Ceramics”, International Journal of Materials and Chemistry, Vol. 3(3): 51- 58.
[58]. Nguyen Dinh Tung Luan, Le Dai Vuong (2014), “Study Structure, Microstructure and Temperature Dependence of Some Physical Properties of ZnO Doped PZT–PMSN Ceramics”, International Journal of Engineering and Innovative Technology, Vol 3 (8), pp: 48-52.
[59]. Nguyen Dinh Tung Luan, Le Dai Vuong, Truong Van Chuong, and Nguyen Truong Tho (2014), “Structure and Physical Properties of PZT–PMnN–PSN Ceramics Near The morphological Phase Boundary”, Advances in Materials Science and Engineering, Volume 2014, Article ID 821404, 8 pages.
[60]. Mao J. B., Zhou J., Zheng H. Q., Sun H. J., Chen W. (2010), “Effects of Fe2O3 Doping on the Properties of PMnS-PZN-PZT Piezoelectric Ceramic”, Journal of synthetic crystals, Vo1. 39 No. 1, pp: 72-76.
[61]. Miclea C., Tanasoiu C., Miclea C.F., Amarande L., Gheorghiu A., Sima
F.N. (2005), “Effect of iron and nickel substitution on the piezoelectric properties of PZT type ceramics”, J. Eur. Ceram. Soc. 25, pp: 2397 – 2400.
[62]. Miclea C., Tanasoiu C., Miclea C.F., Amarande L., Gheorghiu A., Spanulescu I., C. Plavitu, Miclea C.T., Cioangher M.C., Trupina L., Iuga A. (2007), “Effect of lead content on the structure and piezoelectric properties of hard type lead titanate–zirconate ceramics”, Journal of the European Ceramic Society 27, pp: 4055–4059.
[63]. Molak A., Talik E., Kruczek M., Paluch M., Ratuszna A., Ujma Z. (2006), “Characterisation of Pb(Mn1/3Nb2/3)O3 ceramics by SEM, XRD, XPS and dielectric permittivity tests”, Materials Science and Engineering B 128, pp:16–24.
[64]. Muanghlua R., Niemchareon S., Vittayakorn W. C. and Vittayakorn N. (2008), “Effects of Zr/Ti Ratio on the Structure and Ferroelectric Properties
Có thể bạn quan tâm!
-
Ảnh Hiển Vi Điện Tử Quét Của Các Mẫu Thuộc Nhóm Mẫu Mc -
So Sánh Các Tính Chất Của Gốm Đã Chế Tạo Với Gốm Của Các Công Trình Khác Có Cùng Loại Tạp Cuo -
Nghiên cứu chế tạo và các tính chất vật lý của hệ gốm đa thành phần trên cơ sở PZT và các vật liệu sắt điện chuyển pha nhòe - 18
Xem toàn bộ 161 trang tài liệu này.
in PZT-PZN-PMnN Ceramics Near the Morphotropic Phase Boundary”,
Advanced Materials Research Vols. 55-57, pp. 125-128.
[65]. Nam C. H., Park H. Y., Seo I. T., Choi J. H., Nahm S., Lee H. G. (2011),
“Effect of CuO on the sintering temperature and piezoelectric properties of MnO2-doped 0.75Pb(Zr0.47Ti0.53)O3 – 0.25Pb(Zn1/3Nb2/3)O3 ceramics”, Journal of Alloys and Compounds, Vol. 509, pp: 3686–3689.
[66]. Nam C., Park H. Y, Seo I. T, Choi J. H, Joung M. R, and Nahm S. (2011), “Low-Temperature Sintering and Piezoelectric Properties of 0.65Pb(Zr0.42Ti0.58)O3 - 0.35Pb(Ni0.33Nb0.67)O3 Ceramics”, J. Am. Ceram. Soc.
94 (10), pp: 3442–3448.
[67]. Necira Z., Boutarfaia A., Abba M., Menasra H., Abdessalem N. (2013), “Effects of Thermal Conditions in the Phase Formation of Undoped and Doped Pb(Zr1−xTix)O3 Solid Solutions”, Materials Sciences and Applications, Vol. 4, pp: 319-323.
[68]. Pirc R. and Blinc R. (2007), “Vogel-fulcher freezing in relaxor ferroelectrics”, Physical review b 76, pp: 020101:1-3.
[69]. Samara G. A. and. Venturini E. L. (2006), “Ferroelectric relaxor crossover in ompositionally disordered perovskites”, Phase Transitions, Vol. 79, pp. 21–40.
[70]. Sawaguchi E. (1953). “Ferroelectricity versus antiferroelectricity in the solid solution of PbZrO3 and PbTiO3”, J. Phys. Soc. Jpn., 8(5): 615.
[71]. Shi L., Zhang B., Liao Q., Zhu L., Zhao L., Zhang D., Guo D. (2014), “Piezoelectric properties of Fe2O3 doped BiYbO3 -Pb(Zr,Ti)O3 high Curie temperature ceramics”, Ceramics International 40, pp: 2763 – 2769.
[72]. Smolenskii, G. A. and A. I. Agranovskaya (1959), “Dielectric polarization of a number of complex compounds”, Sov. Phys. Solid State 1, 1429-1437.
[73]. Uchino K. (1991), Relaxor ferroelectrics, Journal of the ceramic society of Japan, 99 (10), pp. 829-835.
[74]. Vittayakorn N, Rujijanagul G, and Tunkasiri T. (2003), “Perovskite phase formation and ferroelectric properties of the lead nickel niobate–lead zinc niobate–lead zirconate titanate ternary system”, J. Mater. Res., Vol. 18, No. 12, pp: 2882- 2889.
[75]. Le Dai Vuong, Phan Dinh Gio (2013), “Effect of Li2CO3 addition on the sintering behavior and physical properties of PZT-PZN-PMnN ceramics”, International Journal of Materials Science and Applications, Vol. 2(3): 89- 93.
[76]. Wang J., Wang G., Nie H., Chen X., Cao F., Dong X., Gu Y., and He H. (2013), “Low-Temperature Sintering and Electric Properties of Pb0.99(Zr0.95Ti0.05)0.98Nb0.02O3 Ferroelectric Ceramics with CuO Additive”, J. Am. Ceram. Soc., pp: 1–4.
[77]. Wang L., Mao C., Wang G., Du G., Liang R., and Dong X. (2013), “Effect of CuO Addition on the Microstructure and Electric Properties of Low- Temperature Sintered 0.25PMN – 0.40PT – 0.35PZ Ceramics”, J. Am. Ceram. Soc., Vol. 96(1), pp: 24–27.
[78]. Wintotai P., Udomkan N., Meejoo S. (2005), “Piezoelectric properties of Fe2O3 -doped (1 - x) BiScO3 – xPbTiO3 ceramics”, Sensors and Actuators A 122 (2) 257–263.
[79]. Wu N.N., Song X.M., Hou Y. D., Zhu M.K., Wang C. & Yan H. (2009),
“Relaxor behavior of (1−x)Pb(Mg1/3Nb2/3)O3-xPbTiO3 ceramics”, Chinese Science Bulletin, vol. 54 (7), pp: 1267-1274.
[80]. Wu Tao, Sun Q., Ma W, Liu Z. (2013), “Effect of CuO on the sintering temperature and properties of SrCO3 and MnO2 - doped PMS-PZT piezoelectric ceramics for multilayer piezoelectric transformers”, J Electroceram, Vol 31, pp: 28-34.
[81]. Xu Y. (1991) Ferroelectric materials and their applications, Elsevier Science Publisher, North – Holland, Tokyo-Paris-New York.
[82]. Yan Y., Cho K-H., Maurya D., Kumar A., Kalinin S., Khachaturyan A., and Priya S. (2013), “Giant energy density in [001]-textured Pb(Mg1/3Nb2/3)O3- PbZrO3-PbTiO3”, Applied physics letters 102, 042903.
[83]. Yan Y., Xu Y., Feng Y. (2014), “Effect of Mn doping on the piezoelectric properties of 0.82Pb(Zr1/2Ti1/2)O3 – 0.03Pb(Mn1/3Sb2/3)O3 – 0.15Pb(Zn1/3Nb2/3)O3 ferroelectric ceramics”, Ceramics International 40, pp: 5897 – 5903.
[84]. Yoo J, Lee I., Lee S, Kim K., Yoon H., and Lee S. (2007), “Piezoelectric and dielectric properties of low temperature sintering PMN-PZN-PZT ceramics according to the amount of PbO”, Integrated Ferroelectrics, Vol. 93, pp: 62– 71.
[85]. Yoo J. and Lee S. (2009), “Piezoelectric and Dielectric Properties of Low Temperature Sintered Pb(Mn1/3Nb2/3)0.02(Ni1/3Nb2/3)0.12(ZrxTi1-x)0.86O3 System Ceramics”, Transactions on Electrical and Electronic Materials, Vol. 10, No. 4, pp:121-124.
[86]. Yoo J., Kim D., Song H., Paik D. S. and Kang D. H. (2008), “Effect of Calcination Temperature on the Piezoelectric Characteristics of Pb(Mn1/3Nb2/3)O3-Pb(Ni1/3Nb2/3)O3 – Pb(Zr0.50Ti0.50)O3 Ceramics”, Integrated Ferroelectrics, Vol. 96, pp: 11–18.
[87]. Yoo J., Lee I, & Paik D. S. & Park Y.-W. (2009), “Piezoelectric and dielectric properties of low temperature sintering Pb(Mn1/3Nb2/3)O3 – Pb(Zn1/3Nb2/3)O3 – Pb(Zr0.48Ti0.52)O3 ceramics with variation of sintering time”, J Electroceram 23, pp: 519 – 523.
[88]. Yoo S-Y, Ha J-Y, Yoon S-J., Choi J-W. (2013), “High-power properties of piezoelectric hard materials sintered at low temperature for multilayer ceramic actuators”, Journal of the European Ceramic Society 33, pp: 1769– 1778.
[89]. Yoon S-J., Choi J-W. and Choi J-Y. (2010), “Influences of Donor Dopants on the Properties of PZT-PMS-PZN Piezoelectric Ceramics Sintered at Low Temperatures”, Journal of the Korean Physical Society, Vol. 57 (4), pp. 863- 867.
[90]. Zeng X., Ding A., Liu T., Deng G., Zheng X., and Cheng W., (2006), “Excess ZnO Addition in Pure and La-Doped PZN–PZT Ceramics”, J. Am. Ceram. Soc., Vol 89 (2), pp. 728–730.
[91]. Zhu M. K., Lu P. X., Hou Y. D., Song X. M., Wang H, and Yan H. (2006),
“Analysis of Phase Coexistence in Fe2O3 - Doped 0.2PZN–0.8PZT Ferroelectric Ceramics by Raman Scattering Spectra”, J. Am. Ceram. Soc., Vol. 89 (12), pp: 3739–3744.
[92]. Zhu M. K., Lu P. X., Hou Y. D., Wang H, and Yan H. (2005), “Effects of Fe2O3 addition on microstructure and piezoelectric properties of 0.2PZN– 0.8PZT ceramics”, J. Mater. Res., Vol. 20, No. 10, pp: 2670 - 2675.
[93]. Zheng M.,Hou Y., Ge H., Zhu M. and Yan H. (2013), “Effect of sintering temperature on internal-bias field and electric properties of 0.2PZN–0.8PZT ceramics”, Phys. Status Solidi A 210, No. 2, 261–266.