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[en] In our work we demonstrate growth of carbon nanotubes that can conductively bridge the metal electrodes. The role of different catalysts was examined. Interdigitated metal electrodes are made from copper and we are using bimetal Al/Ni as catalyst for growth of carbon nanotubes. We are using this catalyst composition for growth of the single-walled carbon nanotube network. (authors)
Source
Vajda, J. (ed.) (Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia)); Jamnicky, I. (ed.) (Dept. of Physics,, Faculty of Electrical Engineering, University of Zilina, Zilina (Slovakia)); Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia); Alumni Club of the Faculty of Electrical Engineering and Information Technology, Slovak University of Technology, Bratislava (Slovakia); Dept. of Physics, Faculty of Electrical Engineering, University of Zilina, Zilina (Slovakia); Slovak Physical Society, Bratislava (Slovakia); Institute of Physics, Slovak Academy of Sciences, Bratislava (Slovakia); Slovak Physical Society, Bratislava (Slovakia); Institut Francais-Slovaque, Bratislava (Slovakia). Funding organisation: Sponsors: Slovenske Elektrarne, a. s., Bratislava (Slovakia); Slovak Nuclear Society, Trnava (Slovakia); Institut Francais Slovaquie, Bratislava (Slovakia); 369 p; ISBN 978-80-227-3720-3; 
; 28 May 2012; p. 211-214; APCOM 2012: 18. International Conference on Applied Physics of Condensed Matter; Strbske Pleso (Slovakia); 20-22 Jun 2012; GRANTS APVV-0548-07; VEGA-1/1102/11; VEGA-1/1103/11; Also available from http://kf.elf.stuba.sk/∼apcom/apcom12/proceedings/; 7 figs., 9 refs.
; 28 May 2012; p. 211-214; APCOM 2012: 18. International Conference on Applied Physics of Condensed Matter; Strbske Pleso (Slovakia); 20-22 Jun 2012; GRANTS APVV-0548-07; VEGA-1/1102/11; VEGA-1/1103/11; Also available from http://kf.elf.stuba.sk/∼apcom/apcom12/proceedings/; 7 figs., 9 refs.
[en] The growth of SWCNTs networks on the SiO_2 chips was examined for different growth temperatures and annealing times. According to Raman spectroscopy the temperature is a significant parameter which affects quality of carbon nanotubes. For higher temperatures (850 - 900 deg C) the best quality was achieved. On the other hand, the different annealing times did not affect results of our experiments. SWCNTs network consists of large amount of intersecting carbon nanotubes. This network is electrically conductive over large distances. The SWCNTs networks can be used as transparent conductive layer or as sensitive layer of chemical sensors. (authors)
Source
Pudis, D. (ed.) (Dept. of Physics, Univ. of Zilina, Zilina (Slovakia)); Kubicova, I. (ed.) (Dept. of Physics, Univ. of Zilina, Zilina (Slovakia)); Bury, P. (ed.) (Dept. of Physics, Univ. of Zilina, Zilina (Slovakia)); Dept. of Physics, Faculty of Electrical Engineering, University Of Zilina, Zilina (Slovakia); Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia); Slovak Physical Society, Bratislava (Slovakia); 328 p; ISBN 978-80-554-0386-1; ; 15 Jun 2011; p. 52-55; APCOM 2011: 17. International Conference on Applied Physics of Condensed Matter; High Tatras (Slovakia); 22-24 Jun 2011; VVCE-0049-07; GRANTS APVV-0628-06; APVV-0548-07; SK-CZ-0139-09; LPP-0094-09; LPP-0246-06; LPP- 0149-09; AND VEGA-1/0807/08; VEGA-1/0857/08; VEGA-1/0746/09; VEGA-1/0390/08; Also available from http://kf.elf.stuba.sk/∼apcom/apcom11/proceedings/; 4 figs., 7 refs.
; 15 Jun 2011; p. 52-55; APCOM 2011: 17. International Conference on Applied Physics of Condensed Matter; High Tatras (Slovakia); 22-24 Jun 2011; VVCE-0049-07; GRANTS APVV-0628-06; APVV-0548-07; SK-CZ-0139-09; LPP-0094-09; LPP-0246-06; LPP- 0149-09; AND VEGA-1/0807/08; VEGA-1/0857/08; VEGA-1/0746/09; VEGA-1/0390/08; Also available from http://kf.elf.stuba.sk/∼apcom/apcom11/proceedings/; 4 figs., 7 refs.
[en] We used PECVD method for deposition of Cu incorporated DLC thin films from CH_4/Ar gas mixture. The size of nanoparticles varied with changing the deposition conditions in the range of tenth to hundreds of nm. After annealing process, new small Cu particles appeared in the space between the as deposited ones, and all the particles were distributed more homogenous within the films. The resistivity of the DLC films decreased first with adding of copper to 10 to 6·10"3 Ωcm, and second with the annealing process to 4·10"-"2 to 3 Ωcm. Raman spectra show the tendency of DLCs to become more graphitic with increasing annealing temperature, which may be one possible contribution to increased conductivity of the annealed Cu-DLC films. (authors)
Source
Vajda, J. (ed.) (Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia)); Jamnicky, I. (ed.) (Dept. of Physics,, Faculty of Electrical Engineering, University of Zilina, Zilina (Slovakia)); Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia); Alumni Club of the Faculty of Electrical Engineering and Information Technology, Slovak University of Technology, Bratislava (Slovakia); Dept. of Physics, Faculty of Electrical Engineering, University of Zilina, Zilina (Slovakia); Slovak Physical Society, Bratislava (Slovakia); Institute of Physics, Slovak Academy of Sciences, Bratislava (Slovakia); Slovak Physical Society, Bratislava (Slovakia); Institut Francais-Slovaque, Bratislava (Slovakia). Funding organisation: Sponsors: Slovenske Elektrarne, a. s., Bratislava (Slovakia); Slovak Nuclear Society, Trnava (Slovakia); Institut Francais Slovaquie, Bratislava (Slovakia); 369 p; ISBN 978-80-227-3720-3; ; 28 May 2012; p. 215-218; APCOM 2012: 18. International Conference on Applied Physics of Condensed Matter; Strbske Pleso (Slovakia); 20-22 Jun 2012; CONTRACT CENAMOST VVCE-0049-07; GRANTS APVV-0628-06; APVV-0548-07; LPP-0149-09; DAAD 507 552 00; VEGA-1/1103/11; VEGA-1/1102/11; Also available from http://kf.elf.stuba.sk/∼apcom/apcom12/proceedings/; 10 figs., 8 refs.
; 28 May 2012; p. 215-218; APCOM 2012: 18. International Conference on Applied Physics of Condensed Matter; Strbske Pleso (Slovakia); 20-22 Jun 2012; CONTRACT CENAMOST VVCE-0049-07; GRANTS APVV-0628-06; APVV-0548-07; LPP-0149-09; DAAD 507 552 00; VEGA-1/1103/11; VEGA-1/1102/11; Also available from http://kf.elf.stuba.sk/∼apcom/apcom12/proceedings/; 10 figs., 8 refs.
[en] The iron oxide nanoparticles (IONPs) covered with different lengths and effect of nanoparticle effective size on interparticle distance was investigated. To obtain different interparticle distance, the IONPs with the size of 6.5 nm were functionalized by three kinds of surfactants: mixture of oleic acid/oleylamine, polybutylacrylate and polystyrene. Both hydrodynamic diameter and size distribution of nanoparticles in colloidal solution were measured by dynamic light scattering (DLS) in range from 8 to 17 nm. The ordering and homogeneity of the prepared Langmuir monolayers on solid surface was studied by scanning electron microscope (SEM) and atomic force microscopy (AFM). Method of pair correlation function was used for calculation of interparticle distance ensuing from SEM images. The distances from center to center of particles varied in the range from 6.75 to 11.75 nm. From the results it follows that we are able to change of interparticle distance on a solid substrate using of nanoparticles with different surfactant size. (authors)
Source
Vajda, J. (ed.) (Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia)); Jamnicky, I. (ed.) (Dept. of Physics,, Faculty of Electrical Engineering, University of Zilina, Zilina (Slovakia)); Institute of Nuclear and Physical Engineering, Faculty of Electrical Engineering and Information Technology, Slovak University of Technology, Bratislava (Slovakia); Alumni Club of The Faculty of Electrical Engineering and Information Technology, Slovak University of Technology, Bratislava (Slovakia); Institute of Aurel Stodola, Liptovsky Mikulas, Faculty of Electrical Engineering, University of Zilina (Slovakia); Institute of Physics, Slovak Academy of Sciences, Bratislava (Slovakia); Slovak Physical Society, Bratislava (Slovakia). Funding organisation: Sponsors: New Technologies Research Centre, University of West Bohemia, Plzen (Czech Republic); European Structural and Investment Funds, Operational Programme Research, Development and Education, European Union, City of Brussels (Belgium); Ministry of Education, Youth and Sports, Prague (Czech Republic); NURECO o.z., Miloslavov (Slovakia); 51 p; ISBN 978-80-227-4799-8; ; 2 Jun 2018; 1 p; APCOM 2018: 24. International Conference on Applied Physics of Condensed Matter; Strbske Pleso (Slovakia); 20-22 Jun 2018; Available from http://kf.elf.stuba.sk/∼apcom/proceedings2018/
; 2 Jun 2018; 1 p; APCOM 2018: 24. International Conference on Applied Physics of Condensed Matter; Strbske Pleso (Slovakia); 20-22 Jun 2018; Available from http://kf.elf.stuba.sk/∼apcom/proceedings2018/
[en] The conductance of electron rich inversion layer at the a-Si:H(n)/c-Si(p) interface was measured at various temperature and an activation energy was evaluated from Arrhenius plot. Strong dependence of calculated and measures activation energy on the band offset at the hetero-junction allowed us to determine the conduction band offset in the studied sample ΔE_C = 170 meV. Considering this value and assuming low defect density at the interface we were able to estimate performance of solar cell with one a-Si:H(n)/c-Si(p) hetero-junction prepared under similar conditions as our sample. The open circuit voltage of such solar cell is V_O_C = 0.620 V and the efficiency is η = 15.2%. Increasing the conduction band offset, decreasing the defect density at the interface and improving the light management in the solar cell can attain further increasing of efficiency. (authors)
Source
Pudis, D. (ed.) (Dept. of Physics, Univ. of Zilina, Zilina (Slovakia)); Kubicova, I. (ed.) (Dept. of Physics, Univ. of Zilina, Zilina (Slovakia)); Bury, P. (ed.) (Dept. of Physics, Univ. of Zilina, Zilina (Slovakia)); Dept. of Physics, Faculty of Electrical Engineering, University Of Zilina, Zilina (Slovakia); Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia); Slovak Physical Society, Bratislava (Slovakia); 328 p; ISBN 978-80-554-0386-1; ; 15 Jun 2011; p. 184-187; APCOM 2011: 17. International Conference on Applied Physics of Condensed Matter; High Tatras (Slovakia); 22-24 Jun 2011; CENAMOST CONTRACT VVCE-0049-07; GRANTS APVV-0509-10; VEGA-1/0507/09; VEGA-1/0601/10; VEGA-2/0214/09; PROJECTS CENTEM-CZ.1.05/2.1.00/03.0088; MEYS-1M06031; Also available from http://kf.elf.stuba.sk/∼apcom/apcom11/proceedings/; 4 figs., 6 refs.
; 15 Jun 2011; p. 184-187; APCOM 2011: 17. International Conference on Applied Physics of Condensed Matter; High Tatras (Slovakia); 22-24 Jun 2011; CENAMOST CONTRACT VVCE-0049-07; GRANTS APVV-0509-10; VEGA-1/0507/09; VEGA-1/0601/10; VEGA-2/0214/09; PROJECTS CENTEM-CZ.1.05/2.1.00/03.0088; MEYS-1M06031; Also available from http://kf.elf.stuba.sk/∼apcom/apcom11/proceedings/; 4 figs., 6 refs.
[en] Standard ceramic substrates with patterned surface electrodes few hundred nm thick are not appropriate for advanced nanoparticle gas sensors. Smooth silicon planar substrates with embedded metallic electrodes are introduced in our work. They give the chance to cover the small substrate surface irregularities by fragile nanoparticle arrays and provide an opportunity to integrate sensors into electronic circuits. The suppression of high power consumption of integrated sensor heater due to the high thermal conductivity of Si is resolved using substrates hanging on thin contacting wires without getting in touch with the socket. Embedded Au electrodes were created in sputtered amorphous silicon layer by lift-off technique. The ridges at Au - a:Si interface were reduced due to improved Au wettability of a:Si vertical walls. γ-Fe2O3 nanoparticle deposits on the Si patterned substrates were studied.(authors)
Source
Vajda, J. (ed.) (Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia)); Jamnicky, I. (ed.) (Dept. of Physics,, Faculty of Electrical Engineering, University of Zilina, Zilina (Slovakia)); Institute of Nuclear and Physical Engineering, Faculty of Electrical Engineering and Information Technology, Slovak University of Technology, Bratislava (Slovakia); Alumni Club of The Faculty of Electrical Engineering and Information Technology, Slovak University of Technology, Bratislava (Slovakia); Institute of Aurel Stodola, Liptovsky Mikulas, Faculty of Electrical Engineering, University of Zilina (Slovakia); Institute of Physics, Slovak Academy of Sciences, Bratislava (Slovakia); Slovak Physical Society, Bratislava (Slovakia). Funding organisation: Sponsors: New Technologies Research Centre, University of West Bohemia, Plzen (Czech Republic); European Structural and Investment Funds, Operational Programme Research, Development and Education, European Union, City of Brussels (Belgium); Ministry of Education, Youth and Sports, Prague (Czech Republic); NURECO o.z., Miloslavov (Slovakia); 51 p; ISBN 978-80-227-4799-8; ; 2 Jun 2018; 1 p; APCOM 2018: 24. International Conference on Applied Physics of Condensed Matter; Strbske Pleso (Slovakia); 20-22 Jun 2018; Available from http://kf.elf.stuba.sk/∼apcom/proceedings2018/
; 2 Jun 2018; 1 p; APCOM 2018: 24. International Conference on Applied Physics of Condensed Matter; Strbske Pleso (Slovakia); 20-22 Jun 2018; Available from http://kf.elf.stuba.sk/∼apcom/proceedings2018/
[en] Plasmonic sensors have recently attracted much attention. The past few decades have seen a massive and continued interest in studying electrochemical processes at artificially structured electrodes. Such electrochemical sensors provide sensitive, selective, and easy to use approaches to the detection of many chemical species, e.g. environmental pollutants, biomolecules, drugs etc. The issue raised in this paper is to study the kinetic of the diffusion towards plasmonic surfaces in dark and under illumination with white LED diode. The possibility to use anomalous charge transfer towards plasmonic surfaces in electrochemical sensorics will be discussed, too. (authors)
Source
Vajda, J. (ed.) (Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia)); Jamnicky, I. (ed.) (Dept. of Physics,, Faculty of Electrical Engineering, University of Zilina, Zilina (Slovakia)); Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia); Alumni Club of the Faculty of Electrical Engineering and Information Technology, Slovak University of Technology, Bratislava (Slovakia); Dept. of Physicsand Institute of Aurel Stodola, Faculty of Electrical Engineering, University of Zilina, Zilina (Slovakia); Slovak Physical Society, Bratislava (Slovakia); Institute of Physics, Slovak Academy of Sciences, Bratislava (Slovakia); Slovak Physical Society, Bratislava (Slovakia); Institut Francais-Slovaque, Bratislava (Slovakia). Funding organisation: Sponsors: Slovenske Elektrarne, a. s., Bratislava (Slovakia); Slovak Nuclear Society, Trnava (Slovakia); Institut Francais Slovaquie, Bratislava (Slovakia); 302 p; ISBN 978-80-227-3956-6; ; 5 Jun 2013; p. 229-232; APCOM 2013: 19. International Conference on Applied Physics of Condensed Matter; Strbske Pleso (Slovakia); 19-21 Jun 2013; ASFEU PROJECT ITMS-26240220073; GARANTS VEGA-2/0165/13; VEGA-2/0041/11; Also available from http://kf.elf.stuba.sk/∼apcom/apcom13/proceedings/; 8 figs., 7 refs.
; 5 Jun 2013; p. 229-232; APCOM 2013: 19. International Conference on Applied Physics of Condensed Matter; Strbske Pleso (Slovakia); 19-21 Jun 2013; ASFEU PROJECT ITMS-26240220073; GARANTS VEGA-2/0165/13; VEGA-2/0041/11; Also available from http://kf.elf.stuba.sk/∼apcom/apcom13/proceedings/; 8 figs., 7 refs.
[en] Preparation of metal nanoparticles such as gold or silver of various shape is very attractive for applications in plasmonics and sensorics. Plasmonic photovoltaics uses plasmonic effects inherent to metallic nanostructures to enhance the power conversion efficiency of photovoltaic devices. In particular, gold and silver nanoparticles (NPs) strongly absorb light in the visible region as a result of the surface plasmon resonance. The resonance wavelength depends on the nanoparticle size and shape, aggregation state as well as the dielectric constant of the surrounding medium. The optical properties are related to the interaction between the metal conduction electrons and the electric field component of the incident electromagnetic radiation, which in the case of a few metals, such as gold and silver, leads to strong, characteristic absorption bands in the visible and near-infrared region of the spectrum, not observed in the bulk material. The best way to achieve monodisperse stable metallic nanoparticles in solution is the formation of these particles by chemical methods. This work will focus on two very simple and rapid preparation methods of stable gold and silver nanorods in colloidal solution. The first one is thermal decomposition and reduction of metallic precursor and steric stabilization of nanorods by polymer. The second one isf seed mediated growth where nanorods are stabilized in an aqueous medium by ionic surfactant. (authors)
Source
Vajda, J. (ed.) (Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia)); Jamnicky, I. (ed.) (Dept. of Physics,, Faculty of Electrical Engineering, University of Zilina, Zilina (Slovakia)); Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia); Alumni Club of the Faculty of Electrical Engineering and Information Technology, Slovak University of Technology, Bratislava (Slovakia); Institute of Physicsand Institute of Aurel Stodola, Faculty of Electrical Engineering, University of Zilina, Zilina (Slovakia); Slovak Physical Society, Bratislava (Slovakia); Institute of Physics, Slovak Academy of Sciences, Bratislava (Slovakia); Slovak Physical Society, Bratislava (Slovakia). Funding organisation: Sponsors: Slovenske Elektrarne, a. s., Bratislava (Slovakia); 217 p; ISBN 978-80-227-4179-8; ; 27 Jun 2014; p. 210-213; APCOM 2014: 20. international conference on applied physics of condensed matter; Strbske Pleso (Slovakia); 25-28 Jun 2014; PROJECTS ITMS-26240220073; VEGA-2/0041/11; APVV-0096-11; SAS-TUBITAK JRP 2013/6; COST ACTION CM1101; Also available from http://kf.elf.stuba.sk/∼apcom/apcom14/; 5 figs., 6 refs.
; 27 Jun 2014; p. 210-213; APCOM 2014: 20. international conference on applied physics of condensed matter; Strbske Pleso (Slovakia); 25-28 Jun 2014; PROJECTS ITMS-26240220073; VEGA-2/0041/11; APVV-0096-11; SAS-TUBITAK JRP 2013/6; COST ACTION CM1101; Also available from http://kf.elf.stuba.sk/∼apcom/apcom14/; 5 figs., 6 refs.
[en] In this article, we describe the modified seed-mediated growth synthesis of Au nanorods in aqueous medium according to C. Murphy designed for applications in photovoltaic devices with different aspect ratio (redshift of longitudinal LSPR). It is a method which is divided into two different steps. The first one is preparation of spherical gold particles by metal salts reduction in water which serve as a seeds to the formation of nanorods. In the second step, the rods grow from these seeds applying a structure-directing agent, namely cetyltrimethylammonium bromide (CTAB). The absorption spectra showing different plasmon resonance wavelengths for nanorods with various aspect ratios were detected by the UV/VIS/NIR spectrophotometry. Stability of nanorod solutions was examined by the zeta potential measurement on Zetasizer Nano ZS 90 (Malvern Instrument). (authors)
Source
Vajda, J. (ed.) (Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia)); Jamnicky, I. (ed.) (Dept. of Physics,, Faculty of Electrical Engineering, University of Zilina, Zilina (Slovakia)); Institute of Nuclear and Physical Engineering, Institute of Electronics and Photonics, Faculty of Electrical Engineering and Information Technology, Slovak Univ. of Technology, Bratislava (Slovakia); Alumni Club of the Faculty of Electrical Engineering and Information Technology, Slovak University of Technology, Bratislava (Slovakia); Institute of Physics and Institute of Aurel Stodola, Faculty of Electrical Engineering, University of Zilina, Zilina (Slovakia); Slovak Physical Society, Bratislava (Slovakia); Institute of Physics, Slovak Academy of Sciences, Bratislava (Slovakia); Slovak Physical Society, Bratislava (Slovakia). Funding organisation: Sponsors: Slovenske Elektrarne, a. s., Bratislava (Slovakia); 400 p; ISBN 978-80-227-4373-0; ; 24 Jun 2015; p. 230-233; APCOM 2015; Strbske Pleso (Slovakia); 24-26 Jun 2015; PROJECTS VEGA-2/0010/15; VEGA-2/0004/15; SAS-TUBITAK JRP 2013/6; M-ERA-NET XOPTICS; COST ACTIONS CM1101 AND MP1307; Also available from http://kf.elf.stuba.sk/∼apcom/apcom15/proceedings/; 3 figs., 7 refs.
; 24 Jun 2015; p. 230-233; APCOM 2015; Strbske Pleso (Slovakia); 24-26 Jun 2015; PROJECTS VEGA-2/0010/15; VEGA-2/0004/15; SAS-TUBITAK JRP 2013/6; M-ERA-NET XOPTICS; COST ACTIONS CM1101 AND MP1307; Also available from http://kf.elf.stuba.sk/∼apcom/apcom15/proceedings/; 3 figs., 7 refs.
[en] In this article, we investigate the nanocomposite material formation, particularly the deposition of nanocrystalline diamond and carbon nanowalls (CNWs) on single-wall carbon nanotubes buckypaper (BP). One part of the buckypaper substrate was nucleated by nanodiamond powder. The growth was carried out in a hot filament chemical vapor deposition (HFCVD) system. Contact angle measurements, scanning electron microscopy, and Raman spectroscopy were used for the surface morphology analysis and characterization of carbon phases. Due to a different surface pretreatment, different carbon nanostructures were formed: diamond film was grown on the nucleated BP area; non-treated area of the BP was covered with a dense field of CNWs. Covering a part of the BP surface prevented an access of the HF-plasma and so the growth of any carbon structures. (Copyright copyright 2012 WILEY-VCH Verlag GmbH and Co. KGaA, Weinheim)
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