Oleg Nerushev

Office: 

45

Lab: 

43 and 44

Office Phone: 

+44(0)131 650 4914

Lab Phone: 

+44(0)131 650 7377 (lab 43) / +44(0)131 650 4895 (lab 44)

Present Employment:

Research Associate, School of Chemistry, Edinburgh University (since 9/2007)

Previous Employment:

Visiting Scientist, Dept. of Physics, Gothenburg University, Sweden (2000-2007)
Senior Researcher, Institute of Thermophysics, Novosibirsk, Russia (1995-2007)
Researcher, Institute of Thermophysics, Novosibirsk, Russia (1988-1995)

I graduated from the Department of Physics of Novosibirsk State University in USSR in 1982. After that I worked in the Institute of Thermophysics in Novosibirsk (Russia) in different positions and different fields - from gas dynamics to plasma physics and chemical physics. In 1995 I received a PhD in Physics and Math Sciences with thesis "Fullerenes polarizability in gas phase"(in Russian) based in Refs [5-9] in Publication list below. Since year 2000 I worked part time in Sweden in Atomic Physics group led by Eleanor Campbell in Gothenburg University and Chalmers University of Technology. From this point my interests were shifted to carbon nanotube synthesis, characterization and application.
At the moment we continue experimental work after a long period of labs refurbishment. Our office (room 45) is next to labs where we prepare catalysts for nanotubes and grow nanotubes (lab 44) or measure the results with AFM or micro-Raman/IR system (lab 43).

Publication list.

2012

66.

Determination of the Bending Rigidity of Graphene via Electrostatic Actuation of Buckled Membranes.
Niklas Lindahl, Daniel Midtvedt, Johannes Svensson, Oleg A. Nerushev, Niclas Lindvall, Andreas Isacsson, and Eleanor E. B. Campbell; Nano Letters, 2012, 12, 3526-3531

65.

Investigation of products of thermal methane conversion in hydrocarbon mixtures by mass spectrometry
Smovzh, DV; Nerushev, OA ; Koverznev, MP ; Belikov, AE; Novopashin, SA ; Sakhapov, SZ ; Zamchii, AO ; Zaikovskii, AV J. of Engineering Thermophysics, 2012, 21, 131-135.

64.

Optical in situ characterisation of carbon nanotube growth.
Ek-Weis J.; Nerushev O. A.; Campbell E. E. B. Int. J. of Nanotechnology 2012, 9, 3-17.
 

2011

63.

Carbon Nanotube Field Effect Transistors with Suspended Graphene Gates.
Johannes Svensson, Niklas Lindahl, Hoyeol Yun, Miri Seo, Daniel Midtvedt, Yury Tarakanov, Niclas Lindvall, Oleg Nerushev, Jari Kinaret, SangWook Lee, and Eleanor E. B. Campbell Nano Letters 2011, 11, 3569 -3575.

62.

Direct Deposition of Aligned Single Walled Carbon Nanotubes by Fountain Pen Nanolithography
K. M. Strain, T. Yeshua, A. V. Gromov, O. Nerushev, A. Lewis, E.E.B. Campbell Mater. Express 2011, 1, 4, 279-284.
 

2010

61.

Growth of Aligned MWNT Arrays Using a Micrometer Scale Local-Heater at Low Ambient Temperature.
Dittmer, S.; Ek-Weis, J.; Nerushev, O. A.; Campbell, E. E. B. Journal of Nanoscience and Nanotechnology, 2010, 10, 4015.

60.

Dispersing Individual Single-Wall Carbon Nanotubes in Aqueous Surfactant Solutions below the cmc.
Angelikopoulos, P.; Gromov, A.; Leen, A.; Nerushev, O.; Bock, H.; Campbell, E. E. B. Journal of Physical Chemistry C, 2010, 114, 2.

59.

Methane Conversion into Hydrogen and Carbon Nanostructures.
Belikov, A. E.; Mal'tsev, V. A.; Nerushev, O. A.; Novopashin, S. A.; Sakhapov, S. Z.; Smovzh, D. V. Journal of Engineering Thermophysics 2010, 19, 23.
 

2009

58.

Size distribution function for iron clusters formed during the synthesis of carbon nanotubes by Fe(CO)5 decomposition.
Nerushev, OA; Novopashin, SA; Smovzh, DV. Tech.Phys.Let.(2009), 35, 203-206

57.

The properties of carbon-carbonic condensate synthesized in the plasma arc.
Belikov, A. E.; Zaikovsky, A. V.; Mal'tsev, V. A.; Nerushev, O. A.; Novopashin, S. A.; Pakharukova, V. P.; Snytnikov, P. V.; Sakhapov, C. Z.; Smovzh, D. V. Thermophysics and Aeromechanics 2009, 16, 647.

2008

56.

Local heating method for growth of aligned carbon nanotubes at low ambient temperature.
Dittmer, S.; Mudgal, S.; Nerushev, O. A.; Campbell, E. E. B. Low Temperature Physics(2008), 34(10), 834-837.

55.

In situ Raman studies of single-walled carbon nanotubes grown by local catalyst heating.
Dittmer, S.; Olofsson, N.; Ek Weis, J.; Nerushev, O. A.; Gromov, A. V.; Campbell, E. E. B., Chemical Physics Letters(2008), 457(1-3), 206-210.
 

2007

54.

Dielectrophoresis-induced separation of metallic and semiconducting single-wall carbon nanotubes in a continuous flow microfluidic system.
Mattsson, Mattias; Gromov, Andrei; Dittmer, Staffan; Eriksson, Emma; Nerushev, Oleg A.; Campbell, Eleanor E. B. Journal of Nanoscience and Nanotechnology(2007), 7(10), 3431-3435.

53.

In situ growth rate measurements during plasma-enhanced chemical vapour deposition of vertically aligned multiwall carbon nanotube films.
Jönsson, M.; Nerushev, O. A.; Campbell, E. E. B. Nanotechnology (2007), 18(30), 305702/1-305702/5

52.

Nucleation and aligned growth of multi-wall carbon nanotube films during thermal CVD.
Yao, Y.; Falk, L. K. L.; Morjan, R. E.; Nerushev, O. A.; Campbell, E. E. B. Carbon (2007), 45(10), 2065-2071

51.

Dc plasma-enhanced chemical vapor deposition growth of carbon nanotubes and nanofibers: in situ spectroscopy and plasma current dependence.
Jönsson, M.; Nerushev, O. A.; Campbell, E. E. B. Applied Physics A: Materials Science & Processing (2007), 88(2), 261-267.
 

2006

50. Field emission induced deformations in SiO2 during CVD growth of carbon nanotubes.
Svensson, J.; Bulgakova, N. M.; Nerushev, O. A.; Campbell, E. E. B. Physica Status Solidi B: Basic Solid State Physics (2006), 243(13), 3524-3527.

49.

Marangoni effect in SiO2 during field-directed chemical vapor deposition growth of carbon nanotubes.
Svensson, J.; Bulgakova, N. M.; Nerushev, O. A.; Campbell, E. E. B. Physical Review B: Condensed Matter and Materials Physics (2006), 73(20), 205413/1-205413/5.

48.

Low ambient temperature CVD growth of carbon nanotubes.
Dittmer, S.; Nerushev, O. A.; Campbell, E. E. B. Applied Physics A: Materials Science & Processing (2006), 84(3), 243-246.

47.

Fabrication of individual vertically aligned carbon nanofibres on metal substrates from prefabricated catalyst dots.
Kabir, M. S.; Morjan, R. E.; Nerushev, O. A.; Lundgren, P.; Bengtsson, S.; Enoksson, P.; Campbell, E. E. B. Nanotechnology (2006), 17(3), 790-794.
 

2005

46.

Cross-sectional TEM investigation of nickel-catalysed carbon nanotube films grown by plasma-enhanced CVD.
Yao, Y.; Falk, L. K. L.; Morjan, R. E.; Nerushev, O. A.; Campbell, E. E. B. Journal of Microscopy (Oxford, United Kingdom) (2005), 219(2), 69-75.

45.

Covalent amino-functionalization of single-wall carbon nanotubes.
Gromov, Andrei; Dittmer, Staffan; Svensson, Johannes; Nerushev, Oleg A.; Perez-Garcia, Sergio Alfonso; Licea-Jimenez, Liliana; Rychwalski, Rodney; Campbell, Eleanor E. B Journal of Materials Chemistry (2005), 15(32), 3334-3339.

44.

Plasma-enhanced chemical vapor deposition growth of carbon nanotubes on different metal underlayers.
Kabir, M. S.; Morjan, R. E.; Nerushev, O. A.; Lundgren, P.; Bengtsson, S.; Enokson, P.; Campbell, E. E. B. Nanotechnology (2005), 16(4), 458-466.
 

2004

43.

Highly efficient electron field emission from decorated multiwalled carbon nanotube films.
Sveningsson, M.; Morjan, R. E.; Nerushev, O. A.; Campbell, Eleanor E. B.; Malsch, D.; Schaefer, J. A Applied Physics Letters (2004), 85(19), 4487-4489

42.

A Three-Terminal Carbon Nanorelay.
Lee, Sang Wook; Lee, Dong Su; Morjan, Raluca E.; Jhang, Sung Ho; Sveningsson, Martin; Nerushev, O. A.; Park, Yung Woo; Campbell, Eleanor E. B. Nano Letters (2004), 4(10), 2027-2030

41.

Synthesis of carbon nanotube films by thermal CVD in the presence of supported catalyst particles. Part II: the nanotube film.
Yao, Y.; Falk, L. K. L.; Morjan, R. E.; Nerushev, O. A.; Campbell, E. E. B. Journal of Materials Science: Materials in Electronics (2004), 15(9), 583-594.

40.

Synthesis of carbon nanotube films by thermal CVD in the presence of supported catalyst particles. Part I: The silicon substrate/nanotube film interface.
Yao, Y.; Falk, L. K. L.; Morjan, R. E.; Nerushev, O. A.; Campbell, E. E. B. Journal of Materials Science: Materials in Electronics (2004), 15(8), 533-543

39.

Electron field emission from multiwalled carbon nanotubes.
Sveningsson, M.; Morjan, R. E.; Nerushev, O.; Campbell, E. E. B. Carbon (2004), 42(5-6), 1165-1168

38.

Viscosity of H2-CO2 Mixtures at (500, 800, and 1100) K.
Mal'tsev, Vasilii A.; Nerushev, Oleg A.; Novopashin, Sergey A.; Radchenko, Vyacheslav V.; Licht, William R.; Miller, Edwin J.; Parekh, Vipul S. Journal of Chemical and Engineering Data (2004), 49(3), 684-687.

37.

The Role of Diffusion Current in the Formation of Spherical Striations.
Nerushev, O. A.; Novopashin, S. A.; Radchenko, V. V.; Sakhapov, S. Z. Technical Physics Letters (Translation of Pis'ma v Zhurnal Tekhnicheskoi Fiziki) (2004), 30(2), 106-108

36.

High growth rates and wall decoration of carbon nanotubes grown by plasma-enhanced chemical vapor deposition.
Morjan, R. E.; Maltsev, V.; Nerushev, O.; Yao, Y.; Falk, L. K. L.; Campbell, E. E. B. Chemical Physics Letters (2004), 383(3,4), 385-390.

35.

Growth of carbon nanotubes from C60.
Morjan, R. E.; Nerushev, O. A.; Sveningsson, M.; Rohmund, F.; Falk, L. K. L.; Campbell, E. E. B. Department of Experimental Physics, Goeteborg Applied Physics A: Materials Science & Processing (2004), 78(3), 253-261.
 

2003

34.

Vertically aligned carbon nanotubes synthesized by direct current plasma chemical vapour deposition.
Morjan, R. E.; Maltsev, V.; Gromov, A.; Nerushev, O. A.; Campbell, E. E. B. Proceedings - Electrochemical Society (2003), 2003-15(Fullerenes--Volume 13: Fullerenes and Nanotubes), 371-374

33.

Electron field emission from multiwalled nanotubes.
Sveningsson, M.; Morjan, R.; Nerushev, O.; Svensson, K.; Olsson, E.; Campbell, E. E. B. Proceedings - Electrochemical Society (2003), 2003-

32.

Glow intensity profile in a spherically stratified gas discharge.
Nerushev, O. A.; Novopashin, S. A.; Radchenko, V. V.; Sukhinin, G. I.; Sukhovskii, V. V. Plasma Physics Reports (2003), 29(9), 796-801.

31.

Particle size dependence and model for iron-catalyzed growth of carbon nanotubes by thermal chemical vapor deposition.
Nerushev, O. A.; Dittmar, S.; Morjan, R.-E.; Rohmund, F.; Campbell, E. E. B. Journal of Applied Physics (2003), 93(7), 4185-4190
 

2002

30.

Field emission from multiwalled carbon nanotubes.
Sveningsson, M.; Joensson, M.; Nerushev, O.; Rohmund, F.; Campbell, E. E. B. AIP Conference Proceedings (2002), 633(Structural and Electronic Properties of Molecular Nanostructures), 548-551.

29.

Parametric study of nanotube growth from C2H2 and C60 on supported iron catalyst particles.
Morjan, R.-E.; Nerushev, O. A.; Sveningsson, M.; Falk, L. K. L.; Rohmund, F.; Campbell, E. E. B. AIP Conference Proceedings (2002), 633(Structural and Electronic Properties of Molecular Nanostructures), 186-189.

28.

The temperature dependence of Fe-catalysed growth of carbon nanotubes on silicon substrates.
Nerushev, O. A.; Morjan, R.-E.; Ostrovskii, D. I.; Sveningsson, M.; Jonsson, M.; Rohmund, F.; Campbell, E. E. B. Physica B: Condensed Matter (Amsterdam, Netherlands) (2002), 323(1-4), 51-59.

27.

Blackbody radiation from resistively heated multiwalled carbon nanotubes during field emission.
Sveningsson, M.; Jonsson, M.; Nerushev, O. A.; Rohmund, F.; Campbell, E. E. B. Applied Physics Letters (2002), 81(6), 1095-1097
 

2001

26.

Production and derivatisation of carbon nanotubes.
Rohmund, F.; Gromov, A.; Morjan, R.-E.; Nerushev, O.; Sato, Y.; Sveningsson, M.; Campbell, E. E. B. AIP Conference Proceedings (2001), 591(Electronic Properties of Molecular Nanostructures), 167-170.

25.

Raman spectroscopy and field-emission properties of CVD-grown carbon-nanotube films.
Sveningsson, M.; Morjan, R.-E.; Nerushev, O. A.; Sato, Y.; Backstrom, J.; Campbell, E. E. B.; Rohmund, F Applied Physics A: Materials Science & Processing (2001), 73(4), 409-418.

24.

Iron particle catalysed CVD growth of carbon nanotubes.
Rohmund, Frank; Nerushev, Oleg A.; Sveningsson, Martin; Campbell, Eleanor E. B. School of Physics and Engineering Physics, Gothenburg University and Chalmers University of Technology, Goeteborg, Swed. Editor(s): Campbell, Eleanor E. B.; Larsson, Mats. Physics and Chemistry of Clusters, Proceedings of Nobel Symposium, 117th, 303-306.

23.

Carbon nanotube films obtained by thermal chemical vapor deposition.
Nerushev, Oleg A.; Sveningsson, Martin; Falk, Lena K. L.; Rohmund, Frank Journal of Materials Chemistry (2001), 11(4), 1122-1132

22.

The Spherical Stratification of Discharge in High-Molecular-Mass Gases.
Nerushev, O. A.; Novopashin, S. A.; Radchenko, V. V.; Sukhinin, G. I. Technical Physics Letters (Translation of Pis'ma v Zhurnal Tekhnicheskoi Fiziki) (2001), 27(2), 118-120
 

Last millenium or pre-Nanotube period

21.

Characteristics of stratified spherical gas discharge.
Nerushev, O. A.; Novopashin, S. A.; Radchenko, V. V.; Sukhinin, G.I. Fizika Plazmy (Moscow) (2000), 26(1), 81-86

20.

Transition to turbulence in supersonic jets of nitrogen and argon.
Nerushev, O. A.; Novopashin, S. A.; Perepelkin, A. L. Novosibirsk, Russia. Fluid Dynamics (Translation of Izvestiya Akademii Nauk, Mekhanika Zhidkosti i Gaza) (1998), 33(3), 459-462

19.

Spherical stratification of a glow discharge.
Nerushev, O. A.; Novopashin, S. A.; Radchenko, V. V.; Sukhinin, G. I. Physical Review E: Statistical Physics, Plasmas, Fluids, and Related Interdisciplinary Topics (1998), 58(4),

18.

Photoluminescence of fullerenes C60 and C70 in gas phase.
Gorshkov, B. N.; Nerushev, O. A.; Novopashin, S. A. Asian Journal of Spectroscopy (1998), 2(1), 31-34.

17.

Electron-stimulated condensation of a carbon dioxide gas on an electronegative impurity.
Abornev, E. M.; Zhukovskaya, V. P.; Nerushev, O. A.; Novopashin, S. A.; Perepelkin, A. L.; Radchenko, V. V. Pis'ma v Zhurnal Tekhnicheskoi Fiziki (1998), 24(1), 21-25.

16.

A model for the formation of fullerenes in carbon vapor.
Sukhinin, G.I.; Nerushev, O.A.. Journal of Applied Mechanics and Technical Physics (Translation of Prikladnaya Mekhanika i Tekhnicheskaya Fizika) (1998), Volume Date 1997, 38(4), 625-637

15.

Spherical striations in a glow discharge.
Nerushev, O. A.; Novopashin, S. A.; Radchenko, V. V.; Sukhinin, G. I. Pis'ma v Zhurnal Eksperimental'noi i Teoreticheskoi Fiziki (1997), 66(11-12), 679-682.

14.

Water vapor jets outflow to a vacuum: influence of homogeneous condensation on the gas dynamics.
Khramov, G. A.; Nerushev, O. A. Russian Journal of Engineering Thermophysics (1996), 6(3), 225-230

13.

Argon condensation behind the acoustic nozzle and diaphragm.
Abornev, E. M.; Nerushev, O. A.; Novopashin, S. A.; Perepelkin, A. L.; Sukhinin, G. I. Pis'ma v Zhurnal Tekhnicheskoi Fiziki (1996), 22(21), 84-87

12.

Kinetics of the formation of fullerenes in electric arc evaporation of graphite.
Nerushev, O. A.; Sukhinin, G. I. Zhurnal Tekhnicheskoi Fiziki (1997), 67(2), 41-49

11.

Rotational relaxation and transition to turbulence.
Nerushev, Oleg A.; Novopashin, Sergei A. Physics Letters A (1997), 232(3,4), 243-246

10.

Rotation of molecules and transition to turbulence.
Nerushev, O. N.; Novopashin, S. A. Pis'ma v Zhurnal Eksperimental'noi i Teoreticheskoi Fiziki (1996), 64(1-2), 43-46.

9.

Dynamics of carbon clusters in fullerene production.
Nerushev, O. A.; Sukhinin, G. I. Pis'ma v Zhurnal Tekhnicheskoi Fiziki (1995), 21(13), 50-54

8.

Quadrupolar light scattering by fullerene.
Nerushev, Oleg A.; Novopashin, Sergei A.; Perepelkin, Alexander L. Chemical Physics Letters (1995), 234(1,2,3), 265-8.

7.

Measuring molecular polarizability according to Rayleigh light scattering.
Nerushev, O. A.; Novopashin, S. A. Pribory i Tekhnika Eksperimenta (1994), (2), 179-82.

6.

The polarizability of fullerene.
Mal'tsev, V. A.; Nerushev, O. A.; Novopashin, S. A.; Selivanov, B. A. Pis'ma v Zhurnal Eksperimental'noi i Teoreticheskoi Fiziki (1993), 57(9-10),

5.

Anomalous polarizability of fullerene.
Maltsev, Vasilii A.; Nerushev, Oleg A.; Novopashin, Sergei A.; Selivanov, Boris A. Chemical Physics Letters (1993), 212(5), 480-2.

4.

Application of water vapor as a working medium in high-vacuum diffusion pumps.
Abornev, E. M.; Nerushev, O. A.; Khramov, G. A.; Yarygin, V. N. Rarefied Gas Dyn., Proc. Int. Symp., 17th (1991), 1576-80.

3.

Source of high-enthalpy jets of vapours, gases and their mixture.
Nerushev, O. A.; Khramov, G. A.; Yarygin, V. N. Pribory i Tekhnika Eksperimenta (1987), (4), 202-204

2.

Effect of homogeneous condensation on gasdynamics and IR radiation of carbon dioxide and water vapor free jets.
Yarygin, V. N.; Skovorodko, P. A.; Gorchakova, N. G.; Khramov, G. A.; Nerushev, O. A. Rarefied Gas Dyn., Proc. Int. Symp., 14th (1984), 2 951-8.

1.

Jet expansion of argon into vacuo with condensation.
Nerushev, O. A., USSR, Teplo- Massoobmen Energ. Ustanovkakh (1984) Eds:Tairov, I. P.; Tsyganov, V. A. Gidrogazodin.,, pp. 93-96

last update 2012/July/16

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