References

Journal of Materials Science and Engineering with Advanced Technology

PERFORMANCE OF EU-DOPED OXIDE FILMS FOR ADVANCED MATERIALS ENGINEERING AND ENERGY CONVERSION: ARGUMENTS FOR THE LATTICE COMPATIBILITY THEORY (LCT)

[1] A. Duk, J. Schwarzkopf, A. Kwasniewski, M. Schmidbauer and R. Fornari, Materials Research Bulletin 47(8) (2012), 2056-2061.

[2] J. Zhang Zhou, Y. Liu and G. Wang, Materials Research Bulletin 47(4) (2012), 1104-1106.

[3] N. F. Mott, Nobel Prize Lecture, 1977.

[4] W. W. Li, J. J. Zhu, J. D. Wu, J. Sun, M. Zhu, Z. G. Hu and J. H. Chu, ACS Appl. Mater. Interfaces 2 (2010), 2325-2332.

[5] H. Kimura, T. Fukumura, M. Kawasaki, K. Inaba, T. Hasegawa and H. Koinuma, Appl. Phys. Lett. 80 (2002), 94-96.

[6] S. J. Liu, C. Y. Liu, J. Y. Juang and H. W. Fang, J. Appl. Phys. 105 (2009), 013928.

[7] R. K. Verma, G. Kaur, A. Rai and S. B. Rai, Materials Research Bulletin 47 (2012), 3726-3731.

[8] W. Huang, C. Lu, C. Jiang, J. Jin, M. Ding, Y. Ni and Z. Xu, Materials Research Bulletin 47 (2012), 3726-3731.

[9] X. Qiao, X. Fan, Y. Pan, A. Lotnyk and L. Kienle, Materials Research Bulletin 47 (2012), 29-34.

[10] B. Liu, C. W. Cheng, R. Chen, Z. X. Shen, H. J. Fan and H. D. Sun, J. Phys. Chem. C 114 (2010), 3407-3410.

[11] H. Tran, T. Mehta, M. Zeller and R. H. Jarman, Materials Research Bulletin 48 (2013), 2450-2456.

[12] P. A. Lessing, Ceramic Bulletin 68 (1989), 1002-1006.

[13] E. Niwa, C. Uematsu and T. Hashimoto, Materials Research Bulletin 48 (2013), 1-6.

[14] R. H. Jarman, J. Bafia, T. Gebreslasse, B. J. Ingram and J. D. Carter, Materials Research Bulletin 48 (2013), 3916-3918.

[15] Y. Hasegawa, M. Yamamuro, Y. Wada, N. Kanehisa, Y. Kai and S. Yanagida, J. Phys. Chem. A 107 (2003), 1697-1702.

[16] P. Marwoto, S Sugianto and E Wibowo, J. of Theoret. and Applied Physics 6 (2012), 17-22.

[17] C. D. Hodgman, Handbook of Chemistry and Physics 35th Ed., Vol. 2, (Chemical Rubber Publishing Co., 1953), 2737.

[18] P. Petkova and K. Boubaker, J. of Alloys and Compounds 546(5) (2013), 1769-1777.

[19] K. Boubaker, ISRN Nanomaterials 2012 (2012), 4-8.

[20] K. Boubaker, J. of Ceramics 2013 (2013), 6-9.

[21] Q. Jiao, J. Qiu, D. Zhou and X. Xu, Materials Research Bulletin 51 (2014), 315-319.

[22] H. L. Soo and S. Y. Jae, Materials Research Bulletin 50 (2014), 354-358.

[23] S. B. Alaparthi, L. Lu, Y. Tian and Y. Mao, Research Bulletin 49 (2014), 114-118.

[24] G. Zhu, Z. Ci, C. Ma, Y. Shi, Y. Wang and Mao, Materials Research Bulletin 48 (2013), 1995-1998.

[25] K. Chakraborty, A. Bisoi, B. N. Ganguly, V. Grover, F. N. Sayed and A. K. Tyagi, Materials Research Bulletin 47 (2012), 3660-3664.

[26] T. Thomas, X. Guo, M. Chandrashekhar, C. B. Poitras, W. Shaff, M. Dreibelbis, J. Reiherzer, K. Li, Francis J. DiSalvo, M. Lipson and M. G. Spencer, Journal of Crystal Growth 311 (2009), 4402-4407.

[27] C. Louis, K. Lebbou, M. A. Flores-Gonzalez, R. Bazzi, B. Hautefeuille, B. Mercier, S. Roux, P. Perriat, C. Olagnon and O. Tillement, Journal of Crystal Growth 265 (2004), 459-465.

[28] X. Li, Z. Yang, L. Guan, C. Liu and P. Li, Journal of Crystal Growth 310 (2008), 3117-3120.

[29] F. Khlissa, M. Férid, M. C. Pujol, X. Mateos, J. J. Carvajal, F. Díaz and M. Aguiló, Journal of Crystal Growth 311 (2009), 4360-4364.

[30] J. Mrázek, M. Surýnek, S. Bakardjieva, J. Buršík and I. Kašík, Journal of Crystal Growth 391 (2014), 25-32.

[31] Y. Masubuchi, T. Hata, T. Motohashi and S. Kikkawa, Journal of Solid State Chemistry 184 (2011), 2533-2537.

[32] W. Y. Hernández, O. H. Laguna, M. A. Centeno and J. A. Odriozola, Journal of Solid State Chemistry 184 (2011), 3014-3020.

[33] D. Lee, J. Seo, L. de los Santos Valladares, O. Avalos Quispe and C. H. W. Barnes, Journal of Solid State Chemistry 228 (2015), 141-145.

[34] F. S. Freyria, G. Barrera, P. Tiberto, E. Belluso, D. Levy, G. Saracco, P. Allia, E. Garrone and B. Bonelli, Journal of Solid State Chemistry 201 (2013), 302-311.