Milan Perný, Vladimír Šály, Michal Váry, Miroslav Mikolášek, Jozef Huran and Juraj Packa
 KANNO, H.-IDE, D.-TSUNOMURA, Y.-TAIRA, S.-BABA, T.-YOSHIMINE, Y.-TAGUCHI, M.-KINOSHITA, T.-SAKATA, H.-MARUYAMA, E. : Over 22% Efficient HIT Solar Cell, In: Proceedings of the 23rd European photovoltaic solar energy conference and exhibition, Valencia, Spain, 2008, pp. 1136-1139.
 STREET, R. A. : Technology and Applications of Amorphous Silicon, Springer, New York, 2000.
 CHANG, Y. L.-CHEN, M. Y.-LIU, J. S. Q.-CHIEN, Y. J.-YANG, P. C.-HUANG, M. Y. : SiliconCarbide Emitter for Heterojunction
Milan Perný, Vladimír Šály, František Janíček, Miroslav Mikolášek, Michal Váry and Jozef Huran
 D. A. Anderson and W. E. Kspear, “Electrical and Optical Properties of Amorphous SiliconCarbide, Silicon Nitride and Germanium Carbide Prepared by Glow Discharge Technique”, Philos. Mag. B vol. 35, 1977, pp. 113–131.
 P. P. Dey and A. Khare, “Effect of Substrate Temperature on Structural and Linear and Nonlinear Optical Properties of Nanostructured PLD a-SiC thin films”, Materials Research Bulletin vol. 84, 2016, pp. 105–117.
 I. Kleps and A. Angelescu, “LPCVD Amorphous SiliconCarbide Films, Properties and
Szymon Piasecki, Robert Szmurlo and Marek Jasinski
Power electronic circuits, in particular AC-DC converters are complex systems, many different parameters and objectives have to be taken into account during the design process. Implementation of Multi-Objective Optimization (MOO) seems to be attractive idea, which used as designer supporting tool gives possibility for better analysis of the designed system. This paper presents a short introduction to the MOO applied in the field of power electronics. Short introduction to the subject is given in section I. Then, optimization process and its elements are briefly described in section II. Design procedure with proposed optimization parameters and performance indices for AC-DC Grid Connected Converter (GCC) interfacing distributed systems is introduced in section III. Some preliminary optimization results, achieved on the basis of analytical and simulation study, are shown at each stage of designing process. Described optimization parameters and performance indices are part of developed global optimization method dedicated for ACDC GCC introduced in section IV. Described optimization method is under development and only short introduction and basic assumptions are presented. In section V laboratory prototype of high efficient and compact 14 kVA AC-DC converter is introduced. The converter is elaborated based on performed designing and optimization procedure with the use of silicon carbide (SiC) power semiconductors. Finally, the paper is summarized and concluded in section VI. In presented work theoretical research are conducted in parallel with laboratory prototyping e.g. all theoretical ideas are verified in laboratory using modern DSP microcontrollers and prototypes of the ACDC GCC.
Miroslav Mikolasek, Martin Kemeny, Filip Chymo, Peter Ondrejka and Jozef Huran
 M. Zeman and Z. Dong, “Heterojunction silicon based solar cells, Physics and technology of amorphous-crystalline heterostructure silicon solar cells”, Springer Berlin Heidelberg , pp. 13–43, 2012.
 S. De Wolf, A. Descoeudres, ZC. Holman and C. Ballif, “High-efficiency silicon heterojunction solar cells: A review”, Green , vol. 2, no. 1, pp. 7–24, 2012.
 K. Masuko, M. Shigematsu, T. Hashiguchi, D. Fujishima, M. Kai, N. Yoshimura, T. Yamaguchi, Y. Ichihashi, T. Mishima, N. Matsubara, T. Yamanishi, T. Takahama, M. Taguchi, E
Dinara Sobola, Nikola Papež, Rashid Dallaev, Shikhgasan Ramazanov, Dušan Hemzal and Vladimír Holcman
patterns on HOPG”, Surf. Sci. , 2019.
 M. Kettner, C. Stumm, M. Schwarz, C. Schuschke, and J. Libuda, “Pd model catalysts on clean and modified HOPG: Growth, adsorption properties, and stability”, Surf. Sci. , 2019.
 R. Shikhgasan, T. Stefan, S. Dinara, S. Sebastian, and R. Guseyn, “Epitaxy of siliconcarbide on silicon: Micromorphological analysis of growth surface evolution”, Superlattices Microstruct. , vol. 86, pp. 395–402, 2015.
 D. Sobola, S. Talu, S. Solaymani, and L. Grmela, “Influence of scanning rate on quality of AFM image
Eva Buranská, Ivan Buranský, Michaela Kritikos, Kristína Gerulová and Ján Líška
Proc. Int. DAAAM Symp. , Vol. 2015–Janua, No. 2016, pp. 709–714, 2015.
 BHOWMICK, S., ALPAS, A. T. 2008. Minimum quantity lubrication drilling of aluminium–silicon alloys in water using diamond-like carbon coated drills. Int. J. Mach. Tools Manuf. , Vol. 48 (12–13), pp. 1429–1443.
 YU, D. G. 2017. Deep hole drill with positive taper and principle for elimination of drill deviation using cutting fluid. Int. J. Adv. Manuf. Technol. , 89 (9–12), pp. 3195–3206.
 KONG,L., LI, Y., LV, Y., WANG, Q. 2013. Numerical investigation on dynamic
 L. K. Elbaum, M. Wittmer, C. Y. Ting, J. Cumo, “ZrN diffusion barrier in aluminum metallization schemes”, J. Thin Solid Films , vol. 104, pp. 81, 1983.
 M. Ostling, S. Nygren, C. S. Petersson, H. Norstrom, P. Wiklund, R. Buchta, H. O Blom, S. Berg, “Reactively sputtered ZrN used as an Al/Si diffusion barrier in a Zr contact to silicon”, J. Vac. Sci. Technol. A , vol. 2, pp. 281, 1984.
 W. Ensinger, U. K. Volza, M. Kiuchi, “Ion beam-assisted deposition of nitrides of the 4th group of transition metals”, Surface & Coating Technology
Elżbieta Gadalińska, Andrzej Baczmański, Sebastian Wroński, Mirosław Wróbel and Christian Scheffzük
, “Influence of stirring speed and stirring time on distribution of particles in cast metal matrix composite,” Journal of Materials Processing Technology , vol. 171, no. 2, pp. 268–273, Jan. 2006.
 K. Suryanarayanan, R. Praveen, and S. Raghuraman, “Siliconcarbide reinforced aluminium metal matrix composites for aerospace applications: a literature review,” International Journal of Innovative Research in Science, Engineering and Technology , vol. 2, no. 11, pp. 6336–6344, 2013.
 S. H. Avner, Introduction to physical metallurgy . New York: McGraw
Vapour Deposition and Transfer by a Roll-to-Roll Process, Carbon 48 No. 11 (2010), 3169-3174.
 JUANG, Z. Y.-WU, C. Y.-LO, C. W.-CHEN, W. Y.-JUANY, C. F.-HWANG, J. C.-CHEN, F. R.-LEOU, K. C.-TSAI, C. H. : Synthesis of Graphene on SiliconCarbide Substrates at Low Temperature, Carbon 47 No. 08 (2009), 2026-2031.
 MACHAC, P.-FIDLER, T.-CICHON, S.-JURKA, V. : Syn- thesis of Graphene on Co/SiC Structure, J. Mater. Sci.: Mater. Electron. 24 No. 10 (2013), 3793-3799.
 CANADO, L. G.-TAKAI, K.-ENOKI, T.-ENDO, M.-KIM, Y. A
/DC-Boost-Converter for Wind Turbines Concerning their Efficiency and Installed Semiconductor Power, in Proc. IEEE PESC, 2008, pp. 1814–1820.
 WEI, W.—HONGPENG, L.—JIAWAN, Z.—DIANGUO, X. : Analysis of Power Losses in Z-Source PV Grid-Connected Inverter, in Proc. IEEE ICPE & ECCE, Jeju, 2011, pp. 2588–2592.
 STEINBRING, M.—PACAS, M. : Increasing the Efficiency of a Single Phase Z-Source Inverter by Utilizing SiC-MOSFETs, in Proc. PCIM Europe, Nuremberg, 2014, pp. 706–712.
 OZPINECI, B.—TOLBERT, L. M.—ISLAM, S. K. : SiliconCarbide Power Device