Dissemination

Publications

P1=LUT; P2=UNIPR; P3=nanoGUNE; P4=UmU; P5=PTI; P6=NIIC; P7=UNSW

  1. P1+P6: T.L. Makarova, I. Zakharchuk, P. Geydt, E. Lahderanta, A.A. Komlev, A.A. Zyrianova, A. Lyubchyk, M.A. Kanygin, O.V. Sedelnikova, V. I. Suslyaev, L.G. Bulusheva, A.V. Okotrub, Magnetic studies of polystyrene/iron-filled multi-wall carbon nanotube composite films, JMMM, doi:10.1016/j.jmmm.2016.01.088.
  2. P1+P2+P5: A.A. Komlev, T.L. Makarova, E.Lahderanta, P.V. Semenikhin, A.I. Veinger, T.V. Tisnek, G. Magnani, G. Bertoni, D. Pontiroli, M. Ricco, Magnetism of aniline modified graphene-based materials, JMMM, doi:10.1016/j.jmmm.2015.11.053.
  3. P1+P6: T. Makarova, I. Zakharchuk, P. Geydt, E. Lahderanta, A. Komlev, A. Zyrianova, A. Lyubchyk, M. Kanygin, O. Sedelnikova, A. Kurenya, L. Bulusheva, A. Okotrub, Assessing carbon nanotube arrangement in polystyrene matrix by magnetic susceptibility measurements, Carbon, 96 (2016), 1077–1083, doi:10.1016/j.carbon.2015.10.065.
  4. P1+P6: T.L. Makarova, I. Zakharchuk, P. Geydt, E. Lahderanta, A.A. Komlev, A.A. Zyrianova, A. Lyubchyk, M.A. Kanygin, O.V. Sedelnikova, V. I. Suslyaev, L.G. Bulusheva, A.V. Okotrub, Correlation between manufacturing processes and anisotropic magnetic and electromagnetic properties of carbon nanotube/polystyrene composites, Composites Part B, 91 (2016), 505–512, doi:10.1016/j.compositesb.2016.01.040.
  5. P3+P6: S. T. Skowron, V. O. Koroteev, M. Baldoni, S. Lopatin, A Zurutuza, A. Chuvilin, E. Besley, Reaction kinetics of bond rotations in graphene, Carbon, 105 (2016), 176–182.
  6. P1+P4+P5+P6: T.L. Makarova, A.L. Shelankov, A.A. Zyrianova, A.I. Veinger, T.V. Tisnek, E. Lähderanta, A.I. Shames, A.V. Okotrub, L.G. Bulusheva, G.N. Chekhova, D.V. Pinakov, I.P. Asanov & Ž. Šljivančanin, Edge state magnetism in zigzag-interfaced graphene via spin susceptibility measurements, Scientific reports, 5, 13382 (2015), doi:10.1038/srep13382.
  7. P1+P5: A.I. Veinger, A.G. Zabrodskii, T.L. Makarova, T.V. Tisnek, S.I. Goloshchapov & P.V. Semenikhin, Detection of impurity diamagnetic susceptibility and its behavior in n-Ge:As in the region of the insulator-metal phase transition, Semiconductors, 49, 10 (2015), 1294–1301.
  8. P1+P5: P.V. Semenikhin, A.I. Veinger, A.G. Zabrodskii, T.L. Makarova, T.V. Tisnek, S.I. Goloshchapov, Determination of the Diamagnetic and Paramagnetic Impurity Magnetic Susceptibility in Ge: As near the Metal Insulator Phase Transition, Journal of Physics Conference Series, 661, 012023 (2015), doi: 10.1088/1742-6596/661/1/012023.
  9. P1+P5: A.I. Veinger, A.G. Zabrodskii, T.L. Makarova, T.V. Tisnek, S.I. Goloshchapov, and P.V. Semenikhin, Low Temperature Transformation from Antiferromagnetic to Ferromagnetic Order in Impurity System Ge:As near the Insulator–Metal Phase Transition, AIP: Conference Proceedings, 1610, 129 (2014), http://dx.doi.org/10.1063/1.4893523.
  10. P1: Makarova, T. L. Magnetic Nanocarbon, In Dekker Encyclopedia of Nanoscience and Nanotechnology, Third Edition. CRC Press: New York, 2014, pp. 2218–2228.
  11. P1: Makarova, T. L. Fullerenes: Magnetic Behavior, In Dekker Encyclopedia of Nanoscience and Nanotechnology, Third Edition. CRC Press: New York, 2014, pp. 1521–1528.
  12. P1+P5: A.I. Veinger, A.G. Zabrodskii, T.V. Tisnek, S.I. Goloshchapov, P.V. Semenikhin. Technique for Magnetic Susceptibility Determination in High Doped Semiconductors by Electron Spin Resonance, AIP: Conference Proceedings, 1610, 119 (2014), http://dx.doi.org/10.1063/1.4893521.
  13. P1+P5: A.I. Veinger, A.G. Zabrodskii, T.V. Tisnek, S.I. Goloshchapov, P.V. Semenikhin, Technique for Magnetic Susceptibility Determination in the High Doped Semiconductors by Electron Spin Resonance, http://arxiv.org/abs/1301.6026.
  14. P1+P5: P.V. Semenikhin, A.I. Veinger, A.G. Zabrodskii, T.V. Tisnek, S.I. Goloshchapov, N.V. Abrosimov. Low temperature ordering caused by exchange interaction in Si:P impurity system near the insulator-metal phase transition. AIP: Conference Proceedings, 1610, 124 (2014), http://dx.doi.org/10.1063/1.4893522.
  15. P1+P5: I.V. Rozhansky, I.V.Krainov, N.S. Averkiev, E. Lahderanta, Resonant enhancement of indirect exchange interaction in semiconductor heterostructures, Phys. Stat. Sol. (a), doi:10.1002/pssa.201300676 (2014).
  16. P2: I. Ciabatti, C. Femoni, M. Gaboardi, M. C. Iapalucci, G. Longoni, D.Pontiroli, M. Riccò, S. Zacchini, Structural rearrangements induced by acid-base reactions in metal carbonyl clusters: the case of [H3–nCo15Pd9C3(CO)38]n– (n = 0-3), Dalton Transactions, 43 (11) (2014), 4388–99, doi: 10.1039/c3dt52527a.
  17. P2: M. Aramini, M. Gaboardi, G. Vlachopoulou, D. Pontiroli et al., Muon spin relaxation reveals the hydrogen storage mechanism in light alkali metal fullerides, Carbon 67, 92 (2014), doi: 10.1016/j.carbon.2013.09.063.
  18. P2: M. Gaboardi, A. Bliersbach, G. Bertoni, M. Aramini et al., Decoration of graphene with nickel nanoparticles: study of the interaction with hydrogen, J. Mat. Chem. A 2, 1039 (2014), doi: 10.1039/c3ta14127f.
  19. P2: M. Aramini, C. Milanese, D. Pontiroli, M. Gaboardi et al., Addition of transition metals to lithium intercalated fullerides enhances hydrogen storage properties, Int. J. Hydrogen Energ. 39, 2124 (2014), doi: 10.1016/j.ijhydene.2013.11.087.
  20. P2: D. Pontiroli, M. Aramini, M. Gaboardi, M. Mazzani et al., Tracking the Hydrogen Motion in Defective Graphene, J. Phys. Chem. C 118 (13), 7110 (2014), doi: 10.1021/jp408339m.
  21. P2: P. Wzietek, T. Mito, H. Alloul, D. Pontiroli et al., NMR Study of the Superconducting Gap Variation near the Mott Transition in Cs3C60, Phys. Rev. Lett. 112, 066401 (2014), doi: 10.1103/PhysRevLett.112.066401.
  22. P3: A. Chuvilin, J. Zubeltzu, A. Zurutuza, E. Bichoutskaia, S. Lopatin, Using transmission electron microscopy to stimulate and understand the formation of defects in graphene, Microscopy&Analysis, 28(7) (2014), 5–9.
  23. P3+P6: V. O. Koroteev, D. A. Bulushev, A. L. Chuvilin, A. V. Okotrub, L. G. Bulusheva, Nanometer-Sized MoS2 Clusters on Graphene Flakes for Catalytic Formic Acid Decomposition, ACS Catal., 4 (2014), 3950−3956, dx.doi.org/10.1021/cs500943b.
  24. P6: D.V. Pinakov, V.A. Logvinenko, G.N. Chekhova, The relationship between properties of fluorinated graphite intercalates and matrix composition, J. Therm. Analys. Calorim., 115 (2014), 503–509.
  25. P1+P6: Asanov, I.P., Bulusheva, L.G., Dubois, M., Yudanov, N.F., Alexeev, A.V., Makarova, T.L., Okotrub, A.V., Graphene Nanochains and Nanoislands in the Layers of Room-Temperature Fluorinated Graphite, Carbon, 59 (2013), 518–529.
  26. P1+P5: Veinger A.I., Zabrodskii A.G., Makarova T.L., Tisnek T.V., Goloshchapov S.I., Semenikhin P.V., Low-temperature variation of magnetic order in a nonmagnetic n-Ge:As semiconductor in the vicinity of the metal-insulator phase transition, Journal of Experimental and Theoretical Physics, 116, 5 (2013), 796–799.
  27. P1+P5: Veinger A.I., Zabrodskii A.G., Makarova T.L., Tisnek T.V., Goloshchapov S.I., and Semenikhin P.V., Low-temperature variation of magnetic order in a nonmagnetic n-Ge:As semiconductor in the vicinity of the metal-insulator phase transition, J. Exp. Theor. Phys., 116, 5 (2013), 796–799.
  28. P1+P5: Veinger A.I., Zabrodskii A.G., Tisnek T.V., Goloshchapov S.I., and Semenikhin P.V., Determination of the magnetic susceptibility of “poor” conductors by electron paramagnetic resonance, Tech. Phys., 58, 12 (2013), 1806–1811.
  29. P1+P5: I.V. Rozhansky, N.S. Averkiev, E. Lahderanta, Fano-type coupling of a bound paramagnetic state with 2D continuum, AIP Conf. Proc., 1566, 335, (2013).
  30. P1+P5: I.V. Rozhansky, N.S. Averkiev, E. Lahderanta, Configuration interaction in delta-doped heterostructures, Low.Temp.Phys, 39, 40 (2013).
  31. P1+P5: I.V. Rozhansky, I.V.Krainov, N.S. Averkiev, E. Lahderanta, Resonant exchange interaction in semiconductors, Phys. Rev., B, 88, 155326 (2013).
  32. P2: D. Pontiroli, M. Aramini, M. Gaboardi, M. Mazzani et al., Ionic conductivity in the Mg intercalated fullerene polymer Mg2C60, Carbon 51, 143 (2013), doi: 10.1016/j.carbon.2012.08.022.
  33. P2: P. Mauron, M. Gaboardi, A. Remhof, A. Bliersbach et al., Hydrogen Sorption in Li12C60, J. Phys. Chem. C 117, 22598 (2013), doi: 10.1021/jp408652t.
  34. P2: H. Alloul, Y. Ihara, T. Mito, P. Wzietek, M. Aramini, D. Pontiroli and M. Riccò, NMR investigation of the pressure induced Mott transition to superconductivity in Cs3C60 isomeric compounds, Journal of Physics:ConferenceSeries, 449, 012030 (2013), doi: 10.1088/1742-6596/449/1/012030.
  35. P2: M. Riccò, M. Aramini, M. Mazzani, D. Pontiroli et al., Muons probe magnetism and hydrogen interaction in graphene, Phys. Scr. 88, 068508 (2013), doi: 10.1088/0031-8949/88/06/068508.
  36. P3: Wei, D.; Haque, S.; Andrew, P.; Kivioja, J.; Ryhaenen, T.; Pesquera, A.; Centeno, A.; Alonso, B.; Chuvilin, A.; Zurutuza, A., Ultrathin rechargeable all-solid-state batteries based on monolayer graphene, Journal of Materials Chemistry A, 1 (2013), 3177–3181, doi: 10.1039/C3TA01183F.
  37. P3: Meyer, J. C.; Eder, F.; Kurasch, S.; Skakalova, V.; Kotakoski, J.; Park, H. J.; Roth, S.; Chuvilin, A.; Eyhusen, S.; Benner, G.; Krasheninnikov, A. V.; Kaiser, U., Accurate Measurement of Electron Beam Induced Displacement Cross Sections for Single-Layer Graphene, Physical Review Letters, 110, 239902 (2013), doi: http://dx.doi.org/10.1103/PhysRevLett.108.196102.
  38. P3: Santana, A.; Zobelli, A.; Kotakoski, J.; Chuvilin, A.; Bichoutskaia, E., Inclusion of radiation damage dynamics in high-resolution transmission electron microscopy image simulations: The example of graphene, Physical Review, B, 87, 9 (2013).
  39. P3: Zubeltzu, J.; Chuvilin, A.; Corsetti, F.; Zurutuza, A.; Artacho, E., Knock-on damage in bilayer graphene: Indications for a catalytic pathway, Physical Review, B, 88 (2013).
  40. P6: A.V. Okotrub, N.F. Yudanov, I.P. Asanov, D,V, Vyalikh, L.G. Bulusheva, Anisotropy of Chemical Bonding in Semifluorinated Graphite C2F Revealed with Angle-Resolved X-ray Absorption Spectroscopy, ACS Nano 7 (2013), 65–74.
  41. P6: M.A. Kanygin, O.V. Sedelnikova, I.P. Asanov, L.G. Bulusheva, A.V. Okotrub, P.P. Kuzhir, A.O. Plyushch, S.A. Maksimenko, K.N. Lapko, A.A. Sokol, O.A. Ivashkevich, and Ph. Lambin, Effect of nitrogen doping on the electromagnetic properties of carbon nanotube-based composites, J. Appl. Phys., 113 (2013), 144315.
  42. P6: Vyalikh, L.G. Bulusheva, G.N. Chekhova, D.V. Pinakov, A.V. Okotrub, U. Scheler, Fluorine patterning in room-temperature fluorinated graphite determined by solid-state NMR and DFT, J. Phys. Chem., C 117 (2013), 7940–7948.
  43. P6: D.V. Pinakov, Y.V. Shubin, G.N. Chekhova, Synthesis and properties of (C2Fx Br0.01·yCH3COOC2H5)n (0.5 < x < 1.0) intercalation compounds, Inorg. Mater., 49 (2013) 528–533.
  44. P1+P5: Ziminov V., Zakharova I., Aleshin A., Makarova T., Fullerene Based Organic-Inorganic Bulk Heterojunction Exhibiting Rectifying Behavior, Journal of Nanoelectronics and Optoelectronics, 7(4) (2012), 410–414.
  45. P1+P6: T.L. Makarova, V.S. Zagaynova, G. Inan, A. V. Okotrub, G.N. Chekhova, D.V. Pinakov, L.G. Bulusheva, Structural Evolution and Magnetic Properties of Underfluorinated C2F, Journal of Superconductivity and Novel Magnetism, 25, 1 (2012), 79–83.
  46. P1+P5: T.L. Makarova, A.L. Shelankov, S.B. Lyubchik, I.T. Serenkov, V.I. Sakharov, Induced Ferromagnetism in Helium Bombarded Graphite, Journal of Nanoscience and Nanotechnology, 12 (2012), 5051–5053.
  47. P1+P5: Veinger A.I., Zabrodskii A.G., Tisnek T.V., and Goloshchapov S.I., Angular and Temperature-related Specific Features of the Interaction between Light and Heavy Holes in Weakly Doped p-Ge:Ga at Low Temperatures, Journal of Physics: C, 376, 1, 012015 (2012).
  48. P1+P5: I.V. Rozhansky, N.S. Averkiev, E. Lahderanta, Tunneling magnetic effect in heterostructures with paramagnetic impurities, Phys. Rev., B, 85, 075315 (2012).
  49. P2: P.  Mauron, A. Remhof, A. Bliersbach, A. Borgschulte et al., Reversible hydrogen absorption in sodium intercalated fullerenes, Int. J. Hydrogen Energ., 37(19), 14307 (2012), doi: 10.1016/j.ijhydene.2012.07.045.
  50. P3: Chamberlain, T. W.; Biskupek, J.; Rance, G. A.; Chuvilin, A.; Alexander, T. J.; Bichoutskaia, E.; Kaiser, U.; Khlobystov, A. N., Size, Structure, and Helical Twist of Graphene Nanoribbons Controlled by Confinement in Carbon Nanotubes, Acs Nano, 6 (2012), 3943–3953.
  51. P3: Meyer, J. C.; Eder, F.; Kurasch, S.; Skakalova, V.; Kotakoski, J.; Park, H. J.; Roth, S.; Chuvilin, A.; Eyhusen, S.; Benner, G.; Krasheninnikov, A. V.; Kaiser, U., Accurate Measurement of Electron Beam Induced Displacement Cross Sections for Single-Layer Graphene, Physical Review Letters, 108 (2012).
  52. P4: H. Pardo, N.D. Khan, R. Faccio, F.M. Araujo-Moreira, L. Fernandez-Werner, T. Makarova, A.W. Mombru, Raman characterization of bulk ferromagnetic nanostructured graphite, Physica B-Condensed Matter, 407 (2012), 3206–3209.
  53. P6: D.V. Pinakov, N.I. Alferova, G.N. Chekhova, Synthesis and IR spectroscopic characterization of fluorinated graphite intercalation compounds with chlorinated derivatives of methane and ethane”, Inorg. Mater., 48 (2012), 1153–1157.
  54. P6: A.V. Okotrub, N.F. Yudanov, V.A. Tur, I.P. Asanov, Y.V, Shubin, D.V. Vyalikh, L.G. Bulusheva, Perforation of graphite in boiling mineral acid, Phys. Status Solidi, b 249 (2012), 2620–2624.
  55. P6: O.V. Sedelnikova, L.G. Bulusheva, A.V. Okotrub, Curvature-induced optical transitions in graphene, Fuller. Nanotubes, Carbon Nanostruct., 20 (2012), 558–562.

Conference participated

68

Invited talks

P1=LUT; P2=UNIPR; P3=nanoGUNE; P4=UmU; P5=PTI; P6=NIIC; P7=UNSW

  1. P1: T.L. Makarova, Tabby graphene: realization of edge states at interfaces, NanoPt2016, NanoPortugal International Conference, Lissabon, Portugal, February 16–19, 2016.
  2. P1: T.L. Makarova, Invited lectures “Low-dimensional magnetism”, European training Network ”Thinface”, Universita` di Milano-Bicocca, Italy, February, 2016.
  3. P3: A. Chuvilin, R. Hillenbrand, Optical, ion and electron microscopies – a synergy of combined application, Conference ASCO-NANOMAT, Vladivostok, Russia, August 20, 2015.
  4. P3: A. Chuvilin, Accessing kinetics of structural rearrangements in graphene via direct atomic imaging, International congress “Microscopy at the Frontiers of Science – MFS2015”, Porto, Portugal, September 9–11, 2015.
  5. P3: A. Chuvilin, Low Voltage Cs-corrected TEM for Nanocarbon Materials, Workshop TEMUCA2015, Cadiz, Spain, July 20, 2015.
  6. P1: T.L. Makarova, Magnetism: From Molecules to Graphene-Based Materials, International Conference of Molecule-based Magnetism, St.Petersburg, Russia, July 5–10, 2014.
  7. P4: A. Shchukarev, Application of XPS for surface inverstigation, “X-ray and electron spectra and chemical bond”, Novosibirsk, Russia, November 7–11, 2013.
  8. P3: A. Chuvilin, R. Hillenbrand, On combined application of electron, ion and electron microscopies, Conference “Methods for investigation of the composition and structure of functional materials”, Novosibirsk, Russia, October 21, 2013.
  9. P4+P5: Veynger A.I., Zabrodskii A.G., Makarova T.L., Tisnek T.V., Goloshapov S.I., Semenihin P.V., Observation of ferro-and antiferromagnetic ordering of the spin system Ge: As near the phase transition insulator -metal transition, XI Russian Conference on the Physics of Semiconductors. Saint Petersburg , September 16–20, 2013.
  10. P3: S. Lopatin, A. Chuvilin, Optimization of imaging conditions for atomic resolution in Titan TEM to minimize radiation damage and to study low angle boundaries in graphene-like materials, Trends in Nanotechnology International Conference, Seville, Spain, September 10, 2013.
  11. P3: A. Chuvilin, Application of low voltage Cs-corrected TEM for nanocarbon materials, ASCO-NANOMAT II, Vladivostok, Russia, August 25, 2013.
  12. P1+P5: B. Aronzon, V. Rylkov, S. Nikolaev, V. Tugushev, S. Caprara, N. Perov, A. Semisalova, A. Lashkul, E. Lahderanta, Room temperature ferromagnetism and anomalous Hall effect in Si1-xMnx alloys with high Mn content,  Joint International Magnetic Symposia JEMS2012, Parma, Italy, September 9–14, 2012.
  13. P3: A. Chuvilin, Application of low voltage Cs-corrected TEM for nanocarbon materials, International Conference “Molecular aspects of solid state and interfacial electrochemistry (MolE)”, Dubna, Russia, August 28, 2012.
  14. P6: A.V. Okotrub, M.A. Kanygin, O.V. Sedelnikova, L.G. Bulusheva, V.V. Kubarev, D.S. Bychanok, P.P. Kuzhir, S.A. Maksimenko, Anisotropic electromagnetic response of carbon nanotube in terahertz and gigahertz frequency range, Third International Workshop “Nanocarbon Photonics and Optoelectronics”, Holiday Centre “Huhmari” Polvijarvi, Finland, July 29 – August 4, 2012.
  15. P4: T.L. Makarova, Invited tutorial “Magnetic carbon: molecules and materials”, Summer School, Krytun, Poland, June, 2012.
  16. P4: T.L. Makarova, Invited tutorial “Semi-fluorinated graphite: self-organized magnetic carbon”, Summer School “Frontiers in Science and Technology of Carbon Nano-Materials”, Krytun, Poland, June, 2012.
  17. P6: A.V. Okotrub, L.G. Bulusheva, I.P. Asanov, G.M. Chehova, T.L. Makarova, Structure and electronic properties of fluorographite materials, German-Russian Conference on Fundamentals and Applications of Nanoscience, Freie Universitat Berlin, Germany, May 19–21, 2012.
  18. P3: A. Chuvilin, Inclusion of radiation damage dynamics in high resolution transmission electron microscopy simulations, Workshop “Atomic structure of nanosystemsfrom first-principles simulations and microscopy experiments”, Helsinki, Finland, May 5, 2012.

Conference organized

  1. MagNonMag kick-off meeting, Ioffe Physico-Technical Institute, St. Petersburg, Russia, June 14–16, 2012.
  2. 36th Conference on Low-Temperature Physics, Ioffe Physico-Technical Institute St. Petersburg, Russia, July 26, 2012.
  3. Summer School for Young Scientists “Nanocarbon and nanodiamond materials in electromagnetic and biomedical applications. Modern methods of commercialization of research”, Altai Republic, Russia, August 7–12, 2012.
  4. The Parma coordinator (Prof. Mauro Riccò) and his group (D. Pontiroli , M. Mazzani , M. Choucair, M. Aramini, M. Gaboardihas) have been in the organizing committee of the international conference JEMS2012 (Joint European Magnetic Symposia, http://www.fis.unipr.it/jems2012/) which took place in Parma from 9 to 14 September 2012.
  5. LUT–PTI seminar, Lappeenranta, Finland, December 10–12, 2012.
  6. International Winter School on Physics of Semiconductors, Ioffe Physico-Technical Institute, St. Petersburg, Russia, March 1–4, 2013.
  7. 7th Russian-French Seminar on Nanosciences and Nanotechnologies, Novosibirsk, Russia, June 3–6, 2013.
  8. MagNonMag midterm meeting, San-Sebastian, Spain, September 9–13, 2013.
  9. XI Russian Conference “Physics of Semiconductors”, Ioffe Physico-Technical Institute, St. Petersburg, Russia, September, 16–20, 2013.
  10. All-Russian Conference “X-ray and electron spectra and chemical bond”, Novosibirsk, Russia, November 7–11, 2013.
  11. LUT–PTI seminar, Lappeenranta, Finland, December 12–14, 2013.
  12. International Winter School on Physics of Semiconductors, Ioffe Physico-Technical Institute, St. Petersburg, Russia, February 28 – March 3, 2014.
  13. International Winter School on Physics of Semiconductors, Ioffe Physico-Technical Institute, St. Petersburg, Russia, February 27 – March 3, 2015.
  14. International Winter School on Physics of Semiconductors, Ioffe Physico-Technical Institute, St. Petersburg, Russia, February 26 – March 1, 2016.
  15. Final MagNonMag Workshop, Imatra – Lappeenranta, Finland, August 1–5, 2016.

PhD Theses

  1. Valeria Zagaynova, PhD thesis in Physics, Carbon-Based Magnetic Nanomaterials, Umeå University, Umeå, Sweden, Supervisor T.L. Makarova, 2012.
  2. O.V. Sedelnikova, PhD thesis in Physical Chemistry, Physics of Condense Matter, Theoretical study of dielectrical properties of low-dimensional carbon forms, NIIC, Novosibirsk, Russia, Supervisor Bulusheva L.G., 2012.
  3. M.A. Kanygin, PhD thesis in Physical Chemistry, Anisotropy of the structure and electronic properties of materials based on aligned carbon nanotubes, NIIC, Novosibirsk, Russia, Supervisor Okotrub A.V., 2014.
  4. Matteo Aramini, PhD thesis in Material Science, The Hydrogen Storage in Alkali-Transition metal Fullerides, Parma, Italy, Supervisor M. Ricco, 2014.
  5. Mattia Gaboardi, PhD thesis in Physics, Hydrogen storage in light alkali-cluster intercalated Fullerides, Parma, Italy, Supervisor M. Ricco, 2014.

Master Theses

  1. Chernyaev A., Investigation of the impurity magnetic susceptibility 4H SiC: N near the phase transition insulator – metal, Ioffe PTI, St. Petersburg, Russia, Supervisor Veinger A.I., 2012.
  2. Kovalev E. B. Investigation of n-Si near the metal – insulator by electron paramagnetic resonance, Ioffe PTI, St. Petersburg, Russia, Supervisor Veinger A.I., 2012.
  3. V.A. Tur, Structure and properties of chemically modified graphite, NIIC, Novosibirsk, Russia, 2012.
  4. Giglio, Hydrogen storage in Li12C60 fulleride investigated by structural analysis, Parma, Italy, 2013.
  5. Magnani, Synthesis and characterization of Ni-decorated graphene for hydrogen storage, Parma, Italy, 2013.
  6. Virdis, Synthesis and structural study of magnesium fullerides for hydrogen-storage applications, Parma, Italy, 2013.
  7. Riva, Study of ionic conductivity in lithium fullerides”, Parma, Italy, 2013.
  8. Ali, Raman investigation of nanographites derived from nanodiamonds, Umea, Sweden, 2013.

Bachelor’s Theses

  1. Nicola Sarzi Amadè, Ammonia storage in lithium fullerides, Parma, Italy, 2014.
  2. Silvio Scaravonati, Conductivity measurements on intercalated fullerides, Parma, Italy, 2014.

Award

  1. PTI (ESR) S. Pavlov, project “Development of organic field effect transistor based on fullerene nanostructures as elements of an integrated organic electronics “, winner of the best innovative projects in science and higher education in in the nomination “Best Scientific Innovative idea”, St. Petersburg, 2013.
  2. PTI (ESR) S. Pavlov, Finalist certificate XV competition of business ideas, scientific and technical development and research projects “Young , Daring, Promising ” for the research project “A study of light and electric field stimulated recharges in fullerene nanowires for creating the elements of molecular electronics “, St. Petersburg, 2012.
  3. NIIC (ESR) D. Gorodetsky, winner of the program “Young researchers in innovation competition”, 2013.