Ing. Izsák Tibor, PhD.

Prochazka, V., Kulha, P., Izsák, T., Ukraintsev, E., Varga, M., Jirasek, V., and Kromka, A.: Detection of globular and fibrillar proteins by quartz crystal microbalance sensor coated with a functionalized diamond thin film, Applied Surface Sci 589 (2022) 153017.

1. Yin, S.P.: Front. Nutrition 9 (2023) 1110615.
2. Silori, G.K.: Solar Energy Mater. Solar Cells 260 (2023) 112460.

Budil, J., Szabó, O., Liskova, P., Stenclova, P., Ižák, T., Potocký, Š., and Kromka, A.: Impact of electrolyte solution on electrochemical oxidation treatment of Escherichia coli K-12 by boron-doped diamond electrodes, Lett. in Applied Microbiol. 74 (2022) 924-931.

1. Tang, Y.N.: CHEMOSPHERE 307 (2022) 135912.

Ahmad, N.A., Rahim, R.A., Rezek, B., Kromka, A., Ismail, N.S., Gopinath, S.C.B., Izak, T., Prochazka, V., Faudzi, F.N.M., Abidin, A.S.Z., Maidizn, N.N.M.: Nanocrystalline diamond electrolyte-gates in field effect transistor for a prolific aptasensing HIV-1 tat on hydrogen-terminated surface, Inter. J. Nanoelectr. Mater. 13 (2020) 295-306. (Not IEE SAS)

1. Zhang, Q.W.: IEEE Trans. Electron Dev. 69 (2022) 4534.
2. Xu, B.Q.: Mater. Lett. 318 (2022) 132116.
3. Zhang, Q.W.: J. Electrochem. Soc 170 (2023) 037507.

Procházka, V., Matějka, R., Ižák, T., Szabó, O., Štěpanovská, J., Filová, E., Bačáková, L., Jirásek, V., and Kromka, A.: Nanocrystalline diamond-based impedance sensors for real-time monitoring of adipose tissue-derived stem cells, Colloids Surf. B: Biointerf. 177 (2019) 130-136. (Not IEE SAS)

1. Handschuh-Wang, S.: Small 17 (2021) 2007529.

Štenclová, P., Vyskočil, V., Szabó, O., Ižák, T., Potocký, Š., and Kromka, A.: Structured and graphitized boron doped diamond electrodes: Impact on electrochemical detection of Cd2+ and Pb2+ ions, Vacuum 170 (2019) 108953. (Not IEE SAS)

1. El-Shahawi, M.S.: Chem. Pap. 75 (2021) 2395.
2. Zhao, G.: Sensors Actuators B 350 (2022) 130834.
3. Shellaiah, M.: Nanomater. 12 (2022) 64.
4. Yi, Y.H.: Trends in Environment. Analyt. Chem. 33 (2022) 00152.
5. Kondo, T.: Current Opinion in Electrochem. 32 (2022) 100891.
6. Espinoza-Montero, P.J.: Current Opinion in Solid State Mater. Sci 26 (2022) 100988.
7. Kim, S.: J. Mater. Res. Technol.-JMR&T 23 (2023) 1375.
8. Brosler, P.: Front. Mater. 10 (2023) 1020649.
9. Nazik, G.: Zeitschrift Physik. Chemie 237 (2023) 1257.

Artemenko, A., Ižák, T., Marton, M., Ukraintsev, E., Stuchlík, J., Hruška, K., Vojs, M., and Kromka, A.: Stability of the surface termination of nanocrystalline diamond and diamond-like carbon films exposed to open air conditions, Diamond Related Mater. 100 (2019) 107562. (Not IEE SAS)

1. Mendez-Linan, J.I.: Carbon 169 (2020) 32.
2. Dychalska, A.: Materials 14 (2021) 1301.
3. Ortiz-Ortega, E.: Applied Surface Sci 565 (2021) 150362.
4. Meng, K.K.: Diamond Related Mater. 120 (2021) 108609.
5. Kaczorowski, W.: Materials 15 (2022) 3883.
6. Kanasugi, K.: Bioengn. 9 (2022) 505.
7. Osman, L.: Applied Phys. Express 15 (2022) 115004.

Zemek, J., Houdková, J., Jiricek, P., Ižák, T., Kalba, M.: Non-destructive depth profile reconstruction of single-layer graphene using angle-resolved X-ray photoelectron spectroscopy, Applied Surface Sci 491 (2019) 16-23. (Not IEE SAS)

1. Ozdilek, C.: Ceramics Inter. 46 (2020) 27800.
2. Spencer, B.F.: Applied Surface Sci 541 (2021) 148635.
3. Konvalina, I.: Nanomater. 11 (2021) 2435.
4. Hoshina, Y.: Japan. J. Applied Phys. 60 (2021) 101003.
5. Hoshina, Y.: Japan. J. Applied Phys. 61 (2022) 046501.

Sojková, M., Šiffalovič, P., Babchenko, O., Vanko, G., Dobročka, E., Hagara, J., Mrkývková, N., Majková, E.,  Ižák, T., Kromka, A., and Hulman, M.: Carbide-free one-zone sulfurization method grows thin MoS₂ layers on polycrystalline CVD diamond, Sci Rep. 9 (2019) 2001.

1. Ou, N. C.: Organometall. 39 (2020) 956.
2. Mouloua, D.: Materials 14 (2021) 3283.
3. Goel, N.: Nanotechnol. 32 (2021) 375711.
4. Bhowmik, S.: I SCI 25 (2022) 103832.
5. Zhang, Z.: Crystals 13 (2023) 1034.
6. Raveena, J.: J. Mater. Sci-Mater. Electron. 34 (2023) 1164.
7. Hazdra, P.: Phys. Status Solidi A 220 (2023) Iss. 23.
8. Zeng, S.S.: Adv. Optic. Mater. 11 (2023) Iss. 15.
9. Zhang, C.L.: J. Computat. Methods Sci Engn. 23 (2023) 2595.

Stankova, L., Musilkova, J., Broza, A., Potocký, Š., Kromka, A., Kozak, H., Ižák, T.,  Artemenko, A., Stranska, D., and Bacakova, L.: Alterations to the adhesion, growth and osteogenic differentiation of human osteoblast-like cells on nanofibrous polylactide scaffolds with diamond nanoparticles, Diamond Related Mater. 97 (2019) 107421. (Not IEE SAS)

1. Dorner-Reisel, A.: Lubricants 8 (2020) 35.
2. Lopez de Armentia, S.: Materials 13 (2020) 5083.

Varga, M., Potocký, Š., Domonkos, M., Ižák, T., Babchenko, O., and Kromka, A.: Great variety of man-made porous diamond structures: pulsed microwave cold plasma system with a linear antenna arrangement, ACS Omega 4 (2019) 8441-8450. (Not IEE SAS)

1. Marton, M..: Vacuum 170 (2019) 108954.
2. Handschuh-Wang, S.: Small 17 (2021) 2007529.
3. Wang, J.P.: Carbon 183 (2021) 259.
4. Ashcheulov, P.: Adv. Mater. Interfac. 9 (2022) 2200375.
5. Cho, J.M.: Surfaces Interfaces 34 (2022) 102362.
6. Sedov, V.: Nanoscale Adv. 5 (2023) 1307.
7. Xu, J.: Chem. Comm. 59 (2023) 4838.

Domonkos, M., Ižák, T., Varga, M., Potocký, Š., Demo, P., and Kromka, A.: Diamond nucleation and growth on horizontally and vertically aligned Si substrates at low pressure in a linear antenna microwave plasma system, Diamond Related Mater. 82 (2018) 41-49. (Not IEE SAS)

1. Reshi, B.A.: Mater. Res. Express 6 (2019) 096420.
2. Dekkar, D.: Diamond Related Mater. 94 (2019) 28.
3. Song, C.W.: Coatings 9 (2019) 269.
4. Kumar, S.: Carbon 143 (2019) 678.
5. Balakin, S.: Applied Sci (Switz.) 9 (2019) 1064.
6. Zheng, S.: Mater. Res. Express 6 (2019) 046520.
7. Khan, S.U.D.: Applied Nanosci 12 (2022) SI3111.
8. Deepak, G.D.: Europ. Phys. J.-Applied Phys. 97 (2022) 39.

Romanyuk, O., Varga, M., Tulic, S., Ižák, T., Jiricek, P., Kromka, A., Skakalova, V., and Rezek, B.: Study of Ni-catalyzed graphitization process of diamond by in situ x-ray photoelectron spectroscopy, J. Phys. Chem. C 122 (2018) 6629-6636. (Not IEE SAS)

1. Park, J.-S.: Chem. Engn. J. 373 (2019) 227.
2. Vicentini, R.: J. Power Sourc. 434 (2019) 226737.
3. Kou, T.: Nature Comm. 11 (2020) 590.
4. He, J.: Applied Surface Sci 515 (2020) 146020.
5. Janke, D.: Carbon 159 (2020) 656-667
6. Xu, J.: J. Amer. Chem. Soc 142 (2020) 2310.
7. Linnik, S.A.: Instrum. Experimen. Techniq. 64 (2021) 177.
8. Okotrub, A.V.: J. Phys. Chem. C 127 (2023) 3563.

Dragounová, K., Ižák, T., Kromka, A., Potůček, Z., Bryknar, Z., and Potocký, Š.: Influence of the growth temperature on the Si-V photoluminescence in diamond thin films, Applied Phys. A 124 (2018) 219. (Not IEE SAS)

1. Song, J.: Physica Status Solidi B 255 (2019) 1800173.
2. Himics, L.: J. Lumin. 215 (2019) 116681.
3. Chen, L.: Acta Phys. Sinica 68 (2019) 168101.
4. Tan, X.: Inter. J. Modern Phys. B 34 (2020) 2050036.
5. Tan, X.: J. Optic. Soc America B 38 (2021) 1167.
6. Li, J.P.: Acta Physica Sinica 72 (2023) 038102.

Romanyuk, O., Bartoš, I., Gordeev, I., Artemenko, A., Varga, M., Ižák, T., Marton, M., Jiříček, P., and Kromka, A.: Electron affinity of undoped and boron-doped polycrystalline diamond films, Diamond Related Mater. 87 (2018) 208-214. (Not IEE SAS)

1. Chen, S.-T.: Diamond Related Mater. 94 (2019) 155.
2. Chen, S.-T.: J. Mater. Process. Technol. 82 (2020) 116686.
3. Serpente, V.: Mater. Chem. Phys. 249 (2020) 122989.
4. Li, G.: J. Manufact. Process. 56 (2020) 400.
5. Jaggernauth, A.: J. Mater. Chem. C‏ 8 (2020) 13127.
6. Carcione, R.: Applied Surface Sci 540 (2021) 148334.
7. Fujiwara, M.: Nanotechnol. 32 (2021) 482002.
8. Eremin, S.A.: Inorg. Mater.-Applied Res. 13 (2022) 455.
9. Zheng, Y.T.: ACS Applied Nano Mater. 5 (2022) 10878.
10. Carcione, R.: Surface Coat. Technol. 467 (2023) 129662.
11. Karmakar, S.: ACS Applied Electron. Mater. 5 (2023) 3592.

Babchenko, O., Vanko, G., Gerboc, M., Ižák, T., Vojs, M., Lalinský, T., and Kromka, A.: Study on electronic properties of diamond/SiNx-coated AlGaN/GaN high electron mobility transistors operating up to 500 °C, Diamond Related Mater. 89 (2018) 266-272.

1. Siddique, A.: ACS Applied Electron. Mater. 1 (2019) 1387.
2. Zhu, T.: Semicond. Sci Technol.‏ 35 (2020) 055006.
3. Tijent, F.Z.: ECS J. Solid State Sci Technol. 10 (2021) 074003.
4. Sobaszek, M.: Materials 14 (2021) 6328.
5. Zheng, Y.T.: Ceram. Inter. 48 (2022) 36441.
6. Abdullah, M.F.: Microelectron. Engn. 273 (2023) 111958.
7. Wang, Y.N.: Crystals 13 (2023) 500.
8. Yang, C.: Inter. J. Heat Mass Transfer 214 (2023) 124433.

Procházka, V., Cifra, M., Kulha, P., Ižák, T., Rezek, B., and Kromka, A.: Influence of non-adherent yeast cells on electrical characteristics of diamond-based field-effect transistors, Applied Surface Sci 395 (2017) 214-219. (Not IEE SAS)

1. Piro, B.: Biosensors 8 (2018) 65.
2. Chen, B.: Sensors (Switz.) 18 (2018) 386.
3. Yang, J.: Measurement 173 (2021) 108668.

Varga, M., Ižák, T., Vretenár, V., Kozak, H., Holovsky, J., Artemenko, A., Hulman, M., Skákalová, V., Lee, D.S., and Kromka, A.: Diamond/carbon nanotube composites: Raman, FTIR, and XPS spectroscopic studies, Carbon 111 (2017) 54-61. (Not IEE SAS)

1. Li, H.: Water Air Soil Poll. 228 (2017) 201.
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3. Li, D.: Corrosion Sci 124 (2017) 103.
4. Li, H.: Water Air Soil Pollut. 228  (2017) 201.
5. Silva, A.A.: Diamond Related Mater. 75 (2017) SI116.
6. Kim, S.H.: Sci Rep. 7 (2017) 13756.
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8. Zhang, J.: Phys. Chem. Chem. Phys. 19 (2017) 22462.
9. Ulyanov, A.N.: J. Alloys Comp. 722 (2017) 77.
10. Sanyal, O.: Carbon 127 (2018) 688.
11. Wang, J.: J. Mater. Sci 53 (2018) 1833.
12. Xiao, J.: Coatings 8 (2018) 18.
13. Bardestani, R.: Biomass Bioenergy 108 (2018) 101.
14. Su, L.-X.:Carbon 130 (2018) 384.
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21. Nakaramontri, Y.: Express Polymer Lett. 12 (2018) 867.
22. Hodoroaba, B.: Monthly Notices Royal Astron. Soc 481 (2018) 2841.
23. Bhunia, M.M.: Carbon 139 (2018) 1010.
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26. Lu, C.: Chemistryopen 8 (2019) 87.
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29. Ferreira, F.V.: Carbon-Based Nanofillers and their Rubber Nanocomposites: Carbon Nano-Objects 2019, p. 1-45.
30. Hu, L.: Carbon 144 (2019) 805.|
31. de los Reyes, C.A.: ACS Omega 4 (2019) 5098.
32. Ma, X.: Applied Phys. Lett. 114 (2019) 253502.
33. Zhou, J.: J. Applied Polymer Sci 136 (2019) 47653.
34. Kasahara, S.: Analyt. Chem. 91 (2019) 4980.
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36. Guan J.: Mater. Res. Express 6 (2019) 085633.
37. Naidek, N.: New J. Chem. 43 (2019) 10482.
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40. Wang, X.: Nanomater. 9 (2019) 1476.
41. Wang, Z.: ACS Macro Lett. 8 (2019) 1240.
42. Nilkar, M.: Diamond Related Mater. 98 (2019) UNSP 107482.
43. Zheng, Y.: Surface Coat. Technol. 374 (2019) 409.
44. Gurova, O.A.: Physica Status Solidi B 256 (2019) 1800742.
45. Marton, M.: Vacuum 167 (2019) 182.
46. Liu, J.: Applied Catalysis B 257 (2019) UNSP 117880.
47. Zhou, J.: Macromol. Research 27 (2019) 1144.
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51. Sarac, Elcin C.: J. Applied Polymer Sci 136 (2019) 48347.
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56. Dong, H.: Energy & Fuels 34 (2020) 1453.
57. Fang, S.: CRYSTENGCOMM 22 (2020) 602.
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59. Vozniakovskii, A.: J.Colloid Interface Sci 565 (2020) ‏ 305.
60. Zheng, Y.: J. Mater. Res. 35 (2020) SI462.
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70. Zhang, J.: Electrochim. Acta 354 (2020) 136649.
71. Kertsomboon, T.: Polymer Degradation Stab. 179 (2020) 109266.
72. Zhang, H.: Fuel 275 (2020) 117879.
73. Hussain, S.: ACS Sustainable Chem. Engn. 8 (2020) 12248.
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75. Deng, J.: Bioresource Technol. 310 (2020) 123438.
76. Chen, N.: ACS Nano 14 (2020) 8059.
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78. Tsen, W.-C.: Polymer Engn. Sci‏ 60 (2020) 1832.
79. Li, Q.: Industrial Engn. Chem. Res. 59 (2020) 11453.
80. Fang, S.: CRYSTENGCOMM 22 (2020) 3854.
81. Neves, T.de F.: Water Air Soil Pollution 231 (2020) 304.
82. Shen, Y.: ACS Applied Mater. Interfac. 12 (2020) 25484.
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88. Kuchtova, G.: J. Electroanalyt. Chem. 863 (2020) 114036.
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138. Venkatesh, G.: Colloids Surfac. A 629 (2021) 127523.
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Varga, M., Stehlik, S., Kaman, O., Ižák, T., Domonkos, M., Lee, D.S., and Kromka, A.: Templated diamond growth on porous carbon foam decorated with polyvinyl alcohol-nanodiamond composite, Carbon 119 (2017) 124-132. (Not IEE SAS)

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

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Dragounová, K., Ižák, T., Kromka  A., Potuček, Z., Bryknar, Z., and Potocký, Š.: Influence of substrate material on spectral properties and thermal quenching of photoluminescence of silicon vacancy colour centres in diamond thin films, J. Electr. Engn. 68 (2017), Iss. 7, 3–9. (Not IEE SAS)

1. Behul, M.: Adv.Electr. Electron. Engn. 16 (2018) 239.
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Babchenko, O., Kozak, H., Ižák, T., Stuchlik, J., Remes, Z., Rezek, B., and Kromka, A.: Fabrication of diamond-coated germanium ATR prisms for IR-spectroscopy, Vibrational Spectroscopy 84 (2016) 67–73. (Not IEE SAS)

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Verdanova, M., Rezek, B., Broz, A.,Ukraintsev, E., Babchenko, O., Artemenko, A., Ižák, T., Kromka, A., Kalbac, M., and Kalbacova, M.H.: 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.
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Ižák, T., Jirásek, V., Vanko, G., Dzuba, J., and Kromka, A.: Temperature-dependent stress in diamond-coatewd AlGaN/GaN heterostructures, Mater. & Design 106 (2016) 305-312.

Domonkos, M., Ižák, T., Kromka, A., and Varga, M.: Polymer‐based nucleation for chemical vapour deposition of diamond, J. Applied Polymer Sci 133 (2016) 43688. (Not IEE SAS)

1. Yi, Y.: Surface Coat. Technol. 349 (2018) 959.
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Kromka, A., Ižák, T., Davydova, M., and Rezek, B.: Nanocrystalline diamond films for electronic monitoring of gas and organic molecules. In ASDAM 2016. Eds. Š. Haščík et al. IEEE 2016. ISBN 978-1-5090-3081-1. P. 193-198. (Not IEE SAS)

1. Power, A.C.: Nanotechnol. Rev. 7 (2018) 19.

Ižák, T., Procházka, V., Sakata, T., Rezek, B., and Kromka, A.: Real-time monitoring of cell activities by diamond solution-gated field effect transistors, Procedia Engn. 168 (2016) 469-472. (Not IEE SAS)

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1. Pasquarelli, A.: Physica Status Solidi A 215 (2018) 1800211.
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Jirasek, V., Ižák, T., Varga, M., Babchenko, O., and Kromka, A.: Investigation of residual stress in structured diamond films grown on silicon, Thin Solid Films 589 (2015) 857-863. (Not IEE SAS)

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Dzuba, J., Vanko, G., Vojs, M., Rýger, I., Ižák, T., Jirásek, V., Kutiš, V., and Lalinský, T.:  Finite element analysis of AlGaN/GaN micro-diaphragms with diamond, Proc. SPIE 9517 (2015) 95171I.

1. Zhao, Y.: Sensors Actuators A 309 (2020) 112017.

Ižák, T., Babchenko, O., Jirásek, V., Vanko, G., Vojs, M., and Kromka, A.: Influence of diamond CVD growth conditions and interlayer material on diamond/GaN interface, Mater. Sci Forum 821-823 (2015) 982-985.

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Babchenko, O., Potocky, S., Ižák, T., Hruska, K., Bryknar, Z., and Kromka, A.: Influence of surface wave plasma deposition conditions on diamond growth regime, Surface Coatings Technol. 271 (2015) 74-79. (Not IEE SAS)

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Kromka, A., Čech, J., Kozak, H., Artemenko, A., Ižák, T., Čermák, J., Rezek, B., and Černák, M.: Low-Temperature hydrogenation of diamond nanoparticles using diffuse coplanar surface barrier discharge at atmospheric pressure, Phys. Status Solidi B 252 (2015) 2602-2607. (Not IEE SAS)

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Ižák, T., Vanko, G., Babchenko, O., Potocký, Š., Marton, M., Vojs, M., Choleva, P., and Kromka, A.: Diamond-coated three-dimensional GaN micromembranes: Effect of nucleation and deposition techniques, Phys. Status Solidi B 252 (2015) 2585–2590.

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1. Kajisa, T.: ACS Applied Mater. Interfac. 10 (2018) 34983.
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Ižák, T., Sakata, T., Miyazawa, Y., Kajisa, T., Kromka, A., and Rezek, B.: Diamond-coated field-effect sensor for DNA recognition – influence of material and morphology, Diamond Related Mater. 60 (2015) 87-93. (Not IEE SAS)

1. Hlongwane, G.N.: South African J. Chem. Engn. 27 (2019) 16.
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Vojs, M., Varga, M., Babchenko, O., Ižák, T., Mikolasek, M., Marton, M., and 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.
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Ižák, T., Novotná, K., Kopová, I., Bačáková, L., Varga, M., Rezek, B., and Kromka, A.: Hydrogen-terminated diamond sensors for electrical monitoring of cells, Key Engn. Mater. 605 (2014)577–580. (Not IEE SAS)

1. Marton, M.: Vacuum 170 (2019) 108954.
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Varga, M., Vretenar, V., Ižák, T., Skakalova, V., and Kromka, A.: Carbon nanotubes overgrown and ingrown with nanocrystalline diamond deposited by different CVD plasma systems, Phys. Status Solidi B 251 (2014) 2413-2419. (Not IEE SAS)

1. Marton, M.: Vacuum 167 (2019)‏ 182.

Domonkos, M., Ižák, T., Stolcova, L., Proska, J., and Kromka, A.: Fabrication of periodically ordered diamond nanostructures by microsphere lithography, Phys. Status Solidi B 251 (2014) 2587-2592. (Not IEE SAS)

1. Taylor, A.C.: ACS Applied Mater. Interfac. 7 (2015) 6490.
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Ižák, T., Babchenko, O., Jirásek, V., Vanko, G., Vallo, M., Vojs, M., and Kromka, A.: Selective area deposition of diamond films on AlGaN/GaN heterostructures, Phys. Status Solidi B 251 (2014) 2574-2580.

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Ižák, T., Babchenko, O., Potocky, S., Remes, Z., Kozak, H., Verveniotis, E., Rezek, B., and 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.
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Domonkos, M., Ižák, T., Štolcová, L., Proška, J., Kromka, A.: In NANOCON 2013, pp. 34-38. (Not IEE SAS)

1. Lotito, V.: Adv. Colloid Interface Sci 304 (2022) 102538.
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Ižák, T., Novotná, K., Kopová, I., Bačáková, L., Rezek, B., and Kromka, A.: H-terminated diamond as optically transparent impedance sensor for real-time monitoring of cell growth, Phys. Status Solidi B 250 (2013) 2741-2746. (Not IEE SAS)

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Ižák, T., Sveshnikov, A., Demo, P., and Kromka, A.: Enhanced spontaneous nucleation of diamond nuclei in hot and cold microwave plasma systems, Phys. Status Solidi B 250 (2013) 2753-2758. (Not IEE SAS)

1. Drijkoningen, S.: Crystal Growth Design 17 (2017) 4306.

Kromka, A., Babchenko, O., Ižák, T., Potocky, S., Varga, M., Rezek, B., Sveshnikov, A., and Demo, P.: Diamond nucleation and seeding techniques for tissue regeneration. In: Diamond based materials for biomedical applications. Woodhead Publ. 2013 ISBN 0-85709-340-1. Chapter 10, pp. 206-255. (Not IEE SAS)

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Domonkos, M., Ižák, T., Štolcová, L., Proška, J., Kromka, A.: Controlled structuring of self-assembled polystyrene microsphere arrays by two different plasma systems. In NANOCON 2013, pp. 34-38. (Not IEE SAS)

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Potocky, S., Cada, M., Babchenko, O., Ižák, T., Davydova, M., and 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)

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

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Varga, M., Ižák, T., Kromka, A., Veselý, M., Hruška, K., and Michalka, M.: Study of diamond film nucleation by ultrasonic seeding in different solutions, Central Europ. J. Phys. 10 (2012) 218-224. (Not IEE SAS)

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Stehlik, S., Ižák, T., Kromka, A., Dolenský, B., Havlík, M., and Rezek, B.: Sensitivity of diamond-capped impedance transducer to tröger’s base derivative, ACS Appl. Mater. Interfaces 4 (2012) 3860-3865. (Not IEE SAS)

1. Lee, H.-J.: ACS Applied Mater. Interfac. 5 (2013) 11631.
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Varga, M.,  Kotlár, M., Vretenár, V., Ižák, T., Ledinský, M., Michalka, M., Skákalová, V., Kromka, A., and Veselý, M.: HFCVD growth of various carbon nanostructures on SWCNT paper controlled by surface treatment, Phys. Status Solidi B 249 (2012) 2399-2403. (Not IEE SAS)

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

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