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M. Gwoździk

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A. Smołka, G. Dercz, K. Rodak and B. Łosiewicz

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M. Scendo, N. Radek, J. Konstanty and K. Staszewska

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D. Guney

.B. Song, Y.H. Jeong, Y.J. Lee, J.H. Paik, W.S. Kim, H. Lee, Met. Mater. Int. 16, 109 (2010). [13] F. Yang, W.D. Fei, Z.M. Gao, J.Q. Jiang, Surf. Coat. Tech. 202, 121 (2007). [14] J. Peng, V. Ji, W. Seiler, A. Tomescu, A. Levesque, A. Bouteville, Surf. Coat. Tech. 200, 2738 (2006). [15] B. Girault, P. Villian, E.L. Bourhis, Surf. Coat. Tech. 201, 4372 (2006). [16] H. Okuda, H. Rokkaku, K. Morishita, J.K. Shin, S. Iwamoto, S. Ochiai, M. Sato, K. Osamura, A. Otto, E.J. Harley, A. Malozemoff, Scripta Materialia

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A. Góral, L. Litynska-Dobrzynska, W. Zórawski, K. Berent and J. Wojewoda-Budka

.M. Kusoglu, E. Celik, H. Cetinel, I. Ozdemir, O. Demirkurt, K. Onel, Surf. Coat. Tech. 200 , 1173 (2005). [13] E. Sanchez, E. Bannier, V. Cantavella, M.D. Salvador, E. Klyatskina, J. Morgiel, J. Grzonka, A.R. Boccaccini, J. Therm. Spray Techn. 17 , 329 (2008). [14] I. Levin, D. Brandon, J. Am. Ceram. Soc. 81 , 1995 (1998). [15] J.L. Labar, Ultramicroscopy 103 , 237 (2005). [16] G. Simmons, H. Wang, Single Crystal Elastic Constant and Calculated Aggregate Properties. The M.I.T Press 1971

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R. Skulski, D. Bochenek and P. Wawrzała

References T. R. Shrout, Z. P. Chang, N. Kim, S. Markgraf, Dielectric behavior of single crystals near the (1-x)PbMg 1/3 Nb 2/3 O 3 -xPbTiO 3 morphotropic phase boundary, Ferroelectr. Lett. Sect. 12 , 63 (1990). B. Noheda, D. E. Cox, G. Shirane, J. Gao, Z.-G. Ye, Phase diagram of the ferroelectric relaxor (1-x)PbMg 1/3 Nb 2/3 O 3 -xPbTiO 3 , Phys. Rev. B, 66 , 0541041-0541049 (2002). A. K. Singh, D. Pandey, Evidence for MB and MC phases in the morphotropic phase boundary region

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P. Panek

the 17 th Europ. Photov. Sol. Ener. Conf., Munich, Germany, 1391 – 1395 (2001). [12] S.K. Dhungel, J. Yoo, K. Kim, S. Ghosh, S. Jung, J. Yi, Mater. Science and Engin. (B) 134 , 187-290 (2006). [13] V. Osinniy, A.N. Larsen a, E.H. Dahl, E. Enebakk, A.K. Søiland, R. Tronstad, Y. Safir, Solar Ener. Mater. & Solar Cells, 101 , 123–130 (2012). [14] D.C. Walter, B. Lim, K. Bothe, R. Falster, V. V. Voronkov, J. Schmidt, Solar Ener. Mater. & Solar Cells 131 , 51–57 (2014). [15] O. Schultz, S. W. Glunz, S. Riepe, G. W. Willeke, Prog. in Photov

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T. Maciąg, K. Rzyman and B. Węcki

8 , 503-509 (2000). [7] N. Saunders, P. Miodownik, Calphad, Pergamon Materials Series. Ed. Cahn R.W. 1 , (1998). [8] H.L. Lukas, S.G. Fries, B. Sundman, The Calphad Method. Cambridge University Press. (2007). [9] N. Dupin, I. Ansara, B. Sundman, Calphad 25 , 2, (2001). [10] W. Huang, Y.A. Chang, Intermetallics 7 , 863-874 (1999). [11] V. Raghavan, Journal of Phase Equilibria and Diffusion 27 , 4, 381-388 (2006). [12] A. Taylor, R.W. Floyd, J. Inst. Met. 81 , 451 (1952). [13] P. Broz, M. Svoboda, J. Bursik, A. Kroupa

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G.-Z. Quan, X. Wang, Y.-L. Li and L. Zhang

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Z. Konopka, M. Łągiewka, M. Nadolski and A. Zyska

and Metallurgy. New York, Jon Wiley & Sons Inc., 66 (1996). [13] A. Bochenek, Inicjacjaipodkrytyczny rozwój szczeliny w stalach mikro-stopowychwujeciu metod numerycznych i doswiadczalnych. Czestochowa, Wydaw. Politechniki Czestochowskiej (1990).