Source: https://faculty.skoltech.ru/people/albertnasibulin
Timestamp: 2019-04-21 04:14:44+00:00

Document:
Dr. Sc. Albert G. Nasibulin is a Professor at Skolkovo Institute of Science and Technology and an Adjunct Professor at the Department of Applied Physics of Aalto University School of Science. He held a post of the Academy Research Fellow in Academy of Finland from 2006 to 2011. Since 2018 he is a Professor of the Russian Academy of Sciences. He got his PhD in Physical Chemistry (1996) at Kemerovo State University (Russia) and Doctor of Science (Habilitation, 2011) at Saint-Petersburg Technical State University (Russia). He has specialized in the aerosol synthesis of nanomaterials (nanoparticles, carbon nanotubes and tetrapods), investigation of their growth mechanism and their applications. At the moment his main research is devoted to transparent, flexible, stretchable and conductive single-walled CNT films. He has a successful background in an academic research with more than 240 peer-reviewed scientific publications and 31 patents. He is a co-founder of three companies: Canatu Ltd. (spin-off from Helsinki University of Technology, Finland) and CryptoChemistry and Novaprint (spin-offs from Skolkovo Institute of Science and Technology, Moscow, Russia).
Google scholar: H-index 48; citations 8777. Scopus: H-index: 42; citations 6605. (5.03.2019).
Synthesis of nanomaterials such as nanoparticles, carbon nanotubes, graphene structures, metal oxide nanowires by aerosol and substrate CVD synthesis methods.
Kinetic and mechanistic investigations of the nanomaterial growth.
Applications of electrically conductive, transparent, flexible and streatcheble carbon nanotube films in electronics and electrochemical applications (photovoltaic devices, supercapacitors and OLEDs).
Composites based on carbon nanomaterials.
Peter Karlsen, Mikhail V. Shuba, Chris Beckerleg, Dzmitry I. Yuko, Polina P. Kuzhir, Sergey A. Maksimenko, Vitaly Ksenevich, Ho Viet, Albert G. Nasibulin, Reshef Tenne and Euan Hendry (2018) Influence of nanotube length and density on the plasmonic terahertz response of single-walled carbon nanotubes. Journal of Physics D: Applied Physics, 51, 014003.
Piatrusha, S.U., Ginzburg, L.V., Tikhonov, E.S., Shovkun, D.V., Koblmüller, G., Bubis, A.V., Grebenko, A.K., Nasibulin, A.G., Khrapai, V.S. (2018) Noise insights into electronic transport. JETP Letters 2018, 71-83.
Evgenia Р. Gilshteyn, Shaoting Lin, Vladislav A. Kondrashov, Daria S. Kopylova, Alexey P. Tsapenko, Anton S. Anisimov, A. John Hart, Xuanhe Zhao, Albert G. Nasibulin (2018) A one-step method of hydrogel modification by single-walled carbon nanotubes for highly stretchable and transparent electronics. ACS Applied Materials and Interfaces 10(33), 28069-28075.
L. Martínez-Sarti, A. Pertegás, M. Monrabal-Capilla, E. Gilshteyn, I. Varjos, E. I. Kauppinen, A. G. Nasibulin, M. Sessolo and H. J. Bolink. (2016) Flexible light-emitting electrochemical cells with single-walled carbon nanotube anodes. Organic Electronics. 30, 36–39.
Konstantin G. Mikheev, Aleksandr S. Saushin, Ruslan G. Zonov, Albert G. Nasibulin, Gennady M. Mikheev. (2015) Photon-drag in single-walled carbon nanotube and silver-palladium films: the effect of polarization. J. Nanophoton. 10(1), 012505.
Alexandra L. Gorkina, Alexey P. Tsapenko, Evgenia P. Gilshteyn, Tatiana S. Koltsova, Tatiana V. Larionova, Alexander Talyzin, Anton S. Anisimov, Ilya V. Anoshkin, Esko I. Kauppinen, Oleg V. Tolochko, Albert G. Nasibulin (2016) Transparent and Conductive Hybrid Graphene/Carbon Nanotube Films, Carbon 100, 501–507.
Adinath M. Funde, Albert G. Nasibulin, Hashmi Gufran Syed, Anton S. Anisimov, Alexey Tsapenko, Peter Lund, J. D. Santos, I. Torres, J. J. Gandía, J. Cárabe, and A. D. Rozenberg, Igor A. Levitsky (2016) Carbon nanotube – amorphous silicon hybrid solar cell with improved conversion efficiency. Nanotechnology. 27(18) 185401.
Petri Kanninen, Nguyen Dang Luong, Le Hoang Sinh, Ilya V Anoshkin, Alexey Tsapenko, Jukka Seppälä, Albert G Nasibulin and Tanja Kallio (2016) Transparent and flexible high-performance supercapacitors based on single-walled carbon nanotube films. Nanotechnology 27(23) 235403.
and thickness of graphene layers on copper substrates. Metal Science and Heat Treatment, 58(1–2) 40-45.
Mohammad Tavakkoli, Tanja Kallio, Olivier Reynaud, Albert G. Nasibulin, Jani Sainio, Hua Jiang, Esko I. Kauppinen and Kari Laasonen (2016) Maghemite nanoparticles decorated on carbon nanotubes as efficient electrocatalysts for the oxygen evolution reaction. J. Mater. Chem. A, 2016, 4, 5216–5222.
Anoshkin I., Nefedova I., Nefedov I.S., Lyubchenko D., Nasibulin A., Raisanen A. (2016) Resistivity and optical transmittance dependence on length and diameter of nanowires in silver nanowire layers in application to transparent conductive coatings. Micro & Nano Letters – 11(7), 2016, 343–347.
S. D. Shandakov, M. V. Lomakin, and A. G. Nasibulin (2016) The Effect of the Environment on the Electronic Properties of Single-Walled Carbon Nanotubes. Technical Physics Letters, 2016, 42(11), 1071–1075. Письма в ЖТФ. 42(21) 23-31.
Evgenia P. Gilshteyn, Tanja Kallio, Petri Kanninen, Ekaterina O. Fedorovskaya, Anton S. Anisimov and Albert G. Nasibulin (2016) Stretchable and transparent supercapacitors based on aerosol synthesized single-walled carbon nanotube films, RSC Adv., 2016, 6, 93915.
D S Kopylova, N Yu Boldyrev, V Ya Iakovlev, Yu G Gladush and A G Nasibulin (2016) A bolometer based on single-walled carbon nanotubes and hybrid materials. QUANTUM ELECTRONICS, 2016, 46 (12), 1163-1169. Квант. электрон., 46:12 (2016), 1163–1169.
Alexey V. Kosobutsky, Sergey D. Shandakov, Albert G. Nasibulin (2016) Computer simulation of functionalized carbon nanotubes and graphene. Science Evolution 1(2) 114-125.
Generalov, A.A., Anoshkin, I.V., Erdmanis, M., Lioubtchenko, D.V., Ovchinnikov, V., Nasibulin, A.G., and Räisänen, A.V. (2015) Carbon nanotube network varactor, Nanotechnology 26, 045201.
Albert G. Nasibulin, Adinath M. Funde, Ilya V. Anoshkin, and Igor A. Levitsky. All-carbon nanotube diode and solar cell statistically formed from macroscopic network. NanoResearch8(9), 2800-2809.
Koltsova, T. S., Nasibulin, A. G., Tolochko, O. V., Novel composite materials copper – carbon nanofibers, Scientific and technical bulletin of St. Petersburg State Polytechnic University 3, 125-131 (in Russian) (2010).
April, 2018: Professor of Russian Academy of Sciences.
June, 2017: the best professor of SkolTech “Teaching activities”.
September, 2011: Smoluchowski award for the contribution to field of “Aerosol synthesis and mechanistic investigations of carbon nanotubes” at European Aerosol Conference in Manchester, UK.
September, 2010: FAAR (Finnish Association for Aerosol Research) awarded for Excellent work in Aerosol Science at International Aerosol Conference in Helsinki, Finland.
Course description: The course covers the subject of carbon nanomaterials (fullerenes, nanodimond, nanotubes, and graphene). The history of carbon compounds since antiquity till our days starting from charcoal to carbon nanotubes and graphene will be reviewed. The students will have opportunity to synthesize carbon nanotubes (by aerosol and CVD methods) and graphene, to observe the materials in transmission (TEM) and scanning (SEM) electron microscopes as well as by an scanning tunnelling (STM) and atomic force (AFM) microscopes and to study optical and electrical properties of the produced carbon nanomaterials.
Course description: The course will introduce the basic phenomena of aerosol science, particle formation in the gas phase and their behavior, concepts and measurement techniques for the aerosol particles. Students will synthesize (carbon nanotubes, NaCl, metal, metal oxide and polymer) nanoparticles by two aerosol techniques: gas-to-particle and liquid-to-particle conversions. Students will be trained to operate spark-discharge aerosol synthesis reactor for production of nanoparticles and single-walled carbon nanotubes and spray drying and pyrolysis reactors. Students will perform the on-line measurements of the number size distribution of aerosol synthesized nanoparticles by differential mobility analyzer (size range: 2-1000 nm). Students will become familiar with processes of the aerosol particle collection (filtration, electrostatic precipitation, thermophoretic precipitation).

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