2021 Присуждена учёная степень "Доктор физико-математических наук"
2003 Присуждена учёная степень "Кандидат физико-математических наук"
Образование
2022 Повышение квалификации: Самарский университет, Инклюзивное профессиональное образование
2022 Повышение квалификации: Самарский университет, Навыки оказания первой помощи
2021 Повышение квалификации: Самарский университет, Электронная информационно-образовательная среда университета
2018 Повышение квалификации: Самарский университет, Электронная информационно-образовательная среда университета
2018 Повышение квалификации: Самарский университет, "Навыки оказания первой помощи"
2018 Повышение квалификации: Самарский университет, "Инклюзивное профессиональное образование"
2010 Повышение квалификации: МГТУ им.Н.Э.Баумана
2009 Повышение квалификации: Нижегородский государственный университет им. Н.И.Лобачевского
1993 - 1999 Высшее: Самарский государственный аэрокосмический университет имени академика С.П.Королева, факультет Информатика
Scopus/WoS
2023
1Nesterenko D.V., Hayashi S., Soifer V.Fabry–Pérot Resonances in Planar Metal–Insulator–Metal Structures for Optical Data Processing: A Review // Physics of Wave Phenomena 2023. — Vol. 31. Issue 5. № 5. — P. 293-311
2Hayashi S., Sugimoto H., Fujii M. etc. Formation of Fano line shapes in optical responses and spectra of internal fields of excitonic nanospheres // PHYSICAL REVIEW B 2023. — Vol. 108. Issue 12. № 12.
2022
1Nesterenko D.V., Hayashi S., Soifer V.Ab initio spatial coupled-mode theory of Fano resonances in optical responses of multilayer interference resonators // Physical Review A 2022. — Vol. 106. Issue 2. № 2.
2Podlipnov V.V., Bykov D.A., Nesterenko D.V.Structural and optical properties of thin CdTe films in the visible and infrared regions // Computer Optics 2022. — Vol. 46. Issue 3. № 3. — P. 415-421
3Hayashi S., Motokura K., Fujii M. etc. Nested formation mechanisms of Fano line shape in far-field response of coupled waveguide multilayer structure revealed by analyses of local electric fields // Journal of Applied Physics 2022. — Vol. 132. Issue 16. № 16.
2021
1Pavelkin R.A., Hayashi S., Soifer V.A. etc. Anticrossing behavior of surface plasmon polaritons coupled with vibrational modes in planar plasmon structures // Proceedings of ITNT 2021 - 7th IEEE International Conference on Information Technology and Nanotechnology. — 2021. —
3Kashapov A.I., Doskolovich L.L., Bykov D.A. etc. Optical differentiator based on a trilayer metal-dielectric structure // Computer Optics 2021. — Vol. 45. Issue 3. — P. 356-363
4Motokura K., Fujii M., Nesterenko D.V. etc. Coupling of Planar Waveguide Modes in All-Dielectric Multilayer Structures: Monitoring the Dependence of Local Electric Fields on the Coupling Strength // PHYSICAL REVIEW APPLIED 2021. — Vol. 16. Issue 6.
5Nesterenko D.V., Pavelkin R.A., Hayashi S. etc. Estimation of the resonance characteristics of surface plasmon polariton structures for metal layers with different morphologies // Proceedings of ITNT 2021 - 7th IEEE International Conference on Information Technology and Nanotechnology. — 2021. —
6Nesterenko D.V., Pavelkin R. A. , Hayashi S. etc. Fano Approximation as a Fast and Effective Way for Estimating Resonance Characteristics of Surface Plasmon Structures // Plasmonics 2021. — Vol. 16. Issue 4. — P. 1001-1011
2020
1Podlipnov V.V., Nesterenko D.V.Resonance metal-dielectric structures based on CdTe for finding the concentration of solvents in the IR region // Proceedings of SPIE - The International Society for Optical Engineering. — 2020. — Vol. 11516.
2Motokura K., Kang B., Fujii M. etc. Wide-range line shape control of Fano-like resonances in all-dielectric multilayer structures based on enhanced light absorption in photochromic waveguide layers // Journal of Applied Physics 2020. — Vol. 127. Issue 7.
3Pavelkin R. A. , Hayashi S., Soifer V. etc. Asymmetric resonances and field enhancement of hybrid plasmon-waveguide modes // Proceedings of ITNT 2020 - 6th IEEE International Conference on Information Technology and Nanotechnology. — 2020. —
4Nesterenko D.V., Pavelkin R. A. , Hayashi S. etc. Analysis of resonance characteristics of surface plasmon-polariton modes at water-metal interfaces by Fano approximation // Journal of Physics: Conference Series. — 2020. — Vol. 1461. Issue 1.
5Nesterenko D.V., Kolesnikova M.D., Lyubarskaya L.V. etc. Brewster effect in the broadband light reflectivity // Journal of Physics: Conference Series. — 2020. — Vol. 1461. Issue 1.
6Nesterenko D.V.Resonance characteristics of transmissive optical filters based on metal/dielectric/metal structures // Computer Optics 2020. — Vol. 44. Issue 2. — P. 219-228
7Kang B., Motokura K., Fujii M. etc. Observation of Fano line shape in directional fluorescence emission mediated by coupled planar waveguide modes and interpretation based on Lorentz reciprocity // AIP Advances 2020. — Vol. 10. Issue 7.
8Nesterenko D.V., Moujdi S., Hayashi S. etc. Simulation of photochemically induced motion of matter in gradient light fields // Journal of Applied Physics 2020. — Vol. 127. Issue 24.
9Nesterenko D., Hayashi S., Soifer V.Approximation of Fabry-Pérot resonances in Ag/quartz/Ag structures // Proceedings of ITNT 2020 - 6th IEEE International Conference on Information Technology and Nanotechnology. — 2020. —
2019
1Kolesnikova M.D., Lyubarskaya A.V., Nesterenko D.V. etc. The resolution of optical image edge detection based on Brewster effect // Journal of Physics: Conference Series. — 2019. — Vol. 1368. Issue 2.
2Nesterenko D.V.Fano approximation for coupled modes in metal-dielectric multilayer structures // Journal of Physics: Conference Series. — 2019. — Vol. 1368. Issue 5.
3Nesterenko D.V., Lyubarskaya A.V., Kolesnikova M.D. etc. The dependence of the image edge detection directivity by Brewster effect on the gradient of inhomogeneities of objects // Journal of Physics: Conference Series. — 2019. — Vol. 1368. Issue 2.
4Podlipnov V.V., Ivliev N.A., Khonina S.N. etc. Formation of microstructures on the surface of a carbaseole-containing azopolymer by the action of laser beams // Journal of Physics: Conference Series. — 2019. — Vol. 1368. Issue 2.
5Motokura K., Kang B., Fujii M. etc. Light-controllable Fano resonance in azo-dye-doped all-dielectric multilayer structure // Journal of Applied Physics 2019. — Vol. 125. Issue 22.
6Kang B., Motokura K., Fujii M. etc. Fano resonant behaviour of waveguide mode in all-dielectric multilayer structure directly monitored by fluorescence of embedded dye molecules // Journal of Optics 2019. — Vol. 21. Issue 10.
7Nesterenko D.V., Pavelkin R. A. , Hayashi S. etc. Analysis of the resonance characteristics of surface plasmon polariton modes at air-metal interfaces in the ultraviolet, visible and infrared regions // Journal of Physics: Conference Series. — 2019. — Vol. 1368. Issue 2.
8Moujdi S., Bougdid Y., Rahmouni A. etc. Azo-polymers for holographic recording: Photo-assisted holography and surface relief gratings // Proceedings of SPIE - The International Society for Optical Engineering. — 2019. — Vol. 10944.
9Podlipnov V.V., Ivliev N.A., Khonina S.N. etc. Nonlinear effects in photoinduced nanomovement of carbazole-based azo-polymers // Proceedings of SPIE - The International Society for Optical Engineering. — 2019. — Vol. 11146.
10Nesterenko D.V., Pavelkin R. A. , Hayashi S. Estimation of resonance characteristics of single-layer surface-plasmon sensors in liquid solutions using fano’s approximation in the visible and infrared regions // Computer Optics 2019. — Vol. 43. Issue 4. — P. 596-604
2018
1Podlipnov V.V., Ivliev N.A., Khonina S.N. etc. Investigation of photoinduced formation of microstructures on the surface of a carbaseole-containing azopolymer depending on the power density of incident beams // Computer Optics 2018. — Vol. 42. Issue 5. — P. 779-785
2Nesterenko D.V., Hayashi S., Sekkat Z. Asymmetric surface plasmon resonances revisited as Fano resonances // PHYSICAL REVIEW B 2018. — Vol. 97. Issue 23.
3Nesterenko D.V., Kolesnikova M.D., Lyubarskaya A.V. Optical differentiation based on the brewster effect // Computer Optics 2018. — Vol. 42. Issue 5. — P. 758-763
4Nesterenko D.V., Hayashi S., Sekkat Z. Coupled-mode theory of field transfer processes in surface plasmon resonance structures // Journal of Physics: Conference Series. — 2018. — Vol. 1092.
5Refki S., Hayashi S., Ishitobi H. etc. Resolution Enhancement of Plasmonic Sensors by Metal-Insulator-Metal Structures // Annalen der Physik 2018. — Vol. 530. Issue 4.
6Moujdi S., Rahmouni A., Mahfoud T. etc. Surface relief gratings in azo-polymers revisited // Journal of Applied Physics 2018. — Vol. 124. Issue 21.
7Andam N., Refki S., Hayasi S. etc. Plasmonic coupled modes in metal-insulator-metal structures for sensing applications // Proceedings of SPIE - The International Society for Optical Engineering. — 2018. — Vol. 10722.
8Hayashi S., Nesterenko D.V., Sekkat Z. Light-tunable fano resonance in metal-dielectric multilayer structures // Springer Series in Optical Sciences 2018. — Vol. 219. — P. 241-260
9Moujdi S., Rahmouni A., Mahfoud T. etc. On surface relief gratings in azo-polymers // Proceedings of SPIE - The International Society for Optical Engineering. — 2018. — Vol. 10740.
10Kang B., Fujii M., Nesterenko D.V. etc. Fano resonances in near-field absorption in all-dielectric multilayer structures // Journal of Optics 2018. — Vol. 20. Issue 12.
2017
1Hayashi S., Fujiwara Y., Kang B. etc. Line shape engineering of sharp Fano resonance in Al-based metal-dielectric multilayer structure // Journal of Applied Physics 2017. — Vol. 122. Issue 16.
2Hayashi S., Nesterenko D.V., Rahmouni A. etc. Polarization effects in light-tunable Fano resonance in metal-dielectric multilayer structures // PHYSICAL REVIEW B 2017. — Vol. 95. Issue 16.
2016
1Refki S., Hayashi S., Rahmouni A. etc. Anticrossing Behavior of Surface Plasmon Polariton Dispersions in Metal-Insulator-Metal Structures // Plasmonics 2016. — Vol. 11. Issue 2. — P. 433-440
2Hayashi S., Nesterenko D.V., Rahmouni A. etc. Observation of Fano line shapes arising from coupling between surface plasmon polariton and waveguide modes // Applied Physics Letters 2016. — Vol. 108. Issue 5.
3Sekkat Z., Hayashi S., Nesterenko D.V. etc. Plasmonic coupled modes in metal-dielectric multilayer structures: Fano resonance and giant field enhancement // Optics Express 2016. — Vol. 24. Issue 18. — P. 20080-20088
4Rehman S., Rahmouni A., Shaukat S.F. etc. Optical characteristics of ultra-thin metallic films excited at visible range // Thin Solid Films 2016. — Vol. 615. — P. 38-43
5Hayashi S., Nesterenko D.V., Rahmouni A. etc. Light-tunable Fano resonance in metal-dielectric multilayer structures // Scientific Reports 2016. — Vol. 6.
6Nesterenko D.V., Hayashi S., Sekkat Z. Extremely narrow resonances, giant sensitivity and field enhancement in low-loss waveguide sensors // Journal of Optics 2016. — Vol. 18. Issue 6.
7Rahmouni A., Bougdid Y., Moujdi S. etc. Photoassisted Holography in Azo Dye Doped Polymer Films // Journal of Physical Chemistry B 2016. — Vol. 120. Issue 43. — P. 11317-11322
2015
1Nesterenko D.V., Hayashi S., Sekkat Z. Evanescent-field-coupled guided-mode sensor based on a waveguide grating // Applied Optics 2015. — Vol. 54. Issue 15. — P. 4889-4894
2Zekriti M., Nesterenko D.V., Sekkat Z. Long-range surface plasmons supported by a bilayer metallic structure for sensing applications // Applied Optics 2015. — Vol. 54. Issue 8. — P. 2151-2157
3Zekriti M., Nesterenko D.V., Sekkat Z. Long-range surface plasmons supported by a bilayer metallic structure for sensing applications // Applied Optics 2015. — Vol. 54. Issue 8. — P. 2151-2157
5Hayashi S., Nesterenko D.V., Sekkat Z. Fano resonance and plasmon-induced transparency in waveguide-coupled surface plasmon resonance sensors // Applied Physics Express 2015. — Vol. 8. Issue 2. — P. 022201
6Laghfour Z., Ajjammouri T., Aazou S. etc. Structural and opto-electrical properties of Al doped ZnO sputtered thin films // Journal of Materials Science: Materials in Electronics 2015. — Vol. 26. Issue 9. — P. 6730-6735
2014
1Hayashi S., Nesterenko D.V., Sekkat Z. Fano- and EIT-type resonances in surface plasmon-waveguide hybrid sensors // Nonlinear Photonics, NP 2014. — 2014. —
2Hayashi S., Nesterenko D.V., Sekkat Z. Fano- and EIT-type resonances in surface plasmon-waveguide hybrid sensors // Nonlinear Photonics, NP 2014. — 2014. —
4Hayashi S., Nesterenko D.V., Sekkat Z. etc. Sharp resonances in waveguide-coupled surface plasmon sensors for super-resolution sensing // JSAP-OSA Joint Symposia, JSAP 2014. — 2014. —
5Hayashi S., Nesterenko D.V., Sekkat Z. Fano- and EIT-type resonances in surface plasmon-waveguide hybrid sensors // Nonlinear Photonics, NP 2014. — 2014. —
6Rehman S.-U., Rahmouni A., Mahfoud T. etc. Determination of the optical thickness of sub 10-nm thin metal films by SPR experiments // Plasmonics 2014. — Vol. 9. Issue 2. — P. 381-387
7Hayashi S., Nesterenko D.V., Sekkat Z. Fano- and EIT-type resonances in surface plasmon-waveguide hybrid sensors // Nonlinear Photonics, NP 2014. — 2014. —
2013
1Nesterenko D.V., Sekkat Z. Resolution Estimation of the Au, Ag, Cu, and Al Single- and Double-Layer Surface Plasmon Sensors in the Ultraviolet, Visible, and Infrared Regions // Plasmonics 2013. — Vol. 8. Issue 4. — P. 1585-1595
2012
1Khonina S.N., Nesterenko D.V., Morozov A.A. etc. Narrowing of a light spot at diffraction of linearly-polarized beam on binary asymmetric axicons // Optical Memory and Neural Networks (Information Optics) 2012. — Vol. 21. Issue 1. — P. 17-26
2Nesterenko D.V., Saif-Ur-Rehman null, Sekkat Z. Surface plasmon sensing with different metals in single and double layer configurations // Applied Optics 2012. — Vol. 51. Issue 27. — P. 6673-6682
2011
1Khonina S.N., Nesterenko D.V., Morozov A.A. etc. Experimental research of diffraction of an linearly-polarized gaussian beam by binary microaxicon with the period close to wavelength // Computer Optics 2011. — Vol. 35. Issue 1. — P. 11-21
2KhONINA S. N., NESTERENKO D.V., MOROZOV A.A. etc. Экспериментальное исследование дифракции линейно-поляризованного Гауссова пучка на бинарных микроаксиконах с периодом близким к длине волны // Computer Optics 2011. — № Том 35, № 1. — P. 11-22
3Nesterenko D.V.Modeling of diffraction of electromagnetic waves on periodic inhomogeneities by a finite element method coupled with the Rayleigh expansion // Optoelectronics, Instrumentation and Data Processing 2011. — Vol. 47. Issue 1. — P. 68-75
5NESTERENKO D.V.Металло-диэлектрическая линза Микаэляна // Computer Optics 2011. — № Том 35, № 1. — P. 47-54
2008
1Nesterenko D.V., Kotlyar V.V.Modeling of light propagation in metallic nanorod arrays // Computer Optics 2008. — Vol. 32. Issue 4. — P. 337-343
2Nesterenko D.V., Kotlyar V.V.Hybrid finite element method and boundary element method for analysis of light diffraction on diffraction gratings // Computer Optics 2008. — Vol. 32. Issue 3. — P. 238-245
3Nesterenko D.V., Kotlyar V.V.Light scattering by the dielectric cylinder including 2-D grating of metallic nanowires // Computer Optics 2008. — Vol. 32. Issue 1. — P. 23-28
2005
1Nesterenko D., Min J.H., Choi H.Y. Design and analysis of tapered waveguides as collimators for LED backlighting // Digest of Technical Papers - SID International Symposium. — 2005. — Vol. 36. Issue 2. — P. 1388-1391
2001
1Kotlyar V.V., Nesterenko D.V.Analysis of light diffraction by binary micro-optics using a combination of boundary element method and finite element method // Proceedings of SPIE - The International Society for Optical Engineering. — 2001. — Vol. 4242. — P. 125-132
2Nesterenko D.V., Kotlyar V.V.Design of subwavelength binary microoptics using a gradient optimization method // Proceedings of SPIE - The International Society for Optical Engineering. — 2001. — Vol. 4436. — P. 171-178
2000
1Nesterenko D.V., Kotlyar V.V.Modeling the light diffraction by microoptics elements using the finite element method // Proceedings of SPIE - The International Society for Optical Engineering 2000. — Vol. 4002. — P. 135-142
ВАК
2022
1Подлипнов В.В., Быков Д.А., Нестеренко Д.В.Structural and optical properties of thin CdTe films in the visible and infrared regions // Computer Optics. — 2022. — Т. 46. Вып. 3. № 3. — С. 415-421
2021
1Нестеренко Д.В., Morozov A.A., Досколович Л.Л.Optical image edge detection by transmissive metal-dielectric-metal structures // Компьютерная оптика. — 2021. — Т. 45. Вып. 5. — С. 678-684
2Kashapov A.I., Досколович Л. Л. , Быков Д. А. и др. Optical differentiator based on a trilayer metal-dielectric structure // Компьютерная оптика. — 2021. — Т. 45. Вып. 3. — С. 356-363
2018
1Подлипнов В. В. , Ивлиев Н. А. , Хонина С. Н. и др. Investigation of photoinduced formation of microstructures on the surface of a carbaseole-containing azopolymer depending on the power density of incident beams // Компьютерная оптика. — 2018. — Т. 42. Вып. 5. — С. 779-785
2Нестеренко Д. В. , Kolesnikova M.D., Lyubarskaya A.V. Optical differentiation based on the brewster effect // Компьютерная оптика. — 2018. — Т. 42. Вып. 5. — С. 758-763
2011
1ХОНИНА С. Н., НЕСТЕРЕНКО Д.В., МОРОЗОВ А.А. и др. Экспериментальное исследование дифракции линейно-поляризованного Гауссова пучка на бинарных микроаксиконах с периодом близким к длине волны // Компьютерная оптика. — 2011. — № Том 35, № 1. — С. 11-22
2НЕСТЕРЕНКО Д.В.Металло-диэлектрическая линза Микаэляна // Компьютерная оптика. — 2011. — № Том 35, № 1. — С. 47-54
3НЕСТЕРЕНКО Д.В.Моделирование дифракции электромаг-нитных волн на периодических неодно-родностях объединенным методом конеч-ных элементов и разложения Релея // Автометрия. — 2011. — № Т. 47. № 1.. — С. 85-95
Другие
2020
1Pavelkin R.A., Nesterenko D.V.Estimation of influence of the metal layer morphology on the sensitivity of surface plasmon resonance sensors // XXIII Международная школа молодых ученых и студентов по оптике, лазерной физике и биофотонике Saratov Fall Meeting–2019. — 2020. — P. 54-58