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K. Kreislová and V. Křivý

korozi, SVÚOM.Praha, 2010, ISBN 978-80-87444-05-4. 10. K. Kreislová, D. Knotková: Použití patinujících ocelí v architektuře, ISBN 978-80-87444-10-8, SVÚOM.Praha, 2011. 11. X. H. Chen, J. H. Dong, E. H. Han, W. Ke: Effect of Ni on the ion-selectivity of rust layer on low alloy steel. Material Letters 2007, 61, 4050-4053. 12. A. Tahara, T. Shinohara: Infl uence of the alloy element on corrosion morphology of the low alloy steels exposed to the atmospheric environments, Corrosion Science 2005, 47, 2589

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V. Jeníček, L. Diblíková and M. Bláhová

-103. 5. Zhou Y.J. et al. Solid solution alloys of AlCoCrFeNiTix with excellent room-temperature mechanical properties, Applied Physics Letters 2007 , 90, 181904. 6. Wang X.F. et al. Novel microstructure and properties of multicomponent CoCrcuFeNuTix alloys, Intermetallics 2007 , 15, 357-362. 7. Tsai C.W. et al. Effect of temperature on mechanical properties of Al 0.5 CoCrCuFeNi wrought alloy, Journal of Alloys and Compounds 2010 , 490, 160-165. 8. Senkov O.N. et al. Mechanical properties of Nb 25 Mo 25 Ta 25 W 25 and V 20 Nb 20 Mo 20 Ta 20 W

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Prasad U. Syam, V. V. Kondaiah, K. Akhil, V. Vijay Kumar, B. Nagamani, K. Jhansi, Ravikumar Dumpala, B. Venkateswarlu and Sunil B. Ratna

, K.; Pan, F.; Chen, X.; Tang, A.; Pan, H. and Luo, S. Effect of Zn content on electromagnetic interference shielding effectiveness of Mg–Zn alloys, Materials Research Innovations 2014 , 18, S4-193-197. 20. Li, L.; Jiang, W.; Guo, P.; Yu, W.; Wang, F.; Pan, Z. Microstructure Evolution of the Mg-5.8 Zn-0.5 Zr-1.0 Yb Alloy During Homogenization, Materials Research 2017 , 20 (4), 1063-1071. 21. Kevorkov, D.; Pekguleryuz, M.; Experimental study of the Ce–Mg–Zn phase diagram at 350 °C via diffusion couple techniques, Journal of Alloys and Compounds

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M. Kouřil, T. Prošek, M. Dubus, M. Taube, V. Hubert, B. Scheffel, Y. Degres, M. Jouannic and D. Thierry

References 1. Measurement, Effect Assessment and Mitigation of Pollutant Impact on Movable Cultural Assets; Innovative Research for Market Transfer (MEMORI), 7th Framework Programme of the European Commission, Grant Agreement No. 265132, 11/2010-10/2013. 2. Automated corrosion sensors as on-line real time process control tools (CORRLOG), Co-operative Research Project, 6th Framework Programme, Contract No. 018207, 09/2005-02/2008. 3. Protection of cultural heritage by real-time corrosion monitoring

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A. Krausová, J. Macák, P. Sajdl and O. Vénos

Zircaloy-4, Zirconium in the Nuclear Industry: 12th International Symposium, ASTM STP 1354; Pecheur, D.; 2000. 5. Cox, B; et al. Dissolution of zirconium oxide fi lms in 300°C LiOH. J. Nucl. Mater. 1993, 199, 272-284. 6. Experimental and Theoretical Studies of Parameters that Infl uence Corrosion of Zircaloy-4, Zirconium in the Nuclear Industry: 10th International Symposium, ASTM STP 1245; Billot, Ph.; 1994. 7. Saario, T.; Effect of Lithium Hydroxide on stability of Fuel Cladding Oxide Film in Simulated Pressurized Water

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T. Prošek and V. Šefl

-30Ni and Type 304L Stainless Steel in 0.5 N NaCl Solutions. Corrosion 1990 , 46 (10), 843-852. 9. Viera, M., et al., Comparative study of the effect of oxygen and oxygen/ozone mixtures on the electrochemical behaviour of different metals. Journal of Applied Electrochemistry 2001 , 31 (5), 591-598. 10. Ratnayaka, D. D., et al., 11.22 Production of Ozone. In Twort’s Water Supply (6 th Edition), Elsevier. 11. Lee, W., et al., Corrosion problems caused by bromine formation in additive dosed MSF desalination plants. Desalination 1983 , 44 (1

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J. Fojt, L. Joska, L. Cvrček and V. Březina

-6), 489-497. 29. NIST X-ray Photoelectron Spectroscopy Database, Version 4.0; National Institute of Standards and Technology, Gaithersburg: 2008. 30. Liu, C., et al., EIS comparison on corrosion performance of PVD TiN and CrN coated mild steel in 0.5 N NaCl aqueous solution. Corrosion Science 2001, 43 (10), 1953-1961. 31. Liu, E.; Kwek, H. W., Electrochemical performance of diamond-like carbon thin fi lms. Thin Solid Films 2008, 516 (16), 5201-5205. 32. Joska, L.; Fojt, J

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J. Stoulil and D. Dobrev

. Materials and Corrosion 2015, 66 (4), 342-346. 86. Smart, N. R., et al. Galvanic corrosion of copper-cast iron couples ; SKB Technical Report TR-05-06; 2005. 87. Taxén, C. Possible effects of external electrical fields on the corrosion of copper in bentonite ; SKB Technical Report P-11-43; 2011. 88. Wang, W., et al., Electrochemical techniques used in MIC studies. Materials and Corrosion 2006, 57 (10), 800-804. 89. Xie, X. H., et al., EQCM and EIS Study of the Effect of Potential of Zero Charge on Escherichia Coli Biofilm Development

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P. Pokorný, M. Kouřil, M. Martínek and S. Eriksen

-101. Khadzhai, G. The electrical resistance of the tantalum-hydrogen system at low temperatures. International Journal of Hydrogen Energy.   2001 , 26 , 511-513. Pörschke, E.; et al. Hydrogen Desorption from Tantalum with Segregated Oxide Surface Layers. J. Phys. Chem. Solids.   1986 , 47 (10), 1003-1011. Shleifman, D. E.; et al. Thermally stimulated hydrogen desorption from zirconium and tantalum. J. Alloys Compd.   1995 , 223 , 81-86. Krejčík, V.; et al. Povrchová úprava kovů I ; SNTL

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P. Pokorný

materiálu 2002 , 46 (3), 62-67. 10. Leonard, H. Kovy verze 06b (pro 1. ročník). Prezentace Kovy, (accessed Oct 05, 2012). 11. Bojko, M. Alternativní kovové materiály pro výztuže do betonu. Disertační práce, Vysoká škola chemickotechnologická v Praze, 2007. 12. American Galvanizers Association. Hot-Dip Galvanized Rebar vs Epoxy-Coated Rebar. /uploads/publicationPDFs/Galvanized_Rebar_vs_Epoxy_Rebar (accessed Oct 05, 2012). 13. Hot Dip Galvanized Reinforcing Steel