Mgr. Babchenko Oleg, PhD.

Babchenko, O., Dzuba, J., Lalinský, T., Vojs, M., Vincze, A., Ižák, T., Vanko, G., : Stability of AlGaN/GaN heterostructures after hydrogen plasma treatment,. Applied Surface Sci 395 (2017) 92-97.. (SASPRO 0068/01/01)(APVV 0455-12)(CENTE).

      1. Mishra, M.: Applied Surface Sci 407 (2017) 255.

Verdanova, M., Rezek, B., Broz, A., Ukraintsev, E., Babchenko, O., Artemenko, A., Ižák, T., Kromka, A., Kalbac, M., Kalbacova, M., : Nanocarbon allotropes-graphene and nanocrystalline diamond-promote cell proliferation. Small 12 (2016) 2499-2509. (Not IEE SAS)..

       1. Jeong, N.: Chem. Engn. J. 314 (2017) 69.

Remes, Z., Babchenko, O., Varga, M., Stuchlík, J., Jirásek, V., Prajzler, V., Nekvindova, P., Kromka, A., :Preparation and optical properties of nanocrystalline diamond coatings for infrared planar waveguides,. Thin Solid Films 618 (2016) 130-133. (Not IEE SAS).

       1. Yang, L.: Nanoscale Res. Lett. 11 (2016) 415.

Liskova, J., Babchenko, O., Varga, M., Kromka, A., Hadraba, D., Svindrych, Z., Burdikova, Z., : Osteogenic cell differentiation on H-terminated and O-terminated nanocrystalline diamond films. Inter. J. Nanomedicine 10 (2015) 869-884. (Not IEE SAS).

       1. Marino, A.: ACS Applied Mater. Interfaces (2015) 25574. 2. Tsukanaka, M.: Dental Mater. J. 35 (2016) 118. 3. Ma, S.: J. Hard Tissue Biol. 25 (2016) 6. 4. Hua, C.: Materials & Design 105 (2016) 81. 5. Guler, Z.: J. Biomater. Applic. 31  (2016) 743. 6. Cheng, T.: American J. Pathol. 187  (2017) 292. 7. Padmavathy, N.: Materials & Design 126 (2017) 238.

Babchenko, O., Rezek, B., Stuchlík, J., Kromka, A., Arnault, J., Bergonzo, P., : Comparing the surface termination properties of nanocrystalline diamond films grown on glass in cavity-based and linear-antenna microwave plasma reactors, Adv. Sci., Engn. Medicine 6 (2014) 802-808. (Not IEE SAS).

        1. Bachmann, S.: Applied Surface Sci 371 (2016) 613.

Ižák, T., Babchenko, O., Potocký, Š., Remes, Z., Kozak, H., Verveniotis, E., Rezek, B., Kromka, A., : Low temperature diamond growth. In: Nanodiamond. Royal Soc Chemistry: 2014, ISBN 978-184-973-639-8. Chapter 13, pp. 290-342. (Not IEE SAS).

       1. Nave, A.S.C.: Plasma Sources Sci Technol. 25 (2016) 065002. 2. Nave, A.S.C.: Plasma Sources Sci Technol. 25 (2016) 065003. 3. Baudrillart, B.: Phys. Status Solidi A 213 (2016) 2575. 4. Baudrillart, B.: Diamond Related Mater. 71 (2017) 53.

Babchenko, O., Kromka, A., Conde, J., Chu, V., Schmiedinger, T., Rezek, B., : Optically transparent diamond-PDMS microfluidic system for electronic monitoring of cells. Phys. Status Solidi B 251 (2014) 2593-2598. (Not IEE SAS).

          1. Lee, S.-W.: Bull. Korean Chemical Soc 36 (2015) 2542. 2. Gubanova, O.: Materials Sci Semicond. Process. 60 (2017) 71.

Ižák, T., Babchenko, O., Jirásek, V., Vanko, G., Vallo, M., Vojs, M., Kromka, A., : Selective area deposition of diamond films on AlGaN/GaN heterostructures. Phys. Status Solidi B 251 (2014) 2574-2580. (APVV 0455-12).

        1. Shahin, D.I.: Diamond Related Mater. 59 (2015) 116.

Vojs, M., Varga, M., Babchenko, O., Ižák, T., Mikolášek, M., Marton, M., Kromka, A., : Structural and electrical characterization of diamond films deposited in nitrogen/oxygen containing gas mixture by linear antenna microwave CVD process. Applied Surface Sci 312 (2014) 226-230. (Not IEE SAS).

       1. Zvanya, J.: J. Vacuum Sci Technol. A 32 (2014) 050605. 2. Podgursky, V.: Diamond Related Mater. 58 (2015) 172. 3. Kar, R.: Carbon 106 (2016) 233. 4. Okumura, Y.: Proc. Combustion Instit. 36 (2017) 4409.

Potocký, Š., Kromka, A., Babchenko, O., Rezek, B., Martinova, L., Pokorny, P., : Diamond structures growth from polymer composite, Adv. Sci., Engn. Medicine 5 (2013) 519-521. (Not IEE SAS).

       1. Zhu, Y.: J. Nanosci Nanotechnol. 15 (2015) 4193. 2. Zhu, F.: J. Nanosci Nanotechnol. 15 (2015) 3981.

Remes, Z., Kozak, H., Rezek, B., Ukraintsev, E., Babchenko, O., Kromka, A., Girard, H., Arnault, J., Bergonzo, P., : Diamond-coated ATR prism for infrared absorption spectroscopy of surface-modified diamond nanoparticles. Applied Surface Sci 270 (2013) 411-417. (Not IEE SAS).

      1. Lopez-Lorente, A.I.: TRAC-Trends in Analyt. Chem. 84  (2016) 97.

Potocký, Š., Cada, M., Babchenko, O., Ižák, T., Davydova, M., Kromka, A., : Perspectives of linear antenna microwave system for growth of various carbon nano-forms and its plasma study. Phys. Status Solidi B 250 (2013) 2723-2726. (Not IEE SAS).

      1. Obrusnik, A.: J. Phys. D 48 (2015) 065201. 2. Swaminathan, S.: RSC Adv. 6 (2016) 49127.

Remes, Z., Kozak, H., Babchenko, O., Ukraintsev, E., Rezek, B., Kromka, A., : Photoluminescence and infrared absorption spectra of aminated nanocrystalline diamond surface, Adv. Sci., Engn. Medicine 5 (2013) 515-518. (Not IEE SAS).

       1. Ouyang, J.: J. Nanosci Nanotechnol. 15 (2015) 2798.

Babchenko, O., Romanyuk, N., Jendelova, P., Kromka, A., : Tailoring morphologies of diamond thin films for neural stem cells culturing. Phys. Status Solidi B 250 (2013) 2717-2722. (Not IEE SAS).

       1. Piret, G.: Biomater. 53 (2015) 173. 2. Vaitkuviene, A.: Molecular Cellular Probes  29 (2015) 25. 3. Garrett, D.J.: Carbon 102 (2016) 437. 4. Cai, Y.: Acta Biomater.  31 (2016) 211. 5. Carabelli, V.: ACS Chem. Neurosci 8 (2017) SI252.

Ižák, T., Kromka, A., Babchenko, O., Ledinsky, M., Hruska, K., Verveniotis, E., : Comparative study on dry etching of polycrystalline diamond thin films. Vacuum 86 (2012) SI 799-802. (Not IEE SAS).

       1. Ralchenko, V.G.: Diamond Related Mater. 66 (2016) 171. 2. Liu, D.: Vacuum  (2016) 80.

Kulha, P., Babchenko, O., Kromka, A., Husák, M., Haenen, K., : Design and fabrication of piezoresistive strain gauges based on nanocrystalline diamond layers. Vacuum 86 (2012) SI 689-692. (Not IEE SAS).

       1. Soltanian, S.: J. Mater. Res. 30 (2015) 121.

Ondic, L., Babchenko, O., Varga, M., Kromka, A., Ctyroky, J., Pelant, I., : Diamond photonic crystal slab: Leaky modes and modified photoluminescence emission of surface-deposited quantum dots. Sci Rep. 2 (2012) 914. (Not IEE SAS).

        1. Withayachumnankul, W.: Nature Photon. 8 (2014) 586. 2. Sinha, K.: Phys. Rev. A  92 (2015) 023852. 3. Liu, L.: Sci Rep. 6 (2016) 22445.

Babchenko, O., Verveniotis, E., Hruska, K., Ledinsky, M., Kromka, A., Rezek, B., : Direct growth of sub-micron diamond structures. Vacuum 86 (2012) SI 693-695. (Not IEE SAS).

       1. Nelson, G.W.: Topics in Applied Phys. 121 (2015) 165. 2. Arnault, J.C.: RSC Nanosci Nanotechnol. 2014. P. 221. 3. Arnault, J.C.: Carbon Nanostr. 2016. P. 1.

Kromka, A., Babchenko, O., Ižák, T., Hruska, K., Rezek, B., : Linear antenna microwave plasma CVD deposition of diamond films over large areas. Vacuum 86 (2012) SI776-779. (Not IEE SAS).

        1. Yamada, T.: Thin Solid Films 532 (2013) 89. 2. Su, J.J.: Vacuum  107 (2014) SI 51. 3. Mehedi, H. -A.: Diamond Related Mater. 47 (2014) 58. 4. Lebedev, Y.A.: Plasma Sources Sci Technol. 24 (2015) 053001. 5. Feng, S.: Diamond Related Mater. 56 (2015) 36. 6. Li, X.: AER-Advances in Engn. Research  27 (2015) 2170. 7. Kim, J.: IEEE Trans. Plasma Sci 43 (2015) 480. 8. Ficek, M.: IOP Conf. Ser.-Mater. Sci Engn. 104 (2016) 012025. 9. Li, X.: RSC Adv. 6 (2016) 96479. 10. Guo, J.: Applied Surface Sci 370 (2016) 237. 11. Ivanov, O. A.: Plasma Sources Sci Technol. 25 (2016) 035017. 12. Jiang, C.: Arabian J. Sci Engn. 41 (2016) 2671. 13. Liu, D.: Diamond Related Mater. 68 (2016) 42. 14. Zemek, J.: Diamond Related Mater. 68 (2016) 37. 15. Baudrillart, B.: Diamond Related Mater. 71 (2017) 53.

Potocký, Š., Babchenko, O., Hruska, K., Kromka, A., : Linear antenna microwave plasma CVD diamond deposition at the edge of no-growth region of C-H-O ternary diagram. Phys. Status Solidi B 249 (2012) 2612-2615. (Not IEE SAS).

        1. Rezek, B.: Biointerphases 9 (2014) 031012. 2. Ficek, M.: IOP Conf. Ser.-Mater. Sci Engn. 104 (2016) 012025. 3. Davydova, M.: RSC Adv. 6 (2016) 57820. 4. Amans, D.: J. Colloid Interface Sci 489 (2017) SI114.

Ižák, T., Babchenko, O., Varga, M., Potocký, Š., Kromka, A., : Low temperature diamond growth by linear antenna plasma CVD over large area. Phys. Status Solidi B 249 (2012) 2600-2603. (Not IEE SAS).

       1. Barbosa, Divani C.: J. Vacuum Sci Technol. B  32 (2014) 031808. 2. Obrusnik, A.: J. Phys.  D 48 (2015) 065201. 3. Chandran, M.: J. Phys. D 49 (2016) 213002. 4. Baudrillart, B.: Phys. Status Solidi A 213 (2016) 2575. 5. Baudrillart, B.: Diamond Related Mater. 71 (2017) 53.

Wang, Q., Kromka, A., Houdkova, J., Babchenko, O., Rezek, B., Li, M., Boukherroub, R., Szunerits, S., :Nanomolar hydrogen peroxide detection using horseradish peroxidase covalently linked to undoped nanocrystalline diamond surfaces. Langmuir 28 (2012) 587-592. (Not IEE SAS).

         1. Jedraszko, J.: J. Phys. Chem.C  117 (2013) 20681. 2. Petkov, C.: Phys. Status Solidi A 210 (2013) 2048. 3. Lim, China Y.: Langmuir  30 (2014) 12868. 4. Manai, R.: Biosensors Bioelectron. 60 (2014) 311 5. Bogdanowicz, R.: Phys. Status Solidi A 211 (2014) 2319. 6. Rismetov, B.: Diamond Related Mater. 48 (2014) 88. 7. Lin, Z.: ACS Applied Mater. Interfaces 6 (2014) 10775. 8. Kohri, M.: Polymer J. 46 (2014) 373. 9. Shan, Y.: J. Phys. Chem. C  118 (2014) 11085. 10. Simon, N.: Electrochem. Comm. 42 (2014) 17. 11. Svorc, L.: J. Electroanalyt. Chem. 717 (2014) 34. 12. Burmistrova, N. A.: Sensors Actuat. B 193 (2014) 799. 13. Bandzuchova, L.: Inter. J. Environmental Analyt. Chem. 94 (2014) 943. 14. Dinesh, B.: RSC Adv.  4 (2014) 28229. 15. Liu, X.: ACS Applied Mater. Interfaces 7 (2015) 18283. 16. Nicolini, J.V.: J. Chem. Technol. Biotechnol. 90 (2015) 739. 17. Lei, Z.: RSC Adv. 5 (2015) 38665. 18. Ferraz, H.C.: Mater. Sci Engn. C 70 (2017) 15. 19. Buoro, R.M.: Sensors Actuators B 250 (2017) 169. 20. Luo, D.: J. Photochem. Photobiol. C 31 (2017) 139.

Varga, M., Remes, Z., Babchenko, O., Kromka, A., : Optical study of defects in nano-diamond films grown in linear antenna microwave plasma CVD from H2/CH4/CO2 gas mixture. Phys. Status Solidi B 249 (2012) 2635-2639. (Not IEE SAS).

        1. Gaydaychuk, A.V.: J. Phys. Conf. Ser. 652 (2015) 012029. 2. Ficek, M.: IOP Conf. Ser.-Mater. Sci Engn. 104 (2016) 012025.

Kalbacova, M., Broz, A., Kromka, A., Babchenko, O., Kalbac, M., : Controlled oxygen plasma treatment of single-walled carbon nanotube films improves osteoblastic cells attachment and enhances their proliferation. Carbon 49 (2011) 2926-2934. (Not IEE SAS).

       1. Kang, Jeon W.: NANO Lett. 12 (2012) 6170. 2. Hussain, S.: Nanotechnol.  23 (2012) 385604. 3. Chen, Z.: Plasma Processes Polymers 9 (2012) 733. 4. Huang, H.: Nanoscale  4 (2012) 1491. 5. Abrar, M.: Current Applied Phys. 13 (2013) 567. 6. Chang, H.-Y.: Vacuum 87 (2013) 164. 7. Burmaka, G.: Plasma Processes Polymers 11 (2014) 798. 8. Xu, Z.: Chem. Engn. J. 240 (2014) 187. 9. Apartsin, E.K.: ACS Applied Mater. Interfaces  6 (2014) 1454. 10. Gurunathan, S.: Inter. J. Nanomedicine   9 (2014) 363. 11. Padovani, G.C.: J. Phys. Chem.C  119 (2015) 18741. 12. Xu, A.: Mater. Sci Engn. C 48 (2015) 592. 13. Pei, S.: RSC Adv. 5 (2015) 99841. 14. Aria, Adrianus I.: Carbon  81 (2015) 376. 15. Cho, Y.: Biosci Rep. 37 (2017) BSR20160330.

Babchenko, O., Remes, Z., Ižák, T., Rezek, B., Kromka, A., : Deposition of nanocrystalline diamond films on temperature sensitive substrates for infrared reflectance spectroscopy. Phys. Status Solidi B 248 (2011) 2736-2739. (Not IEE SAS).

        1. Swaminathan, S.: RSC Adv. 6 (2016) 49127.

Ondic, L., Dohnalova, K., Ledinsky, M., Kromka, A., Babchenko, O., Rezek, B., : Effective extraction of photoluminescence from a diamond layer with a photonic crystal. ACS Nano 5 (2011) 346-350. (Not IEE SAS).

       1. Girard, H. A.: Diamond Related Mater. 23 (2012) 83. 2. Al Mamun, M.A.: ACS Applied Mater. Interfaces 7 (2015) 17792. 3. Taylor, A.C.: ACS Applied Mater. Interfaces 7 (2015) 6490. 4. Fujimori, A.: Langmuir 31 (2015) 289. 5. Hu, F.: Nanotechnol. 27 (2016) 245709. 6. Arnault, J.C.: RSC Nanosci Nanotechnol. 2014. P. 221. 7. Tasaki, T.: ACS Applied Mater. Interfaces 9 (2017) 14379.

Ondic, L., Kusova, K., Cibulka, O., Pelant, I., Dohnalova, K., Rezek, B., Babchenko, O., Kromka, A., Ganesh, N., : Enhanced photoluminescence extraction efficiency from a diamond photonic crystal via leaky modes. New J. Phys. 13 (2011) 063005. (Not IEE SAS).

      1. Kononenko, T. V.: Optics Lett. 39 (2014) 6962. 2. Sedov, V.: Diamond Related Mater. 56 (2015) 23. 3. Guo, W.: J. Applied Phys. 117 (2015) 113107.

Vanecek, M., Babchenko, O., Purkrt, A., Holovsky, J., Neykova, N., Poruba, A., Remes, Z., Meier, J., Kroll, U., : Nanostructured three-dimensional thin film silicon solar cells with very high efficiency potential. Applied Phys. Lett. 98 (2011) 163503. (Not IEE SAS).

        1. Yu, R.: ACS Nano 5 (2011) 9291. 2. Lee, S.J.: Mater. Chem. Phys. 130 (2011) 733. 3. Soederstroem, K.: J. Applied Phys. 112 (2012) 114503. 4. Lei, P.-H.: Applied Surface Sci 261 (2012) 857. 5. Sai, H.: Applied Phys. Lett. 101 (2012) 173901. 6. Meguro, T.: Japan. J. Applied Phys. 51 (2012) SIUNSP 10NB02. 7. Meng, X.: Optics Express 20 (2012) A560. 8. Vetushka, A.: J. Non-Crystalline Solids 358 (2012) SI2545. 9. Haug, F.-J.: J. Applied Phys. 112 (2012) 024516. 10. Mizuno, H.: Japan. J. Applied Phys. 51 (2012) 042302. 11. Lei, P.-H.: Surface Coatings Technol. 206 (2012) 3258. 12. Li, C.: Progress Chem. 24 (2012) 8. 13. Baik, S.J.: PVSC 2012. P. 1182. 14. Das, N. C.: PVSC 2012. P. 3076. 15. Theuring, M.: Proc. SPIE 8438 (2012) 84381Q. 16. Yu, M.: NANOSCALE 4 (2012) 2783. 17. Mercaldo, L.V.: Solar Energy Mater. Solar Cells 119 (2013) SI67. 18. Kim, K.-H.: Solar Energy Mater. Solar Cells 119 (2013) SI124. 19. Zheng, G.: Optics Comm. 309 (2013) 318. 20. Sai, H.: Applied Phys. Express 6 (2013) 104101. 21. Kuang, Y.: Reports Progress Phys. 76 (2013) 106502 22. Huang, W.-H.: Applied Phys. Lett. 103 (2013) 073107. 23. Mercaldo, L.V.: Solar Energy Mater. Solar Cells 112 (2013) 163. 24. Sai, H.: Applied Phys. Lett. 102 (2013) 053509. 25. Cho, J.: Progress Photovolt. 21 (2013) 77. 26. Wang, P.H.: Applied Phys. Lett. 105 (2014) 183106. 27. Misra, S.: J. Phys. D 47 (2014) 393001. 28. Ledinsky, M.: Applied Phys. Lett. 105 (2014) 111106 . 29. Zhou, H.: IEEE Trans. Nanotechnol. 13 (2014) 997. 30. Wada, H.: Canadian J. Phys.  92 (2014) SI 920. 31. Kim, J.: Advanced Mater. 26 (2014) 4082. 32. Nowak, R.-E.: Solar Energy Mater. Solar Cells 125 (2014) SI305. 33. Wu, Z.: Phys. Status Solidi A 211 (2014) 641. 34. Micco, A.: IEEE Third Mediterranean Photonics Conf. 2014. 35. Liu, C.-P.: RSC Adv. 4 (2014) 34669. 36. Nowak, R.-E.: Adv. Optical Mater. 2 (2014) 94. 37. Gao, F.: Optics Comm. 357 (2015) 28. 38. Shang, A.: Progress Photovolt. 23 (2015) 1734. 39. Kuang, Y.: J. Applied Phys. 118 (2015) 185307. 40. Ishizaki, K.: Optics Express 23 (2015) A1040. 41. Micco, A.: Mater. 8 (2015) 3648. 42. Mercaldo, L.V.: Solar Energy Mater. Solar Cells 136 (2015) 32. 43. Nowak, R.-E.: IEEE J. Photovolt. 5 (2015) 479. 44. Haug, F.-J.: Energy Environmental Sci 8 (2015) 824. 45. Rizal, B.: Analyst 140 (2015) 39. 46. van Dijk, L.: ACS Photon. 3 (2016) 685. 47. Morawiec, S.: Sci Rep. 6 (2016) 22481. 48. Mercaldo, L.V.: Progress in Photovolt.24 (2016)  968. 49. Orhan, J.-B.: Solar Energy Mater. Solar Cells 140 (2015) 344. 50. Barugkin, C.: Inter. J. Photoenergy  (2016) 7390974. 51. Veldhuizen, L. W.: Solar Energy Mater. Solar Cells 158 (2016) SI209. 52. Ramanujam, J.: Progress in Mater. Sci 82 (2016) 294. 53. De Zoysa, M.: Applied Phys. Express 10 (2017) 012302.

Kozak, H., Kromka, A., Babchenko, O., Rezek, B., : Directly grown nanocrystalline diamond field-effect transistor microstructures. Sensor Lett. 8 (2010) SI482-487. (Not IEE SAS).

           1. Svorc, L.: J. Electroanalyt. Chem. 717 (2014) 34. 2. Bandzuchova, L.: Inter. J. Environmental Analyt. Chem. 94 (2014) 943.                  3. Alcantar-Pena, J. J.: Diamond Related Mater. 69 (2016) 207. 4. Alcantar-Pena, J.J.: Diamond Related Mater. 69 (2016) 221.

Davydova, M., Kromka, A., Rezek, B., Babchenko, O., Stuchlik, M., Hruska, K., : Fabrication of diamond nanorods for gas sensing applications. Applied Surface Sci 256 (2010) 5602-5605. (Not IEE SAS).

       1. Guo, J.: Diamond Related Mater. 20 (2011) 551. 2. Orlanducci, S.: Nanosci Nanotechnol. Lett. 3 (2011) SI83. 3. Zhang, X.-J.: Applied Surface Sci 258 (2012) 664. 4. Ruslinda, A. R.: Biosensors Bioelectron. 40 (2013) SI277. 5. Bogue, R.: Sensor Rev. 34 (2014) 1. 6. Scorsone, E.: RSC Nanosci Nanotechnol.  (2014) 448.

Babchenko, O., Ižák, T., Ukraintsev, E., Hruska, K., Rezek, B., Kromka, A., : Toward surface-friendly treatment of seeding layer and selected-area diamond growth. Phys. Status Solidi B 247 (2010) 3026-3029. (Not IEE SAS).

       1. Zhuang, H.: Langmuir 27 (2011) 11981. 2. Zhang, T.: J. Crystal Growth 372 (2013) 49. 3. Wang, M.: Crystal Growth Design 13 (2013) 716. 4. Jiang, X.: Topics in Applied Phys. 121 (2015) 31.

Babchenko, O., Kromka, A., Hruska, K., Kalbacova, M., Broz, A., Vanecek, M., : Fabrication of nano-structured diamond films for SAOS-2 cell cultivation. Phys. Status Solidi A 206 (2009) 2033-2037. (Not IEE SAS).

       1. Picollo, F.: Sensors 15 (2015) 515. 2. Carabelli, V.: ACS Chem. Neurosci 8 (2017) SI252.

Kulha, P., Kromka, A., Babchenko, O., Vanecek, M., Husák, M., Williams, O., Haenen, K., : Nanocrystalline diamond piezoresistive sensor. Vacuum 84 (2009) 53-56. (Not IEE SAS).

      1. Liao, M.: Diamond Related Mater. 24 (2012) 69. 2. Vul‘, A.Ya.: RSC Nanosci Nanotechnol. 2014. P. 27. 3. Wiora, N.: Diamond Related Mater. 70 (2016) 145.

Babchenko, O., Kromka, A., Hruska, K., Michalka, M., Potmesil, J., Vanecek, M., : Nanostructuring of diamond films using self-assembled nanoparticles. Central European J. Phys. 7 (2009) 310-314. (Not IEE SAS).

      1. Smirnov, W.: Diamond Related Mater. 19 (2010) 186. 2. Janssen, W.: Diamond Related Mater. 20 (2011) 779. 3. Janssen, W.: Diamond Related Mater. 20 (2011) 389. 4. Nelson, G.W.: Topics in Applied Phys. 121 (2015) 165.

Kromka, A., Potocký, Š., Rezek, B., Babchenko, O., Kozak, H., Vanecek, M., Michalka, M., : Role of polymers in CVD growth of nanocrystalline diamond films on foreign substrates. Phys. Status Solidi B 246 (2009) SI2654-2657. (Not IEE SAS).

         1. Varshney, D.: J. Phys. D 44 (2011) 085502. 2. Golunski, L.: Acta Phys. Polonica A 128 (2015) 136. 3. Bogdanowicz, R.: Diamond Related Mater. 55 (2015) 52. 4. Dzuba, J.: Proc. SPIE 9517 (2015) 95171I.

Kromka, A., Babchenko, O., Kozak, H., Hruska, K., Rezek, B., Ledinsky, M., Potmesil, J., Michalka, M., Vanecek, M., : Seeding of polymer substrates for nanocrystalline diamond film growth. Diamond Related Mater. 18 (2009) 734-739. (Not IEE SAS).

      1. Girard, H.A.: ACS Applied Mater. Interfaces 1 (2009) 2738. 2. Hess, A.E.: J. Microelectromech. Systems 20 (2011) 867. 3. Bogdanowicz, R.: Applied Phys. A 116 (2014) 1927. 4. Bogdanowicz, R.: Diamond Related Mater. 55 (2015) 52. 5. Ficek, M.: Acta Phys. Polonica A 127 (2015) 868. 6. Arnault, J.C.: RSC Nanosci Nanotechnol. 2014. P. 221. 7. Arnault, J.C.:Carbon Nanostr. 2016. P. 1.

Kromka, A., Babchenko, O., Rezek, B., Ledinsky, M., Hruska, K., Potmesil, J., Vanecek, M., : Simplified procedure for patterned growth of nanocrystalline diamond micro-structures. Thin Solid Films 518 (2009) 343-347. (Not IEE SAS).

      1. Girard, H.A.: ACS Applied Mater. Interfaces 1 (2009) 2738. 2. Zhuang, H.: Langmuir 27 (2011) 11981. 3. Hess, A.E.: J. Microelectromech. Systems 20 (2011) 867. 4. Wiora, M.: Carbon-Based Nanomater. Hybrids (2014) 5. 5. Jiang, X.: Topics in Applied Phys. 121 (2015) 31.

Kalbacova, M., Broz, A., Babchenko, O., Kromka, A., : Study on cellular adhesion of human osteoblasts on nano-structured diamond films. Phys. Status Solidi B 246 (2009) SI2774-2777. (Not IEE SAS).

        1. Lee, S.-K.: Nanotechnol. 21 (2010) 505302. 2. Anselme, K.: Acta Biomater. 6 (2010) 3824. 3. Torrengo, S.: Diamond Related Mater. 20 (2011) 990. 4. Singh, A.V.: J. Biomedical Mater. Research A 101 (2013) 3019. 5. Soininen, A.: J. Biomedical Mater. Research B 102 (2014) 1462. 6. Jesion, I.: Biotechnol. Biotechnol. Equipment 29 (2015) 415. 7. Taylor, A.C.: J. Neural Engn. 12 (2015) 066016. 8. Fisher, L.E.: Biointerphases 11 (2016) 011014.