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http://dx.doi.org/10.4313/JKEM.2010.23.11.869

Piezoelectric/magnetic Properties and Magnetoelectric Effects in (1-x) [0.5PZT-0.25PNN-0.25PZN] - x [Ni0.9Zn0.1Fe2O4] Particulate Ceramic Composites  

Park, Young-Kwon (Department of Electronic Engineering, Pukyong National university)
Son, Se-Mo (Department of Graphic Arts Engineering, Pukyong National university)
Ryu, Ji-Goo (Department of Electronic Engineering, Pukyong National university)
Chung, Su-Tae (Department of Electronic Engineering, Pukyong National university)
Publication Information
Journal of the Korean Institute of Electrical and Electronic Material Engineers / v.23, no.11, 2010 , pp. 869-874 More about this Journal
Abstract
Magnetoelectric composites with compositions (1-x)[0.5PZT-0.25PNN-0.25PZN](ferroelectric) - x[$(Ni_{0.9}Zn_{0.1})Fe_2O_4$](ferrite) in which x varies as 0, 0.1, 0.2, 0.4, 0.6, 0.8, 1.0 were prepared by conventional ceramic process. The presence of two phases (ferroelectric phase with large grain and ferrite phase with small grain) in the particulate ceramic composites was confirmed by XRD, SEM and EDX. The ferroelectric and magnetic properties of the composites were studied by measuring the P-E and M-H hysterisis loop on the composite composition (x=0, 0.1, 0.2, 1), they were strongly affects of the phase content in composite. The magnetoelectric votage was measured as a function of DC magnetic field and the maximum magnetoelectric voltage coefficient of 14 mV/cm Oe was observed in x=0.2(80 mol% ferroelectric and 20 mol% ferrite phase).
Keywords
Magnetoelectric; Composite; Magnetoelectric voltage coefficient;
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  • Reference
1 S. T. Chyng, S. H. Cho, and U. I. Lee, Journal of the Korean Ceramic Society, Vol. 29, No. 3, 183-188, (1992).
2 S. Narendra Babu, A. Siddeshwar, K. Srinivas, S. V. Suryanarana, and T. Bhimasankaram, J. Mater Sci 44, 3948-3951 (2009).   DOI
3 Y. J. Li, X. M. Chen, R. Z. Hou, and Y. H. Tang, SOLID STATE COMMUN 137, 120-125 (2006).   DOI   ScienceOn
4 Hsin-Kuang Liu, Jin. H. Huang, Chin-Wen Hsieh, and Hsin-Tsung Tu, J. Mater Sci 40, 1979-1985 (2005).   DOI
5 S. D. Bhame and P. A. Joy, SENSER ACTUAT A-PHYS 137, 256-261 (2007).   DOI
6 J. X. Zhang and L. Q. Chen, ACTA MATER 53, 2845-2855 (2005).   DOI
7 G. Srinivasan, V. M. Laletsin, R. Hayes, N. Puddubnaya, E. T. Rasmussen, and D. J. Fekel, SOLID STATE COMMUN 124, 373-378 (2002).   DOI
8 Y. K. Fetisov, K. E. Kamentsev, and A. Y. Ostashchenko, J MAGN MAGN MATER. 272-276, 2064-2066 (2004).   DOI
9 R. Grossinger, Giap V. Duong, and R. Sato-Turtelli, J MAGN MAGN MATER. 320, 1972-1977 (2008).   DOI   ScienceOn
10 S Narendra Babu, K Srinivas, S V. Suryanarayana and T Bhimasankaram, J. Phys. D: Appl. Phys. 41, 165407(6pp) (2008).   DOI
11 Rashed Adnan Islam, Dwight Viehland, and Shashank Priya, J. Mater Sci 43, 1497-1500 (2008).   DOI
12 C. M. Kanamadi, S. R. Kulkarni, B. K. Chougule, Jung Hyun Jeong, Byung Chun Choi, and Young Soo Kang, J. Mater Sci; Mater Electron 20, 632-636 (2009).   DOI
13 B. K. Bammannavar, G. N. Chavan, L. R. Naik, and B. K. Chougule, Mater. Chem. Phys. 117, 46-50 (2009).   DOI
14 Renbing Sun, Bijun Fang, Xinwei Dong, and Junming Liu, J. Mater Sci 44, 5515-5523, (2009).   DOI
15 Jungho Ryu, Shashank Priya, Kenji Uchino, and Hyoun Ee Kim, J ELECTROCERAM. 8, 107-119, (2002).   DOI   ScienceOn
16 H. B. Kang, Electrical and Electronic Engineering Material, (Chung Moon Gak Press, 1986) pp. 470-540.
17 S. T. Chung, K. Nagata, and H, Igarashi, Ferroelectrics, Vol. 94, 243-247 (1989).   DOI