Molodtsova A.A., Buzakov M.K., Burmistrov O.I., Rozenblit A.D., Smirnov V.A., Sennikova D.V., Porvatov V., Puhtina E.M., Dmitriev A.A., Olekhno N.A. Micellization in active matter of asymmetric self-propelled particles: Experiments. Physical Review E. 2025. Vol. 111. pp. 065424.
Rozenblit A.D., Kurganov G.D., Zhirihin D.V., Olekhno N.A. Topological edge states in all-dielectric square-lattice arrays of bianisotropic microwave resonators. Physical Review B. 2025. Vol. 111. No. 8. pp. 085415.
Topological Edge States in a Square Lattice of Dielectric Bianisotropic Resonators
Olekhno N.A., Petrov M.I., Iorsh I.V., Sukhorukov A.A., Solntsev A.S. Generating N00N states of surface plasmon polaritons with N=2 by a single nanoparticle. Physical Review B. 2024. Vol. 109. No. 24. pp. 245416.
Burmistrov O.I., Olekhno N.A. Wireless power transfer in magnetic resonance imaging with a detuned birdcage coil. Научно-технические ведомости Санкт-Петербургского государственного политехнического университета. Физико-математические науки = St.Petersburg State Polytechnical University Journal. Physics and Mathematics. 2024. Vol. 17. No. 3.1. pp. 354-357.
Rozenblit A.D., Kurganov G.D., Zhirihin D.V., Olekhno N.A. Edge states supported by two-dimensional square-lattice arrays of bianisotropic dielectric resonators. Научно-технические ведомости Санкт-Петербургского государственного политехнического университета. Физико-математические науки = St.Petersburg State Polytechnical University Journal. Physics and Mathematics. 2024. Vol. 17. No. 3.2. pp. 360-363.
Образование кластеров активно движущимися частицами асимметричной формы
Wireless power transfer in MRI with a detuned birdcage coil
Численное моделирование отстроенного резонатора типа «птичья клетка» для беспроводной передачи энергии внутри тоннеля аппарата магнитно-резонансной томографии
Беспроводная передача энергии с помощью отстроенного резонатора типа «птичья клетка» в магнитно-резонансной томографии
Topological edge states supported by two-dimensional square-lattice arrays of bianisotropic dielectric resonators
Burmistrov O.I., Mikhailov N.V., Dashkevich D.S., Seregin P., Olekhno N.A. Wireless power transfer in magnetic resonance imaging at a higher-order mode of a birdcage coil. Physical Review Applied. 2024. Vol. 21. No. 1. pp. 014047.
Экспериментальное исследование образования мицелл в активной материи на основе скопления роботов
Jamming transition and micellization in robotic swarms
Koreshin E., Sakhno D., Olekhno N.A., Poddubny A.N., Belov P.A. Emulating quantum photon-photon interactions in waveguides by double-wire media. Photonics and Nanostructures - Fundamentals and Applications. 2023. Vol. 53. pp. 101104.
Buzakov M.K., Smirnov V.A., Sennikova D.V., Molodtsova A.A., Rozenblit A.D., Porvatov V., Burmistrov O.I., Puhtina E.M., Dmitriev A.A., Olekhno N.A. Crystallization of robotic swarms in a parabolic potential. Научно-технические ведомости Санкт-Петербургского государственного политехнического университета. Физико-математические науки = St.Petersburg State Polytechnical University Journal. Physics and Mathematics. 2023. Vol. 16. No. S3.1. pp. 36-40.
Puchnin V.M., Matvievskaya O.V., Slobozhanyuk A.P., Shchelokova A.V., Olekhno N.A. Application of Topological Edge States in Magnetic Resonance Imaging. Physical Review Applied. 2023. Vol. 20. No. 2. pp. 024076.
Molodtsova A.A., Buzakov M.K., Rozenblit A.D., Smirnov V.A., Sennikova D.V., Porvatov V.A., Burmistrov O.I., Puhtina E.M., Dmitriev A.A., Olekhno N.A. Experimental demonstration of robotic active matter micellization. arXiv.org [база препринтов]. 2023. pp. 1-5.
Dmitriev A.A., Rozenblit A.D., Porvatov V., Buzakov M.K., Molodtsova A.A., Sennikova D.V., Smirnov V.A., Burmistrov O.I., Karimov T.I., Puhtina E.M., Olekhno N.A. Swarmodroid 1.0: A Modular Bristle-Bot Platform for Robotic Active Matter Studies. arXiv.org [база препринтов]. 2023. pp. 1-47.
Application of the transmit birdcage coil for wireless power transfer in magnetic resonance imaging
Локальные фазовые переходы в скоплениях роботов
Фазовые переходы в скоплениях движущихся роботов
Смирнов В.А., Бузаков М.К., Сенникова Д.В. (науч. рук. Олехно Н.А.) Исследование динамики вибрирующего робота
Olekhno N.A., Rozenblit A., Kachin V., Dmitriev A.A., Burmistrov O., Seregin P., Zhirihin D.V., Gorlach M.A. Experimental realization of topological corner states in long-range-coupled electrical circuits. Physical Review B. 2022. Vol. 105. No. 8. pp. L081107.
Seregin P., Burmistrov O.I., Solomakha G.A., Kretov E.I., Olekhno N.A., Slobozhanyuk A.P. Energy-Harvesting Coil for Circularly Polarized Fields in Magnetic Resonance Imaging. Physical Review Applied. 2022. Vol. 17. No. 4. pp. 044014.
Olekhno N., Rozenblit A., Stepanenko A.A., Dmitriev A.A., Bobylev D.A., Gorlach M.A. Topological transitions driven by quantum statistics and their electrical circuit emulation. Physical Review B. 2022. Vol. 105. No. 20. pp. 205113.
Olekhno N.A., Petrov M.I., Iorsh I.V., Sukhorukov A.A., Solntsev A.S. Generating N00N-states of surface plasmon-polariton pairs in a nonlinear nanoparticle on metallic substrate. Proceedings - International Conference Laser Optics 2022, ICLO 2022. 2022. pp. 1-1.
Nikolaeva A., Frizyuk K.S., Olekhno N.A., Solntsev A.S., Petrov M.I. Directional emission of down-converted photons from a dielectric nanoresonator. Physical Review A. 2021. Vol. 103. No. 4. pp. 043703.
Dmitriev A., Rozenblit A., Porvatov V.A., Molodtsova A., Puhtina E., Burmistrov O., Filonov D.S., Souslov A., Olekhno N. Statistical Correlations in Active Matter Based on Robotic Swarms. International Conference Engineering and Telecommunication, En and T 2021. 2021. pp. 1-3.
Olekhno N.A., Rozenblit A., Kachin V.I., Burmistrov O.I., Dmitriev A.A., Seregin P., Zhirihin D.V., Gorlach M.A. Higher-Order Topological States in the Extended Two-Dimensional SSH Model and Their Electric Circuit Implementation. Conference on Lasers and Electro-Optics, CLEO 2021. 2021. pp. 1-2.
Olekhno N., Rozenblit A., Kachin V.I., Dmitriev A.A., Burmistrov O.I., Seregin P., Zhirihin D.V., Gorlach M.A. Higher-order topological states mediated by long-range coupling in D4-symmetric lattices. arXiv.org [база препринтов]. 2021.
Poshakinskiy A.V., Zhong J., Ke Y., Olekhno N.A., Lee C., Kivshar Y.S., Poddubny A.N. Quantum Hall phases emerging from atom–photon interactions . npj Quantum Information. 2021. Vol. 7. No. 34. pp. 34.
Two-particle topological states induced by quantum statistics and their electric circuit emulation
Seregin P., Burmistrov O., Solomakha G.A., Kretov E.I., Olekhno N.A., Slobozhanyuk A.P. Circularly polarized RF coil for energy harvesting in clinical MRI. Journal of Physics: Conference Series. 2021. Vol. 2015. No. 1. pp. 012134.
Rozenblit A.D., Olekhno N.A., Dmitriev A.A., Seregin P.S., Gorlach M.A. Topological edge states of anyon pairs emulated in electrical circuits. Journal of Physics: Conference Series. 2021. Vol. 2015. No. 1. pp. 012127.
Porvatov V.A., Rozenblit A.D., Dmitriev A.A., Burmistrov O.I., Petrova D.A., Gritsenko G.Y., Puhtina E.M., Kretov E.I., Filonov D.S., Souslov A., Olekhno N.A. Optimizing self-rotating bristle-bots for active matter implementation with robotic swarms. Journal of Physics: Conference Series. 2021. Vol. 2086. No. 1. pp. 012202.
Robotic ensemble platform for emulation of friction-assisted phase formation in active matter
Zhong J., Poshakinskiy A.V., Ke Y., Olekhno N.A., Lee C., Kivshar Y.S., Poddubny A.N. Topological and localized states in waveguide quantum electrodynamics. Conference on Lasers and Electro-Optics, CLEO 2021. 2021. pp. 1-2.
Olekhno N., Petrov M., Iorsh I., Sukhorukov A., Solntsev A.S. Generating N00N-states of surface plasmon-polariton pairs with a nanoparticle. arXiv.org [база препринтов]. 2020.
Poshakinskiy A.V., Zhong J., Ke Y., Olekhno N., Lee C., Kivshar Y.S., Poddubny A.N. Quantum Hall phase emerging in an array of atoms interacting with photons. arXiv.org [база препринтов]. 2020.
Rozenblit A., Porvatov V., Petrova D.A., Khakhalin I.S., Kotlyar K.P., Gritsenko G., Evreiskaya A., Lebedeva M., Kretov E.I., Filonov D.S., Souslov A., Olekhno N.A. Diffusive dynamics and jamming in ensembles of robots with variable friction. Journal of Physics: Conference Series. 2020. Vol. 1695. No. 1. pp. 012201.
Ivanova P.A., Olekhno N.A., Kachin V., Zhirihin D.V., Seregin P., Gorlach M.A. Realizing topological corner states in two-dimensional Su-Schrieffer-Heeger model with next-nearest neighbor couplings. Journal of Physics: Conference Series. 2020. Vol. 1695. No. 1. pp. 012142.
Olekhno N., Kretov E.I., Stepanenko A.A., Ivanova P.A., Yaroshenko V.V., Puhtina E.M., Filonov D.S., Cappello B., Matekovits L., Gorlach M. Topological edge states of interacting photon pairs emulated in a topolectrical circuit. Nature Communications. 2020. Vol. 11. No. 1. pp. 1436.
Zhong J., Olekhno N.A., Ke Y., Poshakinskiy A.V., Lee C., Kivshar Y.S., Poddubny A.N. Photon-Mediated Localization in Two-Level Qubit Arrays. Physical Review Letters. 2020. Vol. 124. No. 9. pp. 093604.
Olekhno N.A., Rozenblit A., Seregin P., Gorlach M.A. Statistics-induced topological States of interacting anyons. AIP Conference Proceedings. 2020. Vol. 2300. pp. 020093.
Diffusion dynamics in ensembles of robots with variable friction
Realizing topological corner states in two-dimensional Su-Schrieffer-Heeger model with next-nearest neighbor couplings
Zhong J., Poshakinskiy A.V., Ke Y., Olekhno N.A., Lee C., Kivshar Y.S., Poddubny A.N. Interaction-induced topological phases of photons interacting with atoms. Optics InfoBase Conference Papers. 2020. pp. FM5A.2.
Diffusion dynamics in ensembles of robots with variable friction
Топологические состояния высокого порядка в расширенной двумерной модели Су-Шриффера-Хигера
Topological States of Interacting Photon Pairs Emulated in a Topolectrical Circuit
Olekhno N.A., Petrov M.I., Iorsh I.V., Sukhorukov A.A., Solntsev A. Generating Quantum States of Surface Plasmon-Polariton Pairs with a Nonlinear Nanoparticle. Conference on Lasers and Electro-Optics Europe and European Quantum Electronics Conference, CLEO/Europe-EQEC 2019. 2019. pp. 8872429.
Эмуляция топологических состояний пар взаимодействующих фотонов с помощью LC-сетей
Olekhno N.A., Gorlach M.A., Kretov E.I., Stepanenko A.A., Ivanova P.A., Yaroshenko V.V., Puhtina E.M., Filonov D.S., Cappello B., Matekovits L. Topological states of interacting photon pairs emulated in a topolectrical circuit. 2019 Photonics & Electromagnetics Research Symposium - Fall (PIERS - Fall). 2019. pp. 1082-1086.
Olekhno N.A., Petrov M.I., Iorsh I.V. Generation of surface plasmon-polariton pairs by a nonlinear nanoparticle. Journal of Physics: Conference Series. 2018. Vol. 1092. No. 1. pp. 012105.
Аналоговое моделирование топологических состояний связанных пар фотонов с помощью LC-сетей
Petrov M.I., Nikolaeva A.A., Frizyuk K.S., Olekhno N.A. Second harmonic generation and spontaneous parametric down-conversion in Mie nanoresonators. Journal of Physics: Conference Series. 2018. Vol. 1124. No. 5. pp. 051021.
Olekhno N.A., Beltukov Y.M. Two-dimensional plasmons in the random impedance network model of disordered thin film nanocomposites. Physical Review B. 2018. Vol. 97. No. 18. pp. 184204.
Olekhno N.A., Beltukov Y.M. Random matrix approach to plasmon resonances in the random impedance network model of disordered nanocomposites. Physical Review E. 2018. Vol. 97. No. 5. pp. 050101.
Olekhno N.A., Petrov M.I., Iorsh I.V. Generation of photon and plasmon pairs by a nonlinear semiconductor nanoparticle. Optics InfoBase Conference Papers. 2018. Vol. Part F108-NP. pp. NpM2I.5.
Спонтанное параметрическое рассеяние света полупроводниковой наночастицей
Olekhno N.A., Petrov M.I., Iorsh I.V. Spontaneous parametric downconversion of light by a dielectric nanoparticle. Journal of Physics: Conference Series. 2018. Vol. 993. No. 1. pp. 012022.
Olekhno N.A., Beltukov Y.M. 2D-plasmons in a random impedance network model of disordered nanocomposites. 2017 Progress In Electromagnetics Research Symposium - Spring (PIERS). 2017. pp. 1529-1534.
Материалы с управляемыми оптическими и электрическими свойствами на основе двухфазных нанокомпозитов
Спонтанное параметрическое рассеяние света диэлектрической наночастицей в длинноволновом приближении
Российская Федерация, Санкт-Петербург
Российская Федерация, Санкт-Петербург