bilayer Graphene Quantum Dots for Chiral Nanophotonics // Journal of Physical Chemistry C - 2020, Vol. 124, No. 41, pp. 22704-22710 [IF: 4.536]
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  11. 175Vovk I.A., Litvin A.P., Ushakova E.V., Cherevkov S.A., Fedorov A.V., Rukhlenko I.D. Nonparabolicity of Size-quantized Subbands of Bilayer Semiconductor Quantum Wells with Heterojunction // Optics express - 2020, Vol. 28, No. 2, pp. 1657-1664 [IF: 3.307, SJR: 1.394]
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  12. 174Vovk I.A., Lobanov V.V., Litvin A.P., Leonov M.Y., Fedorov A.V., Rukhlenko I.D. Band Structure and Intersubband Transitions of Three-Layer Semiconductor Nanoplatelets // Nanomaterials - 2020, Vol. 10, No. 5, pp. 933 [IF: 3.553, SJR: 0.919]
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  13. 173Yu Y., Xiao F., Rukhlenko I.D., Zhu W. High-efficiency ultra-thin polarization converter based on planar anisotropic transmissive metasurface // AEU - International Journal of Electronics and Communications - 2020, Vol. 118, pp. 153141 [IF: 1.147, SJR: 0.547]
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  14. 172Zhang J., Wei X., Rukhlenko I.D., Chen H., Zhu .W. Electrically tunable metasurface with independent frequency and amplitude modulations // ACS Photonics - 2020, Vol. 7, No. 1, pp. 265-271 [IF: 6.756, SJR: 2.735]
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  15. 171Baimuratov A.S., Martynenko I.V., Baranov A.V., Fedorov A.V., Rukhlenko I.D., Kruchinin S.Y. Giant Stokes Shifts in AgInS2 Nanocrystals with Trapped Charge Carriers // Journal of Physical Chemistry C - 2019, Vol. 123, No. 26, pp. 16430-16438 [IF: 4.536, SJR: 1.401]
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  16. 170Baimuratov A.S., Pereziabova T.P., Tepliakov N.V., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Electric-field effect on the optical activity of helical semiconductor nanoribbons // Proceedings of SPIE - 2019, Vol. 11207, pp. 112070T [SJR: 0.192]
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  17. 169Baimuratov A.S., Pereziabova T.P., Tepliakov N.V., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Electric-field-enhanced circular dichroism of helical semiconductor nanoribbons // Optics Letters - 2019, Vol. 44, No. 3, pp. 499-502 [IF: 3.416]
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  18. 168Cai K., He C., Xiao F., Rukhlenko I.D., Zhu W. Resonant mode coupling in hybrid all-dielectric metamaterial // Materials Research Express - 2019, Vol. 6, No. 12, pp. 125801 [IF: 1.068, SJR: 0.383]
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  19. 167Kundelev E.V., Tepliakov N.V., Leonov M.Y., Maslov V.G., Baranov A.V., Fedorov A.V., Rukhlenko I.D., Rogach A.L. Amino Functionalization of Carbon Dots Leads to Red Emission Enhancement // Journal of Physical Chemistry Letters - 2019, Vol. 10, No. 17, pp. 5111-5116 [IF: 9.353, SJR: 2.563]
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  20. 166Martynenko I.V., Baimuratov A.S., Weigert F., Soares J.X., Dhamo L., Nickl P., Doerfel I., Pauli J., Rukhlenko I.D., Baranov A.V., Resch-Genger U. Photoluminescence of Ag-In-S/ZnS Quantum Dots: Excitation Energy Dependence and Low-Energy Electronic Structure // Nano Research - 2019, Vol. 12, No. 7, pp. 1595-1603 [IF: 7.354, SJR: 2.536]
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  21. 165Shao L., Zhu .W., Leonov M.Y., Rukhlenko I.D. Dielectric 2-bit coding metasurface for electromagnetic wave manipulation // Journal of Applied Physics - 2019, Vol. 125, No. 20, pp. 203101 [IF: 2.068, SJR: 0.699]
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  22. 164Tepliakov N.V., Kundelev E.V., Khavlyuk P., Xiong Y., Leonov M.Y., Zhu .W., Baranov A.V., Fedorov A.V., Rogach A.L., Rukhlenko I.D. Sp2–sp3-Hybridized Atomic Domains Determine Optical Features of Carbon Dots // ACS Nano - 2019, Vol. 13, No. 9, pp. 10737-10744 [IF: 13.942, SJR: 5.554]
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  23. 163Tepliakov N.V., Vovk I.A., Baimuratov A.S., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Optical activity of chiral semiconductor gammadions // Proceedings of SPIE - 2019, Vol. 11026, pp. 110260B [SJR: 0.192]
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  24. 162Tepliakov N.V., Vovk I.A., Leonov M.Y., Baranov A., Fedorov A.V., Rukhlenko I.D. Electronic and Optical Properties of Perovskite Quantum-Dot Dimer // Semiconductors - 2019, Vol. 53, No. 16, pp. 2158-2161 [IF: 0.602, SJR: 0.287]
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  25. 161Tepliakov N.V., Vovk I.A., Shlykov A.I., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Optical activity and circular dichroism of perovskite quantum-dot molecules // Journal of Physical Chemistry C - 2019, Vol. 123, No. 4, pp. 2658–2664 [IF: 4.536, SJR: 1.401]
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  26. 160Xie J., Quader S., Xiao F., He C., Liang X., Geng J., Jin R., Zhu .W., Rukhlenko I.D. Truly all-dielectric ultrabroadband metamaterial absorber: Water-based and ground-free // IEEE Antennas and Wireless Propagation Letters - 2019, Vol. 18, No. 3, pp. 536-540 [IF: 2.533, SJR: 1.328]
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  27. 159Baimuratov A.S., Pereziabova T.P., Leonov M.Y., Zhu .W., Baranov A.V., Fedorov A.V., Gun’ko Y.K., Rukhlenko I.D. Optically Active Semiconductor Nanosprings for Tunable Chiral Nanophotonics // ACS Nano - 2018, Vol. 12, No. 6, pp. 6203–6209 [IF: 13.942, SJR: 5.554]
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  28. 158Lv W., Xie F., Huang Y., Li J., Fang X., Rashid A., Zhu W., Rukhlenko I.D., Wen G. Nonlinear coupling states study of electromagnetic force actuated plasmonic nonlinear metamaterials // Optics express - 2018, Vol. 26, No. 3, pp. 3211-3220 [IF: 3.307, SJR: 1.394]
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  29. 157Martynenko I.V., Baimuratov A.S., Osipova V.A., Kuznetsova V.A., Purcell-Milton F., Rukhlenko I.D., Fedorov A.V., Gun’ko Y.K., Resch-Genger U., Baranov A.V. Excitation Energy Dependence of the Photoluminescence Quantum Yield of Core/Shell CdSe/CdS Quantum Dots and Correlation with Circular Dichroism // Chemistry of Materials - 2018, Vol. 32, No. 2, pp. 465-471 [IF: 9.466, SJR: 3.741]
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  30. 156Pereziabova T.P., Baimuratov A.S., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Optical Activity of Semiconductor Nanosprings // Optics and spectroscopy - 2018, Vol. 125, No. 5, pp. 684-687 [IF: 0.716, SJR: 0.283]
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  31. 155Purcell-Milton F., Mckenna R., Brennan L., Cullen C., Guillemeney L., Tepliakov N.V., Baimuratov A.S., Rukhlenko I.D., Perova T.S., Duesberg G., Baranov A.V., Fedorov A.V., Gun’ko Y.K. Induction of chirality in two-dimensional nanomaterials: Chiral 2D MoS2 nanostructures // ACS Nano - 2018, Vol. 12, No. 2, pp. 954-964 [IF: 13.942, SJR: 5.554]
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  32. 154Tepliakov N.V., Baimuratov A.S., Vovk I.A., Leonov M.Y., Baranov A., Fedorov A.V., Rukhlenko I.D. Circular dichroism study of colloidal semiconductor nanoscrolls // Оптика и спектроскопия - 2018, Vol. 125, No. 5, pp. 652 [IF: 0.484]
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  33. 153Tepliakov N.V., Baimuratov A.S., Vovk I.A., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Circular Dichroism Study of Colloidal Semiconductor Nanoscrolls // Optics and spectroscopy - 2018, Vol. 125, No. 5, pp. 688-692 [IF: 0.716]
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  34. 152Tepliakov N.V., Vovk I.A., Baimuratov A.S., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Optical Activity of Semiconductor Gammadions beyond Planar Chirality // Journal of Physical Chemistry Letters - 2018, Vol. 9, No. 11, pp. 2941-2945 [IF: 9.353, SJR: 2.563]
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  35. 151Tepliakov N.V., Vovk T.A., Rukhlenko I.D., Rozhdestvensky Y.V. Maser emission from gravitational states on isolated neutron stars // Astrophysical Journal - 2018, Vol. 857, No. 1, pp. 41 [IF: 5.533, SJR: 2.376]
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  36. 150Vovk I.A., Tepliakov N.V., Baimuratov A.S., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Excitonic Phenomena in Perovskite Quantum-Dot Supercrystals // Physical Chemistry Chemical Physics - 2018, Vol. 20, No. 38, pp. 25023-25030 [IF: 4.123, SJR: 1.053]
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  37. 149Vovk I.A., Tepliakov N.V., Baimuratov A.S., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Theory of Frenkel Excitons in Planar Arrays of Perovskite Quantum Dots // Optics and spectroscopy - 2018, Vol. 125, No. 5, pp. 693-697 [IF: 0.716, SJR: 0.283]
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  38. 148Xie J., Zhu .W., Rukhlenko I.D., Xiao F., He C., Geng J., Liang X., Jin R., Premaratne M. Water metamaterial for ultra-broadband and wide-angle absorption // Optics express - 2018, Vol. 26, No. 4, pp. 5052-5059 [IF: 3.307, SJR: 1.394]
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  39. 147Andronaki S.A., Zhu .W., Leonov M.Y., Shalkovskiy A.G., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Effect of extinction on separation of nanoparticle enantiomers with chiral optical forces // IEEE Photonics Journal - 2017, Vol. 9, No. 2, pp. 4500906 [IF: 2.291, SJR: 0.725]
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  40. 146Baimuratov A.S., Gun’ko Y.K., Shalkovskiy A.G., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Optical activity of chiral nanoscrolls // Advanced Optical Materials - 2017, Vol. 5, No. 16, pp. 1600982 [IF: 6.875, SJR: 2.89]
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  41. 145Baimuratov A.S., Pereziabova T.P., Zhu .W., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Optical Anisotropy of Topologically Distorted Semiconductor Nanocrystals // Nano Letters - 2017, Vol. 17, No. 9, pp. 5514-5520 [IF: 12.712, SJR: 4.853]
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  42. 144Baimuratov A.S., Shlykov A.I., Zhu W., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Excitons in gyrotropic quantum-dot supercrystals // Optics Letters - 2017, Vol. 42, No. 13, pp. 2423-2426 [IF: 3.416, SJR: 1.524]
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  43. 143Baimuratov A.S., Tepliakov N.V., Gun’ko Y.K., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Erratum: Mixing of quantum states: A new route to creating optical activity (vol 6, pg 5, 2016) // Scientific Reports - 2017, Vol. 7, pp. 2781 [IF: 4.259, SJR: 1.24]
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  44. 142Baimuratov A.S., Tepliakov N.V., Gun’ko Y.K., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Optical Activity of Helical Quantum-Dot Supercrystals // Optics and spectroscopy - 2017, Vol. 122, No. 1, pp. 42-47 [IF: 0.716, SJR: 0.283]
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  45. 141Baimuratov A.S., Tepliakov N.V., Gun’ko Y.K., Shalkovskiy A.G., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Intraband optical activity of semiconductor nanocrystals // Chirality - 2017, Vol. 29, No. 5, pp. 159–166 [IF: 1.956, SJR: 0.43]
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  46. 140Kang M., Zhu .W., Rukhlenko I.D. Experimental observation of the topological structure of exceptional points in an ultrathin hybridized metamaterial // Physical Review A - 2017, Vol. 96, No. 6, pp. 063823 [IF: 2.925, SJR: 1.391]
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  47. 139Shlykov A.I., Baimuratov A.S., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Optically active quantum-dot molecules // Optics express - 2017, Vol. 25, No. 4, pp. 3811-3825 [IF: 3.307, SJR: 1.394]
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  48. 138Tepliakov N.V., Baimuratov A.S., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Analytical Study of Optical Activity of Chiral-Shape Nanocrystals // Proceedings of SPIE - 2017, Vol. 10114, pp. 1011418 [SJR: 0.192]
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  49. 137Tepliakov N.V., Baimuratov A.S., Gun’ko Y.K., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Optical Activity of Semiconductor Nanocrystals with Ionic Impurities // Optics and spectroscopy - 2017, Vol. 122, No. 1, pp. 64-68 [IF: 0.716, SJR: 0.283]
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  50. 136Tepliakov N.V., Baimuratov A.S., Vovk I.A., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Chiral Optical Properties of Tapered Semiconductor Nanoscrolls // ACS Nano - 2017, Vol. 11, No. 7, pp. 7508-7515 [IF: 13.942, SJR: 5.554]
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  51. 135Tepliakov N.V., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Absorption Properties of One- and Two-Dimensional Semiconductor Nanocrystals in the Presence of an Electric Field // Optics and spectroscopy - 2017, Vol. 122, No. 1, pp. 101-105 [IF: 0.716, SJR: 0.283]
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  52. 134Tepliakov N.V., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Optical absorption of semiconductor nanocrystals in strong electric fields // NANOCON 2016 - Conference Proceedings, 8th International Conference on Nanomaterials - Research and Application - 2017, pp. 195-200 [SJR: 0.101]
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  53. 133Turkov V.K., Rukhlenko I.D., Baranov A.V., Fedorov A.V. Excitonic energy bands formation in Quantum dot supercrystals // NANOCON 2016 - Conference Proceedings, 8th International Conference on Nanomaterials - Research and Application - 2017, pp. 64-68 [SJR: 0.101]
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  54. 132Vovk I.A., Baimuratov A.S., Zhu .W., Shalkovskiy A.G., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Chiral nanoparticles in singular light fields // Scientific Reports - 2017, Vol. 7, pp. 45925 [IF: 4.259, SJR: 1.24]
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  55. 131Vovk I.A., Tepliakov N.V., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Analytical theory of real-argument Laguerre–Gaussian beams beyond the paraxial approximation // Journal of the Optical Society of America A: Optics and Image Science, and Vision - 2017, Vol. 34, No. 10, pp. 1940-1944 [IF: 1.621, SJR: 0.803]
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  56. 130Zhu W., Rukhlenko I.D., Xiao F., He C., Geng J., Liang X., Premaratne M., Jin R. Multiband coherent perfect absorption in a water-based metasurface // Optics express - 2017, Vol. 25, No. 14, pp. 15737-15745 [IF: 3.307, SJR: 1.394]
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  57. 129Zhu W., Xiao F., Rukhlenko I.D., Geng J., Liang X., Premaratne M., Jin R. Wideband visible-light absorption in an ultrathin silicon nanostructure // Optics express - 2017, Vol. 25, No. 5, pp. 5781-5786 [IF: 3.307, SJR: 1.394]
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  58. 128Баймуратов А.С., Тепляков Н.В., Гунько Ю.К., Баранов А.В., Федоров А.В., Рухленко И.Д. Оптическая активность винтовых суперкристаллов из квантовых точек // Оптика и спектроскопия - 2017. - Т. 122. - № 1. - С. 48-53 [IF: 0.484]
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  59. 127Вовк И.А., Баймуратов А.С., Баранов А.В., Федоров А.В., Рухленко И.Д. Взаимодействие хиральных наночастиц с электромагнитным полем пучков Лагерра – Гаусса // Сборник трудов X Международной конференции молодых ученых и специалистов «Оптика-2017» (16-20октября 2017г.) - 2017. - С. 536-537
  60. 126Тепляков Н.В., Баймуратов А.С., Гунько Ю.К., Баранов А.В., Федоров А.В., Рухленко И.Д. Оптическая активность полупроводниковых нанокристаллов с ионными примесями // Оптика и спектроскопия - 2017. - Т. 122. - № 1. - С. 71-75 [IF: 0.484]
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  61. 125Тепляков Н.В., Леонов М.Ю., Баранов А.В., Федоров А.В., Рухленко И.Д. Поглощательные свойства одно- и двумерных полупроводниковых нанокристаллов в электрическом поле // Оптика и спектроскопия - 2017. - Т. 122. - № 1. - С. 111–116 [IF: 0.484]
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  62. 124Baimuratov A.S., Gun’ko Y.K., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Chiral quantum supercrystals with total dissymmetry of optical response // Scientific Reports - 2016, Vol. 6, pp. 23321 [IF: 4.259, SJR: 1.24]
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  63. 123Baimuratov A.S., Tepliakov N.V., Gun’ko Y.K., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Mixing of quantum states: A new route to creating optical activity // Scientific Reports - 2016, Vol. 6, pp. 5 [IF: 4.259, SJR: 1.24]
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  64. 122Hajian H., Rukhlenko I.D., Leung P.T., Caglayan H., Ozbay E. Guided Plasmon Modes of a Graphene-Coated Kerr Slab // Plasmonics - 2016, Vol. 11, No. 3, pp. 735-741 [IF: 2.139, SJR: 0.526]
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  65. 121Mukhina M.V., Baimuratov A.S., Rukhlenko I.D., Maslov V.G., Finn P.M., Gun’ko Y.K., Baranov A.V., Fedorov A.V. Circular Dichroism of Electric-Field-Oriented CdSe/CdS Quantum Dots-in-Rods // ACS Nano - 2016, Vol. 10, No. 9, pp. 8904–8909 [IF: 13.942, SJR: 5.554]
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  66. 120Rukhlenko I.D., Baimuratov A.S., Tepliakov N.V., Baranov A.V., Fedorov A.V. Shape-induced optical activity of chiral nanocrystals // Optics Letters - 2016, Vol. 41, No. 11, pp. 2438-2441 [IF: 3.416, SJR: 1.524]
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  67. 119Rukhlenko I.D., Tepliakov N.V., Baimuratov A.S., Andronaki S.A., Gun'Ko Y.K., Baranov A.V., Fedorov A.V. Completely chiral optical force for enantioseparation // Scientific Reports - 2016, Vol. 6, pp. 36884 [IF: 4.259, SJR: 1.24]
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  68. 118Tepliakov N.V., Baimuratov A.S., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Optical Activity of Chirally Distorted Nanocrystals // Journal of Applied Physics - 2016, Vol. 119, No. 19, pp. 194302 [IF: 2.068, SJR: 0.699]
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  69. 117Tepliakov N.V., Baimuratov A.S., Gun'Ko Y.K., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Engineering Optical Activity of Semiconductor Nanocrystals via Ion Doping // Nanophotonics - 2016, Vol. 5, No. 4, pp. 573-578 [IF: 4.492, SJR: 2.717]
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  70. 116Tepliakov N.V., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Quantum theory of electroabsorption in semiconductor nanocrystals // Optics express - 2016, Vol. 24, No. 2, pp. A52-A57 [IF: 3.307, SJR: 1.394]
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  71. 115Tepliakov N.V., Ponomareva I.O., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Field-Induced Broadening of Electroabsorption Spectra of Semiconductor Nanorods and Nanoplatelets // Journal of Physical Chemistry C - 2016, Vol. 120, No. 4, pp. 2379–2385 [IF: 4.536, SJR: 1.401]
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  72. 114Baimuratov A.S., Rukhlenko I.D., Gun’ko Y.K., Baranov A.V., Fedorov A.V. Dislocation-Induced Chirality of Semiconductor Nanocrystals // Nano Letters - 2015, Vol. 15, No. 3, pp. 1710–1715 [IF: 12.712, SJR: 4.853]
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  73. 113Baimuratov A.S., Rukhlenko I.D., Noskov R.E., Ginzburg P.B., Gun’ko Y.K., Baranov A.V., Fedorov A.V. Giant Optical Activity of Quantum Dots, Rods, and Disks with Screw Dislocations // Scientific Reports - 2015, Vol. 5, pp. 14712 [IF: 4.259, SJR: 1.24]
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  74. 112Kruchinin S.Y., Rukhlenko I.D., Baimuratov A.S., Leonov M.Y., Turkov V.K., Gun’ko Y.K., Baranov A.V., Fedorov A.V. Photoluminescence of a quantum-dot molecule // Journal of Applied Physics - 2015, Vol. 117, No. 1, pp. 014306-(1-7) [IF: 2.068, SJR: 0.699]
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  75. 111Ponomareva I.O., Leonov M.Y., Kosenkov A.G., Rukhlenko I.D. Electroabsorption of a semiconductor nanocuboid // Journal of Optical Technology - 2015, Vol. 82, No. 11, pp. 749-754 [IF: 0.299, SJR: 0.219]
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  76. 110Turkov V.K., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Radiative decay rates of impurity states in semiconductor nanocrystals // AIP Advances - 2015, Vol. 5, No. 10, pp. 107126 [IF: 1.568, SJR: 0.421]
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  77. 109Turkov V.K., Kruchinin S.Y., Rukhlenko I.D., Baimuratov A.S., Leonov M.Y., Gun’ko Y.K., Baranov A.V., Fedorov A.V. A theory of low-temperature stationary photoluminescence of a quantum-dot molecule // NANOCON 2014, 6TH INTERNATIONAL CONFERENCE - 2015, pp. 146-151
  78. 108Turkov V.K., Leonov M.Y., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Optical transitions in a complex valence band of semiconductor nanocrystals // Journal of Optical Technology - 2015, Vol. 82, No. 11, pp. 743-748 [IF: 0.299, SJR: 0.219]
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  79. 107Zhu W., Rukhlenko I.D., Noskov R.E., Jin R., Zhou J. Recent Advances in Theory and Applications of Electromagnetic Metamaterials // International Journal of Antennas and Propagation - 2015, Vol. 2015, pp. 982325 [IF: 1.164, SJR: 0.282]
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  80. 106Пономарева И.О., Леонов М.Ю., Косенков А.Г., Рухленко И.Д., Баранов А.В., Федоров А.В. Электропоглощение полупроводникового нанокубоида // Оптический журнал - 2015. - Т. 82. - № 11. - С. 43-49
  81. 105Турков В.К., Леонов М.Ю., Рухленко И.Д., Баранов А.В., Федоров А.В. Оптические переходы в сложной валентной зоне полупроводниковых нанокристаллов // Оптический журнал - 2015. - Т. 82. - № 11. - С. 36-42
  82. 104Achtstein A.V., Prudnikau A.V., Ermolenko M.V., Gurinovich L.I., Gaponenko S.V., Woggon U., Baranov A.V., Leonov M.Y., Rukhlenko I.D., Fedorov A.V., Artemyev M.V. Electroabsorption by 0D, 1D, and 2D Nanocrystals: A Comparative Study of CdSe Colloidal Quantum Dots, Nanorods, and Nanoplatelets // ACS Nano - 2014, Vol. 8, No. 8, pp. 7678–7686 [IF: 13.942, SJR: 5.554]
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  83. 103Baimuratov A.S., Rukhlenko I.D., Leonov M.Y., Shalkovskiy A.G., Baranov A.V., Fedorov A.V. Phonon-assisted photoluminescence from a semiconductor quantum dot with resonant electron and phonon subsystems // Optics express - 2014, Vol. 22, No. 16, pp. 19707-19725 [IF: 3.307, SJR: 1.394]
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  84. 102Baimuratov A.S., Rukhlenko I.D., Turkov V.K., Leonov M.Y., Baranov A.V., Gun’ko Y.K., Fedorov A.V. Harnessing the shape-induced optical anisotropy of a semiconductor nanocrystal: A new type of intraband absorption spectroscopy // Journal of Physical Chemistry C - 2014, Vol. 118, No. 5, pp. 2867–2876 [IF: 4.536, SJR: 1.401]
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  85. 101Baimuratov A.S., Rukhlenko I.D., Turkov V.K., Ponomareva I.O., Leonov M.Y., Perova T.S., Berwick K., Baranov A.V., Fedorov A.V. Level Anticrossing of Impurity States in Semiconductor Nanocrystals // Scientific Reports - 2014, Vol. 4, pp. 6917-(1-6) [IF: 4.259, SJR: 1.24]
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  86. 100Baimuratov A.S., Turkov V.K., Leonov M.Y., Gun’ko Y.K., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Phonon-induced photoluminescence from a single quantum dot in the regime vibrational resonance // Laser Optics, 2014 International Conference - 2014, pp. 6886382
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  87. 99Leonov M.Y., Baimuratov A.S., Baranov A.V., Fedorov A.V., Rukhlenko I.D. Transient photoluminescence from semiconductor nanodumbbells // Laser Optics, 2014 International Conference - 2014, pp. 6886380
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  88. 98Leonov M.Y., Rukhlenko I.D., Baimuratov A.S., Baranov A.V., Gun’ko Y.K., Fedorov A.V. Transient pump–probe absorption spectroscopy of semiconductor nanodumbbells // Proceedings of SPIE - 2014, Vol. 9126, pp. 91262C-(1-8) [SJR: 0.192]
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  89. 97Reddy M.S., Vijaya R., Rukhlenko I.D., Premaratne M. Low-threshold lasing in photonic-crystal heterostructures // Optics express - 2014, Vol. 22, No. 6, pp. 6229-6238 [IF: 3.307, SJR: 1.394]
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  90. 96Rukhlenko I.D. Modeling nonlinear optical phenomena in silicon-nanocrystal composites and waveguides // Journal of Optics - 2014, Vol. 16, No. 1, pp. 015207-(1-11) [IF: 1.741]
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  91. 95Rukhlenko I.D. Optical propagation through graded-index metamaterials in the presence of gain // Plasmonics - 2014, Vol. 9, No. 6, pp. 1257-1263 [IF: 2.139, SJR: 0.526]
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  92. 94Rukhlenko I.D., Kalavally V. Raman amplification in silicon-nanocrystal waveguides // Journal of Lightwave Technology - 2014, Vol. 32, No. 1, pp. 130-134 [IF: 3.671, SJR: 1.346]
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  93. 93Rupasinghe C., Rukhlenko I.D., Premaratne M. Spaser made of graphene and carbon nanotubes // ACS Nano - 2014, Vol. 8, No. 3, pp. 2431-2438 [IF: 13.942, SJR: 5.554]
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  94. 92Sikdar D., Rukhlenko I.D., Cheng W., Premaratne M. Tunable broadband optical responses of substrate-supported metal/dielectric/metal nanospheres // Plasmonics - 2014, Vol. 9, No. 3, pp. 659-672 [IF: 2.139, SJR: 0.526]
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  95. 91Zhu W., Rukhlenko I.D., Xiao F., Premaratne M. Polarization conversion in U-shaped chiral metamaterial with four-fold symmetry breaking // Journal of Applied Physics - 2014, Vol. 115, No. 14, pp. 143101-(1-4) [IF: 2.068, SJR: 0.699]
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  96. 90Baimuratov A.S., Rukhlenko I.D., Fedorov A.V. Engineering band structure in nanoscale quantum-dot supercrystals // Optics Letters - 2013, Vol. 38, No. 13, pp. 2259-2261 [IF: 3.416, SJR: 1.524]
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  97. 89Baimuratov A.S., Rukhlenko I.D., Turkov V.K., Baranov A.V., Fedorov A.V. Quantum-dot supercrystals for future nanophotonics // Scientific Reports - 2013, Vol. 3, pp. 1727-(1-9) [IF: 4.259, SJR: 1.24]
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  98. 88Handapangoda D., Rukhlenko I.D., Premaratne M. Analytical study of optimal design and gain parameters of double-slot plasmonic waveguides // Journal of Optics - 2013, Vol. 15, No. 3, pp. 035006 [IF: 1.741]
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  99. 87Leonov M.Y., Orlova A.O., Baranov A.V., Fedorov A.V., Rukhlenko I.D., Gun’ko Y.K. Transient intraband absorption of light by semiconductor nanorods // Journal of Optical Technology - 2013, Vol. 80, No. 11, pp. 648–654 [IF: 0.299, SJR: 0.219]
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  100. 86Litvin A.P., Parfenov P.S., Ushakova E.V., Fedorov A.V., Artemyev M.V., Prudnikau A.V., Rukhlenko I.D., Baranov A.V. Optical properties and aging of PbS quantum dots embedded in a porous matrix // Proceedings of SPIE - 2013, Vol. 8807, pp. 88070T-(1-7) [SJR: 0.192]
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  101. 85Reddy M.S., Kedia S., Vijaya R., Ray A.K., Sinha S., Rukhlenko I.D., Premaratne M. Analysis of Lasing in Dye-Doped Photonic Crystals // IEEE Photonics Journal - 2013, Vol. 5, No. 1, pp. 4700409 [IF: 2.291, SJR: 0.725]
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  102. 84Reddy M.S., Vijaya R., Rukhlenko I.D., Premaratne M. Low-threshold lasing in active opal photonic crystals // Optics Letters - 2013, Vol. 38, No. 7, pp. 1046-1048 [IF: 3.416, SJR: 1.524]
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  103. 83Rukhlenko I.D. Theory of nonlinear pulse propagation in silicon-nanocrystal waveguides // Optics express - 2013, Vol. 21, No. 3, pp. 2832–2846 [IF: 3.307, SJR: 1.394]
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  104. 82Rukhlenko I.D., Kalavally V., Zhu W., Premaratne M. Engineering optical nonlinearities in silicon-nanocrystal waveguides // Journal of the Optical Society of America B: Optical Physics - 2013, Vol. 30, No. 12, pp. 3145-3150 [IF: 1.843, SJR: 0.741]
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  105. 81Rupasinghe C., Rukhlenko I.D., Premaratne M. Design optimization of spasers considering the degeneracy of excited plasmon modes // Optics express - 2013, Vol. 21, No. 13, pp. 15335–15349 [IF: 3.307, SJR: 1.394]
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  106. 80Sikdar D., Rukhlenko I.D., Cheng W., Premaratne M. Effect of number density on optimal design of gold nanoshells for plasmonic photothermal therapy // Biomedical Optics Express - 2013, Vol. 4, No. 1, pp. 15-31 [IF: 3.337, SJR: 1.362]
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  107. 79Sikdar D., Rukhlenko I.D., Cheng W., Premaratne M. Optimized gold nanoshell ensembles for biomedical applications // Nanoscale Research Letters - 2013, Vol. 8, pp. 142 [IF: 2.833, SJR: 0.87]
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  108. 78Sikdar D., Rukhlenko I.D., Cheng W., Premaratne M. Unveiling ultrasharp scattering-switching signatures of layered gold-dielectric-gold nanospheres // Journal of the Optical Society of America B: Optical Physics - 2013, Vol. 30, No. 8, pp. 2066-2074 [IF: 1.843, SJR: 0.741]
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  109. 77Turkov V.K., Baimuratov A.S., Rukhlenko I.D., Baranov A.V., Fedorov A.V. Spectroscopy of intraband optical transitions in an anisotropic semiconductor nanocrystals // Proceedings of SPIE - 2013, Vol. 8807, pp. 88070U-(1-9) [SJR: 0.192]
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  110. 76Xiong W., Sikdar D., Walsh M., Si K.J., Tang Y., Chen Y., Mazid R., Weyland M., Rukhlenko I.D., Etheridge J., Premaratne M., Li X., Cheng W. Single-crystal caged gold nanorods with tunable broadband plasmon resonances // Chemical Communications - 2013, Vol. 49, No. 83, pp. 9630–9632 [IF: 6.319, SJR: 1.837]
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  111. 75Zhu W., Rukhlenko I.D., Huang Y., Wen G., Premaratne M. Wideband giant optical activity and negligible circular dichroism of near-infrared chiral metamaterial based on a complementary twisted configuration // Journal of Optics - 2013, Vol. 15, No. 12, pp. 125101 [IF: 1.741]
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  112. 74Zhu W., Rukhlenko I.D., Premaratne M. Application of zero-index metamaterials for surface plasmon guiding // Applied Physics Letters - 2013, Vol. 102, No. 1, pp. 011910 [IF: 3.411, SJR: 1.182]
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  113. 73Zhu W., Rukhlenko I.D., Premaratne M. Graphene metamaterial for optical reflection modulation // Applied Physics Letters - 2013, Vol. 102, No. 24, pp. 241914 [IF: 3.411, SJR: 1.182]
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  114. 72Zhu W., Rukhlenko I.D., Si L., Premaratne M. Graphene-enabled tunability of optical fishnet metamaterial // Applied Physics Letters - 2013, Vol. 102, No. 12, pp. 121911 [IF: 3.411, SJR: 1.182]
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  115. 71Леонов М.Ю., Орлова А.О., Баранов А.В., Рухленко И.Д., Гунько Ю.К., Федоров А.В. Нестационарное внутризонное поглощение света полупроводниковыми наностержнями // Оптический журнал - 2013. - Т. 80. - № 11. - С. 7-15
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  116. 70Baimuratov A.S., Rukhlenko I.D., Baranov A.V., Fedorov A.V. Phonon-assisted secondary emission from a semiconductor quantum dot in the regime of vibrational resonance // Proceedings of SPIE - 2012, Vol. 8564, pp. 85640A-(1-6) [SJR: 0.192]
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  117. 69Baimuratov A.S., Turkov V.K., Rukhlenko I.D., Fedorov A.V. Shape-induced anisotropy of intraband luminescence from a semiconductor nanocrystal // Optics Letters - 2012, Vol. 37, No. 22, pp. 4645-4647 [IF: 3.416, SJR: 1.524]
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  118. 68Handapangoda D., Rukhlenko I.D., Premaratne M. Optimizing the design of planar heterostructures for plasmonic waveguiding // Journal of the Optical Society of America B - 2012, Vol. 29, No. 4, pp. 553–558 [IF: 1.843, SJR: 0.741]
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  119. 67Kalavally V., Rukhlenko I.D., Premaratne M. Combined Effect of ASE and DRBS on Noise in Pulse-Pumped Fiber Raman Amplifiers // Journal of Lightwave Technology - 2012, Vol. 30, No. 18, pp. 2983–2987 [IF: 3.671, SJR: 1.346]
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  120. 66Leonov M.Y., Turkov V.K., Rukhlenko I.D., Fedorov A.V. Kinetics of thermalized luminescence of a single quantum dot at room temperature // Optics and spectroscopy - 2012, Vol. 113, No. 3, pp. 259-264 [IF: 0.716, SJR: 0.283]
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  121. 65Litvin A.P., Parfenov P.S., Ushakova E.V., Fedorov A.V., Artemyev M.V., Prudnikau A.V., Cherevkov S.A., Rukhlenko I.D., Baranov A.V. Size-dependent room-temperature luminescence decay from PbS quantum dots // Proceedings of SPIE - 2012, Vol. 8564, pp. 85641Z-(1-7) [SJR: 0.192]
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  122. 64Ng K.C., Udagedara I.B., Rukhlenko I.D., Chen Y., Tang Y., Premaratne M. Free-standing plasmonic-nanorod superlattice sheets // ACS Nano - 2012, Vol. 6, No. 1, pp. 925–934 [IF: 13.942, SJR: 5.554]
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  123. 63Reddy M.S., Vijaya R., Rukhlenko I.D., Premaratne M. Spatial and spectral distributions of emission from dye-doped photonic crystals in reflection and transmission geometries // Journal of Nanophotonics - 2012, Vol. 6, No. 1, pp. 063526 [IF: 1.325, SJR: 0.323]
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  124. 62Rukhlenko I.D., Belov P.A., Litchinitser N.M., Boltasseva A.E. Modern Trends in Metamaterial Applications // Advances in OptoElectronics - 2012, Vol. 2012, pp. 514270 [SJR: 0.118]
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  125. 61Rukhlenko I.D., Leonov M.Y., Turkov V.K., Litvin A.P., Baimuratov A.S., Baranov A.V., Fedorov A.V. Kinetics of pulse-induced photoluminescence from a semiconductor quantum dot // Optics express - 2012, Vol. 20, No. 25, pp. 27612-27635 [IF: 3.307, SJR: 1.394]
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  126. 60Rukhlenko I.D., Premaratne M. Optimization of nonlinear performance of silicon-nanocrystal cylindrical nanowires // IEEE Photonics Journal - 2012, Vol. 4, No. 3, pp. 952–959 [IF: 2.291, SJR: 0.725]
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  127. 59Rukhlenko I.D., Premaratne M., Agrawal G.P. Effective mode area and its optimization in silicon-nanocrystal waveguides // Optics Letters - 2012, Vol. 37, No. 12, pp. 2295–2297 [IF: 3.416, SJR: 1.524]
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  128. 58Rukhlenko I.D., Premaratne M., Agrawal G.P. Effective third-order susceptibility of silicon-nanocrystal-doped silica // Optics express - 2012, Vol. 20, No. 24, pp. 26275–26284 [IF: 3.307, SJR: 1.394]
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  129. 57Rukhlenko I.D., Premaratne M., Agrawal G.P. Guided plasmonic modes of anisotropic slot waveguides // Nanotechnology - 2012, Vol. 23, No. 44, pp. 444006 [IF: 3.44, SJR: 0.926]
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  130. 56Rukhlenko I.D., Premaratne M., Agrawal G.P. Plasmonic Modes of Metamaterial-Based Slot Waveguides // Advances in OptoElectronics - 2012, Vol. 2012, pp. 907183 [SJR: 0.118]
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  131. 55Turkov V.K., Leonov M.Y., Rukhlenko I.D., Fedorov A.V. Pauli equation for semiconductor quantum dot photoluminescence kinetics investigation // Proceedings of SPIE - 2012, Vol. 8564, pp. 85641Y-(1-7) [SJR: 0.192]
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  132. 54Ushakova E.V., Litvin A.P., Parfenov P.S., Fedorov A.V., Artemyev M.V., Prudnikau A.V., Rukhlenko I.D., Baranov A.V. Anomalous Size-Dependent Decay of Low-Energy Luminescence from PbS Quantum Dots in Colloidal Solution // ACS Nano - 2012, Vol. 6, No. 10, pp. 8913 - 8921 [IF: 13.942, SJR: 5.554]
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  133. 53Zhu W., Rukhlenko I.D., Premaratne M. Light amplification in zero-index metamaterial with gain inserts // Applied Physics Letters - 2012, Vol. 101, No. 3, pp. 031907 [IF: 3.411, SJR: 1.182]
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  134. 52Zhu W., Rukhlenko I.D., Premaratne M. Linear transformation optics for plasmonics // Journal of the Optical Society of America B - 2012, Vol. 29, No. 10, pp. 2659–2664 [IF: 1.843, SJR: 0.741]
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  135. 51Zhu W., Rukhlenko I.D., Premaratne M. Maneuvering propagation of surface plasmon polaritons using complementary medium inserts // IEEE Photonics Journal - 2012, Vol. 4, No. 3, pp. 741–747 [IF: 2.291, SJR: 0.725]
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  136. 50Zhu W., Rukhlenko I.D., Premaratne M. Manipulating energy flow in variable-gap plasmonic waveguides // Optics Letters - 2012, Vol. 37, No. 24, pp. 5151–5153 [IF: 3.416, SJR: 1.524]
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  137. 49Zhu W., Rukhlenko I.D., Wen G., Premaratne M. Configurable metamaterial absorber with pseudo wideband spectrum // Optics express - 2012, Vol. 20, No. 6, pp. 6616–6621 [IF: 3.307, SJR: 1.394]
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  138. 48Леонов М.Ю., Турков В.К., Рухленко И.Д., Федоров А.В. Кинетика резонансной люминесценции одиночной квантовой точки при комнатной температуре // Оптика и спектроскопия - 2012. - Т. 113. - № 3. - С. 295-300 [IF: 0.484]
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  140. 46Dissanayake C.M., Rukhlenko I.D., Premaratne M., Agrawal G.P. Polarization-dependent spectral broadening of femtosecond pulses in silicon waveguides // Journal of the Optical Society of America B - 2011, Vol. 28, No. 10, pp. 2383–2389
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  141. 45Handapangoda D., Premaratne M., Rukhlenko I.D., Jagadish C. Optimal design of composite nanowires for extended reach of surface plasmon-polaritons // Optics Express - 2011, Vol. 19, No. 17, pp. 16058–16074 [SJR: 1.394]
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  142. 44Pannipitiya A., Rukhlenko I.D., Premaratne M. Analytical modeling of resonant cavities for plasmonic-slot-waveguide junctions // IEEE Photonics Journal - 2011, Vol. 3, No. 2, pp. 220–233 [IF: 2.291, SJR: 0.725]
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  143. 43Pannipitiya A., Rukhlenko I.D., Premaratne M. Analytical theory of optical bistability in plasmonic nanoresonators // Journal of the Optical Society of America B - 2011, Vol. 28, No. 11, pp. 2820–2826
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  144. 42Rukhlenko I.D., Fedorov A.V., Baimuratov A.S., Premaratne M. Theory of quasi-elastic secondary emission from a quantum dot in the regime of vibrational resonance // Optics express - 2011, Vol. 19, No. 16, pp. 15459–15482 [IF: 3.307, SJR: 1.394]
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  145. 41Rukhlenko I.D., Pannipitiya A., Premaratne M. Dispersion relation for surface plasmon-polaritons in metal/nonlinear-dielectric/metal slot waveguides // Optics Letters - 2011, Vol. 36, No. 17, pp. 3374–3376 [IF: 3.416, SJR: 1.524]
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  146. 40Rukhlenko I.D., Pannipitiya A., Premaratne M., Agrawal G.P. Exact dispersion relation for nonlinear plasmonic waveguides // Physical Review B - 2011, Vol. 84, No. 11, pp. 113409 [IF: 3.836, SJR: 1.78]
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  147. 39Rukhlenko I.D., Premaratne M., Agrawal G.P. Maximization of gain in slow-light silicon Raman amplifiers // International Journal of Optics - 2011, Vol. 2011, pp. 581810 [SJR: 0.263]
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  148. 38Rukhlenko I.D., Premaratne M., Agrawal G.P. Nonlinear propagation in silicon-based plasmonic waveguides from the standpoint of applications // Optics express - 2011, Vol. 19, No. 1, pp. 206–217 [IF: 3.307, SJR: 1.394]
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  149. 37Udagedara I.B., Rukhlenko I.D., Premaratne M. Complex-w approach versus complex-k approach in description of gain-assisted SPP propagation along linear chains of metallic nanospheres // Physical Review B - 2011, Vol. 83, No. 11, pp. 115451 [IF: 3.836, SJR: 1.78]
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  150. 36Udagedara I.B., Rukhlenko I.D., Premaratne M. Surface plasmon-polariton propagation in piecewise linear chains of composite nanospheres: The role of optical gain and chain layout // Optics express - 2011, Vol. 19, No. 21, pp. 19973–19986 [IF: 3.307, SJR: 1.394]
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  151. 35Dissanayake C.M., Premaratne M., Rukhlenko I.D., Agrawal G.P. FDTD modeling of anisotropic nonlinear optical phenomena in silicon waveguides // Optics Express - 2010, Vol. 18, No. 20, pp. 21427–21448 [SJR: 1.394]
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  152. 34Handapangoda D., Rukhlenko I.D., Premaratne M., Jagadish C. Optimization of gain-assisted waveguiding in metal-dielectric nanowires // Optics Letters - 2010, Vol. 35, No. 24, pp. 4190–4192 [IF: 3.416, SJR: 1.524]
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  153. 33Kalavally V., Rukhlenko I.D., Premaratne M., Win T. Multipath interference in pulse-pumped fiber Raman amplifiers: Analytical approach // IEEE Journal of Lightwave Technology - 2010, Vol. 28, No. 18, pp. 2701–2707
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  154. 32Pannipitiya A., Rukhlenko I.D., Premaratne M., Hattori H.T., Agrawal G.P. Improved transmission model for metal-dielectric-metal plasmonic waveguides with stub structure // Optics Express - 2010, Vol. 18, No. 6, pp. 6191–6204 [SJR: 1.394]
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  155. 31Rukhlenko I.D., Dissanayake C., Premaratne M. Visualization of electromagnetic-wave polarization evolution using the Poincare sphere // Optics Letters - 2010, Vol. 35, No. 13, pp. 2221–2223 [IF: 3.416, SJR: 1.524]
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  156. 30Rukhlenko I.D., Dissanayake C., Premaratne M., Agrawal G.P. Optimization of Raman amplification in silicon waveguides with finite facet reflectivities // IEEE Journal on Selected Topics in Quantum Electronics - 2010, Vol. 16, No. 1, pp. 226–233 [SJR: 1.131]
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  157. 29Rukhlenko I.D., Garanovich I.L., Premaratne M., Sukhorukov A.A., Agrawal G.P., Kivshar Y.S. Polarization rotation in silicon waveguides: Analytical modeling and applications // IEEE Photonics Journal - 2010, Vol. 2, No. 3, pp. 423–435 [IF: 2.291, SJR: 0.725]
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  158. 28Rukhlenko I.D., Premaratne M. Spectral compression and group delay of optical pulses in silicon Raman amplifiers // Optics Letters - 2010, Vol. 35, No. 18, pp. 3138–3140 [IF: 3.416, SJR: 1.524]
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  159. 27Rukhlenko I.D., Premaratne M., Agrawal G.P. Analytical study of optical bistability in silicon ring resonators // Optics Letters - 2010, Vol. 35, No. 1, pp. 55–57 [IF: 3.416, SJR: 1.524]
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  160. 26Rukhlenko I.D., Premaratne M., Agrawal G.P. Nonlinear silicon photonics: Analytical tools // IEEE Journal of Selected Topics in Quantum Electronics - 2010, Vol. 16, No. 1, pp. 200–215 [IF: 3.971, SJR: 1.131]
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  161. 25Rukhlenko I.D., Premaratne M., Agrawal G.P. Theory of negative refraction in periodic stratified metamaterials // Optics Express - 2010, Vol. 18, No. 26, pp. 27916–27929 [SJR: 1.394]
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  162. 24Rukhlenko I.D., Premaratne M., Garanovich I.L., Sukhorukov A.A., Agrawal G.P. Analytical study of pulse amplification in silicon Raman amplifiers // Optics express - 2010, Vol. 18, No. 17, pp. 18324–18338 [IF: 3.307, SJR: 1.394]
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  163. 23Rukhlenko I.D., Udagedara I.B., Premaratne M., Agrawal G.P. Effect of free carriers on pump-to-signal noise transfer in silicon Raman amplifiers // Optics Letters - 2010, Vol. 35, No. 14, pp. 2343–2345 [IF: 3.416, SJR: 1.524]
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  164. 22Dissanayake C.M., Rukhlenko I.D., Premaratne M., Agrawal G.P. Raman-mediated nonlinear interactions in silicon waveguides: Copropagating and counterpropagating pulses // IEEE Photonics Technology Letters - 2009, Vol. 21, No. 19, pp. 1372–1374 [IF: 2.375, SJR: 0.81]
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  165. 21Hattori H.T., Li Z., Liu D., Rukhlenko I.D., Premaratne M. Coupling of light from microdisk lasers into plasmonic nano-antennas // Optics Express - 2009, Vol. 17, No. 23, pp. 20878–20884 [SJR: 1.394]
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  166. 20Kalavally V., Rukhlenko I.D., Premaratne M. Analytical study of RIN transfer in pulse-pumped Raman amplifiers // Journal of Lightwave Technology - 2009, Vol. 27, No. 20, pp. 4536-4543 [IF: 3.671, SJR: 1.346]
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  167. 19Rukhlenko I.D., Dissanayake C., Premaratne M., Agrawal G.P. Maximization of net optical gain in silicon-waveguide Raman amplifiers // Optics Express - 2009, Vol. 17, No. 7, pp. 5807–5814 [SJR: 1.394]
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  168. 18Rukhlenko I.D., Premaratne M., Agrawal G.P. Analytical study of optical bistability in silicon-waveguide resonators // Optics Express - 2009, Vol. 17, No. 24, pp. 22124–22137 [SJR: 1.394]
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  169. 17Rukhlenko I.D., Premaratne M., Dissanayake C., Agrawal G.P. Continuous-wave Raman amplification in silicon waveguides: Beyond the undepleted pump approximation // Optics Letters - 2009, Vol. 34, No. 4, pp. 536–538 [IF: 3.416, SJR: 1.524]
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  170. 16Rukhlenko I.D., Premaratne M., Dissanayake C., Agrawal G.P. Nonlinear pulse evolution in silicon waveguides: An approximate analytic approach // Journal of Lightwave Technology - 2009, Vol. 27, No. 15, pp. 3241–3248 [IF: 3.671, SJR: 1.346]
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  171. 15Udagedara I., Premaratne M., Rukhlenko I.D., Hattori H.T., Agrawal G.P. Unified perfectly matched layer for finite-difference time-domain modeling of dispersive optical materials // Optics Express - 2009, Vol. 17, No. 23, pp. 21179–21190 [SJR: 1.394]
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  172. 14Rukhlenko I.D., Fedorov A.V., Baranov A.V., Perova T.S., Berwick K. Tip-enhanced secondary emission of a semiconductor quantum dot // Physical Review B - 2008, Vol. 77, No. 4, pp. 045331 [IF: 3.836, SJR: 1.78]
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  173. 13Fedorov A.V., Baranov A.V., Rukhlenko I.D., Perova T.S., Berwick K. Quantum dot energy relaxation mediated by plasmon emission in doped covalent semiconductor heterostructures // Physical Review B - 2007, Vol. 4, pp. 045332 [IF: 3.836, SJR: 1.78]
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  174. 12Fedorov A.V., Rukhlenko I.D. Study of electronic dynamics of quantum dots using resonant photoluminescence technique // Optics and Spectroscopy - 2006, Vol. 100, No. 5, pp. 716–723 [SJR: 0.283]
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  175. 11Rukhlenko I.D. Carrier relaxation in quantum dots involving bulk plasmon modes of doped components of heterostructures // Scientific and Technical Bulletin of SPSU ITMO - 2006, Vol. 26, pp. 362–372
  176. 10Rukhlenko I.D., Fedorov A.V. Penetration of electric fields induced by surface phonon modes into the layers of a semiconductor heterostructure // Optics and Spectroscopy - 2006, Vol. 101, No. 2, pp. 253–264 [SJR: 0.283]
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  177. 9Rukhlenko I.D., Fedorov A.V. Propagation of electric fields induced by optical phonons in semiconductor heterostructures // Optics and Spectroscopy - 2006, Vol. 100, No. 2, pp. 238–244 [SJR: 0.283]
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  178. 8Rukhlenko I.D., Fedorov A.V. Resonant photoluminescence of quantum dots: Dynamics of electron subsystem // Bulletin of the Russian Academy of Sciences: Physics - 2006, Vol. 70, No. 1, pp. 126–129 [SJR: 0.226]
  179. 7Рухленко И.Д. Распространение индуцированных оптическими фононами электрических полей в полупроводниковых гетероструктурах. Опт. и спектр. // Оптика и спектроскопия - 2006. - Т. 100. - № 1. - С. 274-281
  180. 6Рухленко И.Д., Федоров А.В. Резонансная фотолюминесценция квантовых точек: Динамика электронной подсистемы // Известия РАН. Серия физическая - 2006. - Т. 70. - № 1. - С. 111-113
  181. 5Fedorov A.V., Baranov A.V., Rukhlenko I.D., Gaponenko S.V. Enhanced intraband carrier relaxation in quantum dots due to the effect of plasmon-LO-phonon density of states in doped heterostructures // Physical Review B - 2005, Vol. 71, No. 19, pp. 195310 [IF: 3.836, SJR: 1.78]
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  182. 4Baranov A.V., Fedorov A.V., Rukhlenko I.D., Masumoto Y. Intraband carrier relaxation in quantum dots embedded in doped heterostructures // Physical Review B - 2003, Vol. 68, No. 20, pp. 205318 [IF: 3.836, SJR: 1.78]
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  183. 3Baranov A.V., Fedorov A.V., Rukhlenko I.D., Masumoto Y. New mechanism of intraband carrier relaxation in quantum dots // Physica Status Solidi (c) Current Topics in Solid State Physics - 2003, No. 4, pp. 1217–1220 [SJR: 0.28]
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  184. 2Fedorov A.V., Baranov A.V., Rukhlenko I.D., Masumoto Y. New many-body mechanism of intraband carrier relaxation in quantum dots embedded to doped heterostructures // Solid State Communications - 2003, Vol. 128, pp. 219–223 [IF: 1.554, SJR: 0.429]
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  185. 1Vinar I., Sudo S., Geraud A., Perin J.P., Manzagol J., Ladd P., Saksagansky G., Skoblikov S., Lukin A., Umov A., Reznichenko P., Khlopenkov K., Krasilnikov I., Rukhlenko I. Pellet injectors developed at the PELIN laboratory for international projects // Fusion Engineering and Design - 2001, Vol. 58–59, pp. 295–299 [SJR: 0.656]
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