Ing. Varga Marián, PhD.

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.

Tulić, S., Waitz, T., Čaplovičová, M., Habler, G., Varga, M., Kotlár, M., Vretenár, V., Romanyuk, O., Kromka, A., Rezek, B., and  Skákalová, V.: Covalent diamond–graphite bonding: mechanism of catalytic transformation, ACS Nano 13 (2019) 4621–4630. (Not IEE SAS)

1. Hembram, K.P.S.S.: Mater. Horizons 7 (2020) 470.
2. Greshnyakov, V.A.: J. Phys.: Conf. Ser. 1431 (2020) 012016.

Cajzl, J., Nekvindová, P., Macková, A., Malinský, P., Oswald, J., Remeš, Z., Varga, M., Kromka, A. Akhetova, B., Böttger, R., and Prajzler, V.: Erbium luminescence centres in single- and nano-crystalline diamond—effects of ion implantation fluence and thermal annealing, Micromachines 9 (2018) 316. (Not IEE SAS)

1. Liu, K.: Adv. Mater. 33 (2021)‏ SI2000891.

Stehlik, S., Ondič, L., Varga, M., Fait, J., Artemenko, A., Glatzel, T., Kromka, A., and Rezek, B.: Silicon-vacancy centers in ultra-thin nanocrystalline diamond films, Micromachines 9 (2018) 281. (Not IEE SAS)

1. Pan, Y.: Applied Sci 9 (2019) 5471.
2. Shen, W.: J. Mater. Chem. C 7 (2019) 9756.
3. Ekimov, E. A.: Semicond. Semimetals 103 (2020) 161.

Domonkos, M., Varga, M., Ondič, L., Gajdošová, L., and Kromka, A.: Microsphere lithography for scalable polycrystalline diamond-based near-infrared photonic crystals fabrication, Mater.  Design 139 (2018) 363-371. (Not IEE SAS)

1. Mehmel, L.: Phys. Status Solidi A 215 (2018) 1800391.
2. Kushnir, S.E.: Mater. Design 144 (2018) 140.
3. Kumar, N.: Diamond Related Mater. 97 (2019) 107472.
4. Zhang, J.: Polymers 12 (2020) 964.
5. Tien Van, N.: Applied Sci-Basel 10 (2020) 5232.
6. Yang, B.: Carbon 171 (2021) 455.

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.

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.

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. Jaggernauth, A.: J. Mater. Chem. C‏ 8 (2020) 13127.
5. Li, G.: J. Manufact. Process. 56 (2020) 400.
6. Carcione, R.: Applied Surface Sci 540 (2021) 148334.

Cajzl, J., Akhetova, B., Nekvindová, P., Macková, A., Malinský, P., Oswald, J., Remeš, Z., Varga, M., and Kromka, A.: Co‐implantation of Er and Yb ions into single‐crystalline and nano‐crystalline diamond, Surface Interface Anal. 50 (2018) 1218-1223. (Not IEE SAS)

1. Palyanov, Y.N.: Crystals 9 (2019) 300.
2. Vanpoucke, D.E.P.: Diamond Related Mater. 94 (2019) 233.

Stehlik, S., Varga, M., Stenclova,  P., Ondič, L., Ledinsky, M., Pangrac, J., Vanek, O., Lipov, J., Kromka, A., and Rezek, B.: Ultrathin nanocrystalline diamond films with silicon vacancy color centers via seeding by 2 nm detonation nanodiamonds, ACS Appl. Mater. Interfaces 9 (2017) 38842–38853. (Not IEE SAS)

1. Weng, J.: J. Crystal Growth 495 (2018) 1.
2. Krishnia, L.: Diamond Related Mater. 87 (2018) 18.
3. Liu, C.-W.: Applied Surface Sci 455 (2018) 581.
4. Petit, T.: Diamond Related Mater. 89 (2018) 52.
5. Inam, F.A.: J. Optical Soc America B 35 (2018) 2153.
6. Sankaran, K.J.: ACS Omega 3 (2018) 9956.
7. Balakin, S.: Applied Sci 9 (2019) 1064.
8. Janssens, S.D.: Diamond Related Mater. 98 (2019) 107511.
9. Huang, L.: Applied Surface Sci 527 (2020) 146733.
10. Lu, S.: Carbon 159 (2020) 9.
11. Sedov, V.: ACS Applied Nano Mater. 3 (2020) 1324.
12. Yang, B.: Carbon 156 (2020) 242.
13. Guo, X.: J. Phys. D 53 (2020) 015101.
14. Yang, B.: Carbon 171 (2021) 455.

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.
2. Silva, A.A.: MRS Adv. 2 (2017) 2247.
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.
7. Wang, C.: Composites B 125 (2017) 181.
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.
15. Wang, L.: Mater. Chem. Phys. 207 (2018) 58.
16. Beigmoradi, R.: Beilstein J. Nanotechnol. 9 (2018) 415.
17. Kumar, U.: J. Power Sources 394 (2018) 140.
18. Shi, X.: Electrochim. Acta 278 (2018) 61.
19. Yang, X.: Inorg. Chem. Front. 5 (2018) 1432.
20.Ma, Q.: Chemistry-A Europ. J. 24 (2018) 6886.
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.
24. Guo, L.: Inter. J. Refractory Metals & Hard Mater. 79 (2019) 47.
25. Pehlivan, Z.S.: Composite Struct. 208 (2019) 418.
26. Lu, C.: Chemistryopen 8 (2019) 87.
27. Li, M.: J. Non-Crystall. Solids 503 (2019) 252.
28. Lv, Z.: RSC Adv. 9 (2019) 10578.
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.
35. Duan, Q.: Applied Surface Sci 486 (2019) 144.
36. Guan J.: Mater. Res. Express 6 (2019) 085633.
37. Naidek, N.: New J. Chem. 43 (2019) 10482.
38. Zheng, Y.: J. Phys. Chem. Solids 130 (2019) 111.
Zeng, Y.: Functional Mater. 26 (2019) 816.
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.
48. Steffen, T.T.: Applied Surface Sci 491 (2019) 405.
# 49. Li, C.: Guocheng Gongcheng Xuebao/Chinese J. Process Engn. 19 (2019) 809.
#       50. Li, X.: Gongneng Cailiao/J. Function. Mater. 50 (2019) 6128.
51. Sarac, Elcin C.: J. Applied Polymer Sci 136 (2019) 48347.
52. Zhou, S.: J. Alloys Comp. 817 (2020) 152737.
53. Chang, C.-W.: Chemical Engn. J. 383 (2020) 123116.
54. Wang, S.: J. Coat. Technol. Res. 17 (2020) 91.
55. Wang, A.-Y.: Sci Total Environ. 698 (2020) 134238.
56. Dong, H.: Energy & Fuels 34 (2020) 1453.
57. Fang, S.: CRYSTENGCOMM 22 (2020) 602.
58. Wang, Y.: Nanomater.‏ 10 (2020) 178.
59. Vozniakovskii, A.: J.Colloid Interface Sci 565 (2020) ‏ 305.
60. Zheng, Y.: J. Mater. Res. 35 (2020) SI462.
61. Zhou, J.: Bioinspired Biomim. Nanobiomater.‏ 9 (2020) 33.
62. Tasleem, S.: J. Alloys Comp. 842 (2020) 155752.
63. Gao, W.: Nanotechnol. 31 (2020) 475601.
64. Dong, H.: Fuel 280 (2020) 118514.
65. Yin, X.: Fuel 280 (2020) 118601.
66. Li, X.: J. Hazardous Mater. 398 (2020) 122938.
67. Zhang, Z.: Carbon 166 (2020) 436.
68. Wang, J.: Surface Coat. Technol. 398 (2020) 126103.
69. Kim, K.H.: Mater. Chem. Phys. 252 (2020) 123471.
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.
74. Qi, Z.: Applied Thermal Engn. 177 (2020) 115489.
75. Deng, J.: Bioresource Technol. 310 (2020) 123438.
76. Chen, N.: ACS Nano 14 (2020) 8059.
77. Li, S.: J. Hazardous Mater. 394 (2020) 122541.
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.
83. Zhou, Q.: Applied Organometall. Chem. 34 (2020) e5700.
84. Wang, X.: Nanomater.10 (2020) 838.
85. Wang, J.: Carbon 166 (2020) 71.
86. Dong, H.: ACS Omega 5 (2020) 9078.
87. Mukhiya, T.: ACS Applied Energy Mater. 3 (2020) 3435.
88. Kuchtova, G.: J. Electroanalyt. Chem. 863 (2020) 114036.
89. Chen, X.: Fulleren. Nanotub. Carbon Nanostruct. 28 (2020)‏ 1048.
90. Sedov, V.: Carbon 174 (2021) 52.
91. Kim, J.H.: Applied Surface Sci 542 (2021) 148637.
92. Noor, S.: New J. Chem. 45 (2021) 2431.
93. Kumar, U.: Energy Fuels ‏ 35 (2021) SI1820.
94. Meng, X.: ACS Omega 6 (2021) 1612.
95. Mohan, L.: J. Mater Sci-Mater. Electr. 32 (2021) 4437.
96. Wu, Z.: J. Bionic Engn. 18 (2021) 40.
97. Ribeiro, B.: J. Mater Sci-Mater. Electr. 32 (2021) 1962.
98. Yang, N.: Carbon 171 (2021) 88.
99. Zhou, S.: J. Cleaner Prod.‏ 278 (2021) 123438.

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)

1. Raymakers, J.: J. Mater. Chem. C 7 (2019) 10134.
2. Lounasvuori, M.M.: Topics in Applied Phys. 121 (2019) 257.
3. Wong, A.: Talanta 206 (2020) 120252.
4. Zhang, J.: Electrochim. Acta 354 (2020) 136649.
5. Kausar, A.: Adv. Mater. Sci 20 (2020) 5.
6. Salehi, E.: Rev.Chem. Engn. 36 (2020) 723.
7. Wang, M.: Nanoscale 12 (2020) 24107.
8. Shi, X.: Diamond Related Mater. 109 (2020) 108092.

Ondič, L., Varga, M., Hruška, K.,  Fait, J., and Kapusta, P.: Enhanced extraction of silicon-vacancy centers light emission using bottom-up engineered polycrystalline diamond photonic crystal slabs, ACS Nano 11 (2017) 2972–2981. (Not IEE SAS)

1. Su, X.: Nanoscale 9 (2017) 17877.
2. Yang, B.: CrystEngComm 20 (2018) 1158.
3. Marseglia, L.: Optics Express 26 (2018) 80.
4. Wu, S.: Adv. Mater. 30 (2018) 1803362.
5. Jaffe, T.: Adv. Optic. Mater. 7 (2019) 1800715.
6. Mei, Y.: Nanoscale 11 (2019) 656.
7. Schmidt, A.: Optic. Mater. Express 9 (2019) 4545.
8. Schmidt, A.: Phys. Status Solidi A 216 (2019) 1900233.
9. Yang, B.: Carbon 156 (2020) 242.
10. Wu, Y.: J. Mater. Sci 55 (2020) 11095.
11. Ahiboz, D.: OSA Continuum 3 (2020) 971.
12. Wuerth, C.: Nano Lett. 20 (2020) 6682.
13. Yang, B.: Carbon 171 (2021) 455.

Cajzl, J., Nekvindová, P., Macková, A., Malinský, P., Sedmidubský, D., Hušák, M., Remeš, Z., Varga, M., Kromka, A., Böttgerf, R., and Oswald, J.: Erbium ion implantation into diamond – measurement and modelling of the crystal structure, Phys. Chem. Chem. Phys. 19 (2017) 6233-6245. (Not IEE SAS)

1. Vanpoucke, D.E.P.: Diamond Related Mater. 79 (2017) 60.
2. Vanpoucke, D.E.P.: Diamond Related Mater. 94 (2019) 233.
3. Tan, X.: Optic. Mater. Express 10 (2020) 1286
4. Paz, C.V.: Applied Surface Sci 508 (2020) 145114.

Ondič, L., Varga, M., Pelant, I., Valenta, J., Kromka, A., and Elliman, R.G.: Silicon nanocrystal-based photonic crystal slabs with broadband and efficient directional light emission, Sci Reports 7 (2017) 5763. (Not IEE SAS)

1. Wang, J.: Sensors 17 (2017) 2396.
2. Chen, X.: Materials 11 (2018) 2017.
3. Dyakov, S.A.: Sci Reports 8 (2018) 4911.
4. Ummer, K.V.: Applied Physics B 124 (2018) 136.
5. Jakob, M.: Nanoscale Research Lett. 13 (2018) 383.
6. Yu, S.: Proc. SPIE 10687 (2018) 106871I.
7. Castillo-Gallardo, V.: J. Optical Soc America B 36 (2019) 829.
8. Castillo-Gallardo, V.: Springer Proc. Phys. 233 (2019) 37.
9. Lo Faro, M.J.: Sci Reports 10 (2020) 12854.
10. Avramenko, T.V.: J. Nanoparticle Research 22 (2020) 110.
11. Wang, F.: Adv. Optical Mater. 8 (2020) 1901236.

Stehlik, S., Varga, M., Ledinsky, M., Miliaieva, D., Kozak, H., Skakalova, V., Mangler, C., Pennycook, T.J., Meyer, J.C., Kromka, A., and Rezek, B.: High-yield fabrication and properties of 1.4 nm nanodiamonds with narrow size distribution, Sci Reports 6 (2016) 38419. (Not IEE SAS)

1. Škarohlíd, J.: Sci Reports 7 (2017) 6469.
2. Shakhov, F.M.: J. Solid State Chem. 256 (2017) 72.
3. Trofimuk, A.D.: Materials 11 (2018) 1285.
4. Chipaux, M.: Small 14 (2018) 1704263.
5. Kamneva, N.N.: Surface Engn. Applied Electrochem. 54 (2018) 64.
6. Koniakhin, S.V.: Superlatt. Microst. 113 (2018) 204.
7. Iqbal, S.: J. Phys. Chem. Solids 122 (2018) 72.
8. Utesov, O.I.: J. Phys. Chem. C 122 (2018) 22738.
9. Koniakhin, S.V.: J. Phys. Chem. C 122 (2018) 19219.
10. Mermoux, M.: Diamond Related Mater. 87 (2018) 248.
11. Muravijova, D.V.: Semiconductors 52 (2018) 2065.
12. Matsumoto, K.: Sci Reports 8 (2018) 5807.
13. Siampour, H.: Light 7 (2018) 61.
14. Sangiao, E.T.: Materials 12 (2019) 1639.
15. Osipov, V.Y.U.: J. Optical Technol. 86 (2019) 1.
16. Mchedlov-Petrossyan, N.O.: J. Molecular Liquids 283 (2019) 849.
17. Basso, L.: Carbon 153 (2019) 148.
18. Gao, Y.: Diamond Related Mater. 99 (2019) 107524
19. Claveau, S.: Nanomater. 10 (2020) 553.
20. Kume, A.: Diamond Related Mater. 103 (2020) 107705.
21. Kovářík, T.: J. Nanopart. Research 22 (2020) 34.
22. Korepanov, V.I.: J. Raman Spectroscopy 51(2020) 881.
23. López-Carballeira, D.: Diamond Related Mater. 108 (2020) 107959.
24. Hayashi, T.: ACS Applied Nano Mater. 3 (2020) 6884.
25. Kornienko, N.E.: Phys. Chem. Solid State 21 (2020) 598.
26. Koniakhin, S.: Phys. Rev. Res. 2 (2020) 013316.
27. Koniakhin, S.V.: Phys. Rev. B 102 (2020) 205422.
28. Utesov, O.I.: Phys. Rev. B 102 (2020) 205421.
29. Kryshtal, A.P.: Colloids Surf. A-Physicochem. Engn. Aspects 614 (2021) 126079.

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.

Remes, Z., Babchenko, O., Varga, M., Stuchlík, J., Jirásek, V., Prajzler, V., Nekvindova, P., and 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.
2. Shen, L.: Mater. Sci Technol. 34 (2018) 419.
3. Fan, H.: Mater. Res. Express 6 (2019) 115090.
4. Wang, J.-L.: Chinese Phys. B 29 (2020) 018103.
5. Smirnov, Y.: APL Mater. 8 (2020) 061108.
6. Fan, H.: Mater. Trans.‏ 61 (2020) 795.

Salava, J., Trojánek, F., Stehlík, Š., Varga, M., Rezek, B., and Malý, P.: Influence of air annealing on the luminescence dynamics of HPHT nanodiamonds, Diamond Related Mater. 68 (2016) 62-65. (Not IEE SAS)

1. Iqbal, S.: J. Phys. Chem. Solids 122 (2018) 72.
2. Iqbal, S.: Mater. Sci Semicond. Process. 74 (2018) 31.

Stehlik, S., Miliaieva, D., Varga, M., Kromka, A., and Rezek, B.: Size decrease of detonation nanodiamonds by air annealing investigated by AFM, MRS Adv. (Electron. Photon.) 1, Iss. 16 (2016) 1067-1073. (Not IEE SAS)

1. Koniakhin, S.V.: Superlatt. Microstr. 113 (2018) 204.
2. Stelmakh, S.: Diamond Related Mater. 113 (2021) 108286.
3. Stelmakh, S.: Diamond Related Mater. 111 (2021) 108177.

Liskova, J., Babchenko, O., Varga, M., Kromka, A., Hadraba, D., Svindrych, Z., and 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.
8. Svindrych, Z.: In Deep Imaging in Tissue and Biomedical Materials: Using Linear and Nonlinear Optical Methods. Pan Stanford Publ. Pte. Ltd. 2017. ISBN: 978-981474588-8. P. 157-202.
9. Nogués, C.: In Biomaterials in Clinical Practice: Advances in Clinical Research and Medical Devices. Springer 2017. ISBN: 978-331968024-8. P. 461-475.
10. Nistor, P.A.: J. Royal Soc Interface 14 (2017) 0382.
11. Strazic Geljic, I.: J. Tissue Engn. Regenerat. Medicine 12 (2018) e854.
12. Subramanian, B.: Biointerphases 13 (2018) 041002.
13. Zhang, X.-F.: Surface Coat. Technol. 375 (2019) 681.
14. Pandey, P.C.: Nanotechnol.‏ 32 (2021) 132001.

Bacakova, M., Lopot, F., Hadraba, D., Varga, M., Zaloudkova, M., Stranska, D., Suchy, T., and  Bacakova, L.: Effects of fiber density and plasma modification of nanofibrous membranes on the adhesion and growth of HaCaT keratinocytes, J. Biomater. Appl. 29 (2015) 837-853. (Not IEE SAS)

1. Lorden, E.R.: Biomater. 43 (2015) 61.
2. Thakur, S.: Rev. Adhesion Adhesives 3 (2015) 53.
*      3. Meka, S.R.M.: Biomater. Nanotechnol. for Tissue Engn. CRC Press 2016. ISBN: 978-149874373-0. P. 35-74 .
4. Kinikoglu, B.: Dev. Circuits Systems 52 (2016) 147.
5. Dufay, M.: ACS Applied Bio Mater.‏ 3 (2020)
6. Dutta, D.: ACS Applied Bio Mater.‏ 4 (2021) 1852.
7. Tang, H.: Mater. Sci Engn. C‏ 119 (2021) 111470.

Stehlik, S., Varga, M., Ledinsky, M., Jirasek, V., Artemenko, A., Kozak, H., Ondic, L., Skakalova, V., Argentero, G., Pennycook, T., Meyer, J.C., Fejfar, A., Kromka, A., and Rezek, B.: Size and purity control of HPHT nanodiamonds down to 1 nm, J. Phys. Chem. C 119 (2015) 27708–27720. (Not IEE SAS)

1. Kumar, R.: RSC Adv. 6 (2016) 47164.
2. Landeros-Martínez, L.-L.: J. Nanomater. (2016) 2682105.
3. Yavkin, B.V.: Magnet. Resonance in Solids 17 (2015) 15101.
4. Grudinkin, S.A.: Nanotechnol. 27 (2016) 395606.
5. Luo, N.: Fuller. Nanotub. Carbon Nanostr. 24 (2016) 494.
6. Gao, Y.: Sci Rep. 6 (2016) 20539.
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8. Li, H.: Phys. Chem. Chem. Phys. 19 (2017) 28056.
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10. Karami, P.: Polymer Inter. 66 (2017) 557.
11. Plakhotnik, T.: Current Opinion in Solid State Mater. Sci 21 (2017) 25.
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15. Landeros-Martinez, L.-L.: Molecules 22 (2017) 1740.
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18. Laube, C.: Mater. Chem. Frontiers 1 (2017) 2527.
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20. Hong, S.P.: Diamond Related Mater. 81 (2018) 27.
21. Beck, R.A.: J. Phys. Chem. C 122 (2018) 8573.
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Varga, M., Laposa, A., Kulha, P., Kroutil, J., Husak, M., and Kromka, A.: Quartz crystal microbalance gas sensor with nanocrystalline diamond sensitive layer, Phys. Status Solidi B 252 (2015) 2591–2597. (Not IEE SAS)

1. Dultsev, F.N.: Sensors Actuat. B 267 (2018) 70.
2. Kato, F.: Japan. J. Applied Phys. 57 (2018) 07LD14.

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)

1. Ahmed, R.: Applied Phys. Lett. 112 (2018) 181907.
2. Zhang, Z.: Modern Phys. Lett. B 33 (2019) 1950283.

Remes, Z., Sun, S.-J., Varga, M., Chou, H., Hsu, H.-S., Kromka, A., and Horak, P.: Ferromagnetism appears in nitrogen implanted nanocrystalline diamond films, J. Magnetism Magnet. Mater. 394 (2015) 477-480. (Not IEE SAS)

1. Zhang, G.: ACS Nano 11 (2017) 5358.
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3. Barzola-Quiquia, J.: Sci Rep. 9 (2019) 8743.
4. Chen, X.: Carbon 164 (2020) 224.
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Potocký, Š., Ižák, T., Varga, M., and Kromka, A.: Influence of gas chemistry on Si-V color centers in diamond films, Phys. Status Solidi B 252 (2015) 2580-2584. (Not IEE SAS)

1. Prieske, M.: Diamond Related Mater. 65 (2016) 47.
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Varga, M., Laposa, A., Kulha, P., Davydova, M., Kroutil, J., Husak, M., and Kromka, A.: Fabrication of diamond based quartz crystal microbalance gas sensor, Key Engn. Mater. 605 (2014) 589-592. (Not IEE SAS)

1. Feng, P.: Applied Phys. Lett. 107 (2015) 233103.

Varga, M., Vretenar, V., Kotlar, M., Skakalova, V., and Kromka, A.: Fabrication of free-standing pure carbon-based composite material with the combination of sp2–sp3 hybridizations, Applied Surface Sci 308 (2014) 211-215. (Not IEE SAS)

1. Amafabia, D.-A.M.: SDHM Struct. Durability Health Monitor. 11 (2017) 91.
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3. Xia, Q.: Composites Part B‏ 199 (2020) 108231.

Galář, P., Dzurňák, B., Varga, M., Marton, M., Kromka, A., and Malý, P.: Influence of non-diamond carbon phase on recombination mechanisms of photoexcited charge carriers in microcrystalline and nanocrystalline diamond studied by time resolved photoluminescence spectroscopy, Optical Mater. Express 4 (2014) 624-637. (Not IEE SAS)

1. Sobaszek, M.: Optical Mater. 42 (2015) 24.
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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.

Prajzler, V., Nekvindová, P., Varga, M., Kromka, A., and Remeš, Z.: Design of 1×2 wavelength demultiplexer based on multimode interference, J. Optoelectron. Adv. Mater. 16 (2014) 1226-1231. (Not IEE SAS)

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Varga, M., Potocky, S., Tesarek, P., Babchenko, O., Davydova, M., and Kromka, A.: Diamond growth on copper rods from polymer composite nanofibres, Applied Surface Sci 312 (2014) 220-225. (Not IEE SAS)

1. Inzoli, F.: Diamond Related Mater. 80 (2017) 69.
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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.
2. Marton, M.: J. Micromech. Microengn. 29 (2019) 124004.

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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Remeš, Z., Pham, T.T., Varga, M., Kromka, A., Stuchlik, J., and Mao, H.B.: The optical spectra of carbon-based thin films measured by the photothermal deflection spectroscopy (PDS). In NANOCON 2013, p. 405-409. (Not IEE SAS)

1. Gallego, M.: Veterin. Record Open 6 (2019) e000251.

Prajzler, V., Varga, M., Nekvindová, P., Remeš, Z., and Kromka, A.: Design and investigation of properties of nanocrystalline diamond optical planar waveguides, Optics Express 21 (2013) 8417-8425. (Not IEE SAS)

1. Kraszewski, M.: Photon. Lett. Poland 5 (2013) 140.
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Ondič, L., Varga, M., Hruška, K., Kromka, A., Herynková, K., Hönerlage, B., and Pelant, I.: Two-dimensional photonic crystal slab with embedded silicon nanocrystals: Efficient photoluminescence extraction, Appl. Phys. Lett. 102 (2013) 251111. (Not IEE SAS)

1. Jannesari, R.: Optics Express 22 (2014) 25426.
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Kozák, M., Trojánek, F., Galář, P., Varga, M., Kromka, A., and Malý, P.: Coherent phonon dynamics in micro- and nanocrystalline diamond, Optics Express 21 (2013) 31521-31529. (Not IEE SAS)

1. Marton, M.: Applied Surface Sci 312 (2014) 139.
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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)

1. Radhika, P.: Applied Surface Sci 540 (2021) 148402.
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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)

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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)

1. Buijnsters, J.G.: J. Phys. Chem. C 117 (2013) 23322.
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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)

1. Holz, T.: ACS Applied Mater. Interfac. 6 (2014) 22649.
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Varga, M., Vojs, M., Marton, M., Michalíková, L., Veselý, M., Redhammer, R., and Michalka, M.: Diamond thin film nucleation on silicon by ultrasonication in various mixtures, Vacuum 86 (2012) 681-683. (Not IEE SAS)

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Marton, M., Kovalčík, D., Vojs, M., Zdravecká, E., Varga, M., Michalíková, L., Veselý, M., Redhammer, R., and Písečný, P.: Electrochemical corrosion behavior of amorphous carbon nitride thin films, Vacuum 86 (2012) 696-698. (Not IEE SAS)

1. Mikmeková, E.: Applied Surface Sci 275 (2013) 7.
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Ondic, L., Babchenko, O., Varga, M., Kromka, A., Ctyroky, J., and 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.
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Varga, M., Remes, Z., Babchenko, O., and 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).

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Ižák, T., Marton, M., Vojs, M., Redhammer, R., Varga, M., and Veselý, M.: A Raman spectroscopy study on differently deposited DLC layers in pulse arc system, Chem. Papers 64 (2010) 46-50. (Not IEE SAS)

1. Dreiling, I.: Surface Coat. Technol. 205 (2010) 1339.

Ižák, T., Marton, M., Varga, M., Vojs, M., Veselý, M., Redhammer, R., and Michalka, M.: Bias enhanced nucleation of diamond thin films in a modified HFCVD reactor, Vacuum 84 (2009) 49-52. (Not IEE SAS)

1. Staryga, E.: Vacuum 85 (2010) 518.
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Marton, M., Zdravecká, E., Vojs, M., Ižák, T., Veselý, M., Redhammer, R., Varga, M., and Šatka, A.: Study of adhesion of carbon nitride thin films on medical alloy substrates, Vacuum 84 (2009) 65-67. (Not IEE SAS)

1. Izman, S.: Proc. IEEE/CPMT (IEMT) Symp. 2010, no. 5746719.
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