References
- [1] THE HOLY BIBLE, Genesis 13:12.
- [2] SLUIJTER, W.L. - KREIJGER, P.C.: Potentio dynamic polarization curves and steel corrosion. Heron, Vol. 22 (1977), No. 1, pp. 13-27.
- [3] ACI 222R-01 Protection of metals in concrete against corrosion. ACI Committee 222, 2001, 41 pp.
- [4] STN 73 1341 Corrosion protection of reinforcements provided by the properties of concrete. Methods of test. SÚTN Bratislava, 1987, 20 pp.
- [5] KINNUNEN, P.: Electrochemical characterisation and modelling of passive films on Ni- and Febased alloys. VTT Publications 472, Helsinki, 2002, 72 pp.
- [6] HINDS, G.: The electrochemistry of corrosion. Edited by Gareth Hinds from the original work of J G N Thomas. National Physical Laboratory, Teddington, 2010, 25 pp.
- [7] SAZOU, D. - PAVLIDOU, M. - DIAMANTOPOULOU, A. - PAGITSAS, M.: Oscillatory phenomena as a probe to study pitting corrosion of iron in halide-containing sulfuric acid solutions. Pitting corrosion. Chapter 4. InTech, 2012, 178 pp., ISBN 978-953-51-0275-5.
- [8] KRAJČI, Ľ.: Diagnostic of reinforcement condition of reinforced concrete structures by electrical methods and the assessment of their reliability. Doctoral thesis, Slovak Academy of Sciences, Bratislava, 1999.
- [9] NOSEK, V.: Electrochemical corrosion. Lecture No. 2. Technical University Liberec, Faculty of Mechanical Engineering, Department of Materials. Liberec, 2012, 39 pp.
- [10] DAO, L.T.N. - DAO, V.T.N. - KIM, S-H. - ANN, K.Y.: Modeling steel corrosion in concrete structures - Part 1: A new inverse relation between current density and potential for the cathodic reaction. International Journal of Electrochemical Science, Vol. 5 (2010), pp. 302-313.
- [11] KIM, CH-Y - KIM, J-K.: Numerical analysis of localized steel corrosion in concrete. Construction and Building Materials, Vol. 22 (2008), pp. 1129-1136.
- [12] KEAR, G. - WALSH, F.C.: The characteristics of a true Tafel slope. Corrosion & Materials, Vol. 30 (2005), No. 6, pp. 1-4.
- [13] LORBEER, P. - LORENZ, W.J.: A critical consideration of the Flade potential. Corrosion Science, Vol. 21 (1981), pp. 79-86.
- [14] GERISCHER, H.: Remarks on the electronic structure of the oxide film on passive iron and the consequences for its electrode behaviour. Corrosion Science, Vol. 29 (1989), pp. 191-195.
- [15] CAHAN, B.D. - CHEN, CH.T.: The nature of the passive film on iron: II . AC impedance studies. Journal of the Electrochemical Society, Vol. 129 (1982), No. 3, pp. 474-480.
- [16] VERWEY, E.J.W.: Electrolytic conduction of a solid insulator at high fields. The formation of the anodic oxide film on aluminium. Physica, Vol. 2 (1935), pp. 1059-1063.
- [17] CABRERA, N. - MOTT, N.F.: Theory of the oxidation of metals. Reports on Progress in Physics, Vol. 12 (1949), No. 1, pp. 163-184.
- [18] KIRCHHEIM, R. - HEINE, B. - HOFMANN, S. - HOFSÄSS, H.: Compositional changes of passive films due to different transport rates and preferential dissolution. Corrosion Science, Vol. 31 (1990), pp. 573-578.
- [19] CASTRO, E.B.: Analysis of the impedance response of passive iron. Electrochimica Acta, Vol. 39 (1994), pp. 2117-2123.
- [20] MACDONALD, D.D. - SMEDLEY, S.I.: An electrochemical impedance analysis of passive films on Nickel (111) in phosphate buffer solutions. Electrochimica Acta, Vol. 35 (1990), pp. 1949-1956.
- [21] BEVERSKOG, B. - BOJINOV, M. - ENGLUND, A. - KINNUNEN, P. - LAITINEN, T. - MÄKELÄ, K. - SAARIO, T. - SIRKIÄ, P.: A mixed-conduction model for oxide films on Fe, Cr and Fe-Cr alloys in high-temperature aqueous electrolytes. I. Comparison of the electrochemical behaviour at room temperature and at 200 °C. Corrosion Science, Vol. 44 (2002), No. 9, pp. 1901-1921.
- [22] BOJINOV, M. - FABRICIUS, G. - KINNUNEN, P. - LAITINEN, T. - MÄKELÄ, K. - SAARIO, T. - SUNDHOLM, G.: The mechanism of transpassive dissolution of Ni-Cr alloys in sulphate solutions. Electrochimica Acta, Vol. 45 (2000), pp. 2791-2802.
- [23] BOJINOV, M. - FABRICIUS, G. - KINNUNEN, P. - LAITINEN, T. - MÄKELÄ, K. - SAARIO, T. - SUNDHOLM, G. - YLINIEMI, K.: Transpassive dissolution of Ni-Cr alloys in sulphate solutions - comparison between a model alloy and two industrial alloys. Electrochimica Acta, Vol. 47 (2002), pp. 1697-1712.
- [24] JANOTKA, I. - MOJUMDAR, S.C.: Thermal analysis at the evaluation of concrete damage by high temperatures. Journal of Thermal Analysis and Calorimetry, Vol. 81 (2005), No. 1, pp. 197-203.
- [25] MELCER, J. - LAJČÁKOVÁ, G.: Severe load test of a bridge and its consequences. Proceedings of the International Conference on Reliability of Structures. Ostrava, 2003, pp. 93-96.
- [26] TESAR, A.: The ultimate response of slender bridges subjected to braking forces. Proceedings of the First International Conference on Railway Technology: Research, Development and Maintenance, Las Palmas de Gran Canaria, Spain. Paper 4. Civil-Comp Press, 2012, pp. 1-13.
- [27] JANOTKA, I. - KRAJČI, Ľ.: Effect of polymer on structural characteristics and steel corrosion of cement-poor mortar. Chemical Papers, Vol. 58 (2004), No. 2, pp. 79 - 86.
- [28] JERGA, J. - HALAS, P.: Ingress of chloride into the prestressed concrete structure. Proceedings of the 5th International Conference on Concrete. Prague: ICC; 1990, pp. 400-404.
- [29] KRAJČI, Ľ.: Relation of cement matrix deterioration to steel reinforcement corrosion of mortars in aggressive environment. Building Research Journal, Vol. 54 (2006), No. 3-4, pp. 233-241.
- [30] KRAJČI, Ľ. - JANOTKA, I.: Measurement techniques for rapid assessment of carbonation in concrete. ACI Materials Journal Vol. 97 (2000), pp. 168-171.