Oleg Baranov
Doctor of Technical Sciences, Professor,
Head of the Department of Theoretical Mechanics,
Mechanical Engineering and Robotic Mechanical Systems
of the Faculty of Aviation Engines of the National Aerospace University
"Kharkiv Aviation Institute"
Е-mail: [email protected]
Education:
July 2016
Doctor of Science in materials science and processing technologies, National Aerospace University “Kharkiv Aviation Institute”, Kharkiv, Ukraine.
Dissertation title: “Scientific basis of formation of distribution of ion fluxes with specified parameters in setups of plasma-ion treatment of surfaces”.
October 2000
Doctor of Philosophy in the aircraft technology and materials science, National Aerospace University “Kharkiv Aviation Institute”, Kharkiv, Ukraine.
Dissertation title: “Development of combined technology for the formation of the surface layer of aviation constructional materials”.
February 1997
Master of Science in Robotics (with honours), National Aerospace University “Kharkiv Aviation Institute”, Kharkiv, Ukraine.
Research Interests:
Plasma physics and nanotechnology (carbon and oxide nanostructures), plasma propulsion, PVD coatings, magnetron and vacuum arc deposition, plasma control and diagnostics in technological setups, mechanical properties of materials and coatings, surface plasma processing, and robotics.
Research Experience:
Contribute to projects and collaboration with the research groups:
Synthesis of graphene materials. School of Chemistry, Physics, Mechanical Engineering, Queensland University of Technology, Brisbane, Queensland, Australia (Prof. K. Bazaka);
Plasma enhanced synthesis of carbon nanomaterials. Plasma Sources and Applications Centre, National Institute of Education, Nanyang Technological University, Singapore (Prof. I Levchenko);
Synthesis of copper-oxide nanostructures in radiofrequency plasma discharge. Plasma Nanoscience Group, Jozef Stefan Institute, Ljubliana, Slovenia, EU (Prof. U. Cvelbar);
Magnetic control of ion fluxes for plasma processing of a large substrate and for plasma propulsion. Plasma Nanoscience, School of Physics, the University of Sydney, Australia (Prof. K. Ostrikov); The George Washington University, Washington, USA (Prof. M. Keidar); Nanotech. & Advanced Materials Research Institute, University of Ulster, UK (Prof. D. Mariotti); Plasma Sources and Appl. Center, NIE, Nanyang Technological University, Singapore (Prof. S. Xu);
Low-pressure planar magnetron discharges for surface deposition and nanofabrication. CSIRO Materials Science and Engineering, Australia (Prof. K. Ostrikov); Department of Physics, Shanghai Jiao Tong University, Shanghai, China (Prof. X. X. Zhong); Institute of Experimental and Applied Physics, University Kiel, Germany (Dr. Wolter)
Contribute to grants of Ministry of Education and Science of Ukraine, National Aerospace University “Kharkiv Aviation Institute”:
Development of automated complex for precision thermo-impulse treatment by detonating gas mixtures (0117U002500)
Scientific foundations of growth of oxide and carbon nanostructures under conditions of plasma environment (0120U105422)
Teaching and Mentoring Experience:
From May 2019 to the present, he is the Head of Department of Theoretical Mechanics, Engineering and Robomechanical Systems, National Aerospace University “Kharkiv Aviation Institute”;
From September 2018 to May 2019, he was a Professor of Department of Theoretical Mechanics, Engineering and Robomechanical Systems, National Aerospace University “Kharkiv Aviation Institute;
From September 2011 to September 2018, he was an Assistant professor of Department of Theoretical Mechanics, Engineering and Robomechanical Systems, National Aerospace University “Kharkiv Aviation Institute”;
From April 2006 to September 2011, he was an Assistant professor of Department of Robotic Systems, National Aerospace University “Kharkiv Aviation Institute”;
From September 2000 to April 2006, he was an Assistant, Department of Physical-technical treatment of construction materials, National Aerospace University “Kharkiv Aviation Institute”.
The main lecture courses:
- Mathematical fundamentals of robotic technical systems;
- Fundamentals of designing of robotic technical systems;
- Design of robotic systems and complexes
Honors and Awards:
Diploma of Kharkiv Regional Administration (2019)
International Publication Encouragement Awards (2013, 2014) from Institute of Electrical and Electronics Engineers (IEEE) East Ukraine Joint Chapter.
Technical Skills:
Programming languages and mathematical packages: Matlab, MathCAD, Turbo Pascal, Python,
Computer aided design/engineering: SolidWorks, Kompas Other: Linux, Windows OS.
Languages:
Ukrainian, Russian, and English: Fluent.
Publications:
Levchenko, S. Xu, O. Cherkun, O. Baranov and K. Bazaka. “Plasma meets metamatertials: Three ways to advance space micropropulsion systems”, Advances in Physics X, 2020, 2021, V. 6, No. 1, 1834452. https://doi.org/10.1080/23746149.2020.1834452
Levchenko, O. Baranov, J. Fang, O. Cherkun, S. Xu, K. Bazaka. Focusing plasma jets to achieve high current density: Feasibility and opportunities for applications in debris removal and space exploration. Aerospace Science and Technology. 2020, 106343. https://doi.org/10.1016/i.ast.2020.106343
Sun, I. Levchenko, J. W. M. Lim, L. Xu, S. Huang, Z. Zhang, F. Thio, G- C. Potrivitu, M. Rohaizat, O. Cherkun, O. Baranov, K. Bazaka, S. Xu, “Miniaturized rotating magnetic field driven plasma system: proof-of-concept experiments”, Plasma Sources Science and Technology 2020, accepted. https://doi.org/10.1088/1361-6595/ab9b34
Alancherry, M.V. Jacob, K. Prasad, J. Joseph, O. Bazaka, R. Neupane, O.K. Varghese, O. Baranov, S. Xu, I. Levchenko, K. Bazaka, “Tuning and fine morphology control of natural resource-derived vertical graphene”, Carbon 2020, 159, 668-685. https://doi.org/10.1016/i.carbon.2019.10.060
Levchenko, K. Bazaka, O. Baranov, O. Cherkun, M. Keidar, S. Xu, “Processes at Plasma-Matter Interfaces: An Overview and Future Trends”, AAPPS Bulletin 2020, 30 (3) 37-48. https://doi.org/10.22661/AAPPSBL.2020.30.3.37
Baranov, G. Filipic and U. Cvelbar, “Towards a highly-controllable synthesis of copper oxide nanowires in radio-frequency reactive plasma: fast saturation at the targeted size”, Plasma Sources Science and Technology 2019, 28 084002. https://doi.org/10.1088/1361-6595/aae12e
Baranov, I. Levchenko, S. Xu, X. G. Wang, H. P. Zhou, K. Bazaka, “Direct current arc plasma thrusters for space applications: basic physics, design and perspectives”, Reviews of Modern Plasma Physics 2019, 3 (7), 1-63. https://doi.org/10.1007/s41614-019-0023-3
Bazaka, I. Levchenko, J. W. M. Lim, O. Baranov, C. Corbella, S. Xu and M. Keidar, “MoS2-based nanostructures: synthesis and applications in medicine”, Journal of Physics D: Applied Physics 52, 183001 (2019). https://doi.org/10.1088/1361-6463/ab03b3
Guo, M. Kosicek, J. Fu, Y. Qu, G. Lin, O. Baranov, J. Zavasnik, Q. Cheng, K. Ostrikov and U. Cvelbar “Single-Crystalline Metal Oxide Nanostructures Synthesized by Plasma-Enhanced Thermal Oxidation”, Nanomaterials 2019, 9(10), 1405. https://doi.org/10.3390/nano9101405
Baranov, I. Levchenko, S. Xu, J. W. M. Lim, U. Cvelbar and K. Bazaka, “Formation of vertically oriented graphenes: what are the key drivers of growth?”, 2D Materials 5 044002 (2018). https://doi.org/10.1088/2053-1583/aad2bc
Baranov, I. Levchenko, J. Bell, M. Lim, S. Huang, L. Xu, B. Wang, D. U. B. Aussems, S. Xu and K. Bazaka, “From nanometre to millimetre: A range of capabilities for plasma-enabled surface functionalization and nanostructuring”, Materials Horizons 5, 765-798 (2018). https://doi.org/10.1039/C8MH00326B
M. Santhosh, G. Filipic, E. Tatarova, O. Baranov, H. Kondo, M. Sekine, M. Hori, K. (Ken) Ostrikov and U. Cvelbar, “Oriented Carbon Nanostructures by Plasma Processing: Recent Advances and Future Challenges”, Micromachines 2018, 9(11), 565. https://doi.org/10.3390/mi9110565
Bazaka, O. Baranov, U. Cvelbar, B. Podgornik, Y. Wang, S. Huang, L. Xu, J. W. M. Lim, I. Levchenko and S. Xu, “Oxygen plasmas: a sharp chisel and handy trowel for nanofabrication”, Nanoscale, 10, 17494-17511 (2018). https://doi.org/10.1039/C8NR06502K
B. Wang, X. L. Qu, M. K. Zhu, I. Levchenko, O. Baranov, X. X. Zhong, S. Xu, K. Ostrikov, “Morphological transformations of BNCO nanomaterials: Role of intermediates”, Applied Surface Science, 442, 682-692 (2018). https://doi.org/10.1016/i.apsusc.2018.02.195
Levchenko, K. Bazaka, O. Baranov, R. M. Sankaran, A. Nomine, T. Belmonte, and S. Xu, “Lightning under water: Diverse reactive environments and evidence of synergistic effects for material treatment and activation”, Applied Physics Reviews 5, 021103 (2018). https://doi.org/10.1063/1.5024865
Baranov, S. Xu, L. Xu, S. Huang, J. W. M. Lim, U. Cvelbar, I. Levchenko, K. Bazaka, “Miniaturized Plasma Sources: Can Technological Solutions Help Electric Micropropulsion?”, IEEE Transactions on Plasma Science 46 (2), 230-238 (2018). https://doi.org/10.1109/TPS.2017.2773073
Baranov, U. Cvelbar, K. Bazaka, “Concept of a Magnetically Enhanced Vacuum Arc Thruster With Controlled Distribution of Ion Flux”, IEEE Transactions on Plasma Science, 46 (2), 304-310 (2018). https://doi.org/10.1109/TPS.2017.2778880
Baranov, S. Xu, K. Ostrikov, B. B. Wang, U. Cvelbar, K. Bazaka, I. Levchenko, “Towards universal plasma-enabled platform for the advanced nanofabrication: plasma physics level approach”, Review of Modern Plasma Physics 2 (4), 1-49 (2018). https://doi.org/10.1007/s41614-018-0016-7
Baranov, K. Bazaka, H. Kersten, M. Keidar, U. Cvelbar, S. Xu, “Plasma under control: Advanced solutions and perspectives for plasma flux management in material treatment and nanosynthesis”, Applied Physics Reviews 4, 041302 (2017). https://doi.org/10.1063/1.5007869
Baranov, J. Fang, K. Ostrikov, U. Cvelbar, “TiN deposition and morphology control by scalable plasma-assisted surface treatments”, Materials Chemistry and Physics 188, 143-153 (2017). https://doi.org/10.1016/i.matchemphys.2016.12.010
Filipic, O. Baranov, M. Mozetic, U. Cvelbar, “Growth dynamics of copper oxide nanowires in plasma at low pressures”, Journal of Applied Physics 117, 043304 (2015). https://doi.org/10.1063/1.4906501
Filipic, O. Baranov, M. Mozetic, K. Ostrikov, U. Cvelbar, “Uniform surface growth of copper oxide nanowires in radiofrequency plasma discharge and limiting factors”, Physics of plasmas 21, 113506 (2014). https://doi.org/10.1063/1.4901813
Baranov, J. Fang, M. Keidar, X. Lu, U. Cvelbar, K. Ostrikov, “Effective control of the arc discharge-generated plasma jet by smartly designed magnetic fields”, IEEE Transactions on Plasma Science 42 (10), 2464-2465 (2014). https://doi.org/10.1109/TPS.2014.2323263
Baranov, X. Zhong, J. Fang, S. Kumar, S. Xu, U. Cvelbar, D. Mariotti, K. Ostrikov, “Dense plasmas in magnetic traps: generation of focused ion beams with controlled ion-to-neutral flux ratios”, IEEE Transactions on Plasma Science 42 (10), 2518-2519 (2014). https://doi.org/10.1109/TPS.2013.2295626
Baranov, J. Fang, A. Rider, S. Kumar, K. Ostrikov, “Effect of ion current density on the properties of vacuum arc-deposited TiN coatings”, IEEE Transactions on Plasma Science 41 (12), 3640-3644 (2013). https://doi.org/10.1109/TPS.2013.2286405
Baranov, M. Romanov, J. Fang, U. Cvelbar, K. Ostrikov, “Control of ion density distribution by magnetic traps for plasma electrons”, Journal of Applied Physics 112 (7), 073302 (2012). https://doi.org/10.1063/1.4757022
Baranov, M. Romanov, S. Kumar, X. Zhong, K.Ostrikov, “Magnetic control of breakdown: Toward energy-efficient hollow-cathode magnetron discharges” Journal of Applied Physics 109 (6), 063304 (2011). https://doi.org/10.1063/1.3553853
Baranov, M. Romanov, M. Wolter, S. Kumar, X. Zhong, K. Ostrikov, “Low-pressure planar magnetron discharge for surface deposition and nanofabrication” Physics of Plasmas 17, 053509 (2010). https://doi.org/10.1063/1.3431098
Baranov, M. Romanov, and K. Ostrikov, ’’Discharge parameters and dominant electron conductivity mechanism in a low-pressure planar magnetron discharge” Physics of Plasmas 16, 063505 (2009). https://doi.org/10.1063/1.3153554
Baranov, M. Romanov, and K. Ostrikov, ’’Effective control of ion fluxes over large areas by magnetic fields: From narrow beams to highly uniform fluxes” Physics of Plasmas 16, 053505 (2009). https://doi.org/10.1063/1.3130267
Baranov and M. Romanov, “Process Intensification in Vacuum Arc Deposition Setups” Plasma Processes and Polymers 6 (2), 95 (2009). https://doi.org/10.1002/ppap.200800131
Baranov, M. Romanov, “Current Distribution on the Substrate in a Vacuum Arc Deposition Setup” Plasma Processes and Polymers 5, 256 (2008). https://doi.org/10.1002/ppap.200700160
Levchenko, M. Romanov, O. Baranov, and M. Keidar, “Ion deposition in a crossed ExB field system with vacuum arc plasma sources” Vacuum 72, 335 (2004). https://doi.org/10.1016/i.vacuum.2003.09.002
Levchenko, O. Baranov, “Simulation of island behavior in discontinuous film growth” Vacuum 72, 205 (2003). https://doi.org/10.1016/i.vacuum.2003.08.004
Books:
Розроблення автоматизованого комплексу для прецизійного термоімпульсного оброблення детонувальними газовими сумішами: наукові матеріали: монографія / С. І. Планковський, О. В. Шипуль, Є. В. Цегельник, О. В. Трифонов, К. В. Коритченко, О. О. Баранов, Ю. О. Сисоєв, В. О. Гарін, Є. О. Аксьонов, В. В. Комбаров, С. О. Заклінський ; за ред. С. І. Планковського. - Харків : Нац. аерокосм. ун-т ім. М. Є. Жуковського «Харків. авіац. ін-т», 2020. - 318 с. http://library.khai.edu/catalog?mode=DocBibRecord&docid=510534734
Book Chapters:
O. O. Baranov, I. Levchenko, S. Xu, K. Bazaka, “Advanced concepts and architectures for plasma- enabled material processing” // Synthesis lectures on emerging engineering technologies. - Morgan & Claypool Publishers. - San Rafael, USA. - 2020. - P. 1-90. ISBN 9781681739113 . https://doi.org/10.2200/S01042ED1V01Y202008EET011
Conference Presentations:
Baranov, G. Filipic, U. Cvelbar. “Plasma enhanced growth of oxide nanowires: advantages and limiting factors” Third Gaseous electronic symposia, February 3- 6th 2020, Rogla, Slovenia.
Baranov, U. Cvelbar, and K. Bazaka. “Technological Plasma Systems: Perspectives and Trends for Space Electric Propulsion” - Second International Conference on Micropropulsion and CubeSats, January 8 - 12, Singapore, 2018.
Cvelbar, O. Baranov and G. Filipic. “Copper Oxide Nanowire Plasma-Assisted Growth Dynamics and Role of Underlying Oxide Layers” - 231st ECS Meeting May 28, 2017 - June 1, 2017 New Orleans, USA.
Baranov. “Deposition of uniform vacuum arc coatings by use of magnetic traps for plasma electrons” - Proceedings of the International Conference Nanomaterials: Applications and Properties. - September 21 - 27, Lviv, 2014.
Baranov. “Influence of ion current density on the properties of vacuum arc-deposited TiN coating” - Proceedings of the International Conference Nanomaterials: Applications and Properties. - September 16 - 21, Alushta, 2013.
Baranov. “Control of ion density distribution by use of magnetic traps for plasma electrons” - Proceedings of the International Conference Nanomaterials: Applications and Properties. - September 17 - 22, Alushta, 2012.
Methodological Publications:
Руденко, Н. В. Функціональні комплекси логістичних систем [Текст] : навч. посіб. до практ. занять / Н. В. Руденко, Т. М. Соляник, О. О. Баранов. - Харків : Нац. аерокосм. ун-т ім. М. Є. Жуковського «Харків. авіац. ін-т», 2020. - 144 с.
Костюк, Г. І. Конструювання промислових роботів [Текст]: навч. посіб. / Г. І. Костюк, О. О. Баранов, Ю. В. Широкий. — Харків: Нац. аерокосм. ун-т ім. М. Є. Жуковського «Харків. авіац. ін-т», 2019. - 136 с.
Гнучкі робототехнічні комплекси для механічної обробки [Текст]: навч. посіб / В. М. Павленко, Г. І. Костюк, О. О. Баранов, М. С. Романов. - Харків: Нац. аерокосм. ун-т ім. М. Є. Жуковського «Харк. авіац. ін-т», 2014. - 168 с.
Современные технологические системы в автоматизированном производстве [Текст]: учеб. пособие / В.Н. Павленко, Г.И. Костюк, О.О. Баранов, М.С. Романов. - Харьков: Нац. аэрокосм. ун-т "Харьк. авиац. ин-т", 2012. - 108 с.
Гибкие автоматизированные цехи механической обработки. Часть 1 [Текст]: учеб. пособие / Г.И. Костюк, М.С. Романов, О.О. Баранов, В.А. Фадеев. - Харьков: Нац. аэрокосм. ун-т им. Н.Е. Жуковского «Харьк. авиац. ин-т», 2010. - 104 с.
Костюк, Г.И. Гибкие автоматизированные цехи механической обработки. Часть 2 [Текст]: учеб. пособие / Г.И. Костюк, М.С. Романов, О.О. Баранов. - Харьков: Нац. аэрокосм. ун-т им. Н.Е. Жуковского «Харьк. авиац. ин-т», 2011. - 92 с.
Костюк, Г.И. Гибкие производственные модули механической обработки. Часть 1 [Текст]: учеб. пособие / Г.И. Костюк, О.О. Баранов, М.С. Романов. - Харьков: Нац. аэрокосм. ун-т им. Н.Е. Жуковского «Харьк. авиац. ин-т», 2011. - 92 с.
Костюк, Г.И. Гибкие производственные модули механической обработки. Часть 2 [Текст]: учеб. пособие / Г.И. Костюк, О.О. Баранов, М.С. Романов. - Харьков: Нац. аэрокосм. ун-т им. Н.Е. Жуковского «Харьк. авиац. ин-т», 2011. - 88 с.
Гибкие автоматизированные участки механической обработки [Текст]: учеб. пособие. / Г.И. Костюк, О.О. Баранов, И.Г. Левченко, М.С. Романов. - Харьков: Нац. аэрокосм. ун-т "Харьк. авиац. ин-т", 2005. - 162 с.
Загрузочно-ориентирующие устройства роботизированных технологических комплексов [Текст]: учеб. пособие / Г.И. Костюк, О.О. Баранов, И.Г. Левченко. - Харьков: Нац. аэрокосм. ун-т "Харьк. авиац. ин-т", 2004. - 114 с.
Роботизированные технологические комплексы [Текст]: учеб. пособие / Г.И. Костюк, О.О. Баранов, И.Г. Левченко, В.А. Фадеев. - Харьков: Нац. аэрокосм. у-нт «Харьк. авиац. ин-т», 2003. - 214 с.