Progress in Dual Piezoelectric-Magnetostrictive Phase Magnetoelectric Sintered CompositesReport as inadecuate




Progress in Dual Piezoelectric-Magnetostrictive Phase Magnetoelectric Sintered Composites - Download this document for free, or read online. Document in PDF available to download.

Advances in Condensed Matter PhysicsVolume 2012 2012, Article ID 320612, 29 pages

Review Article

Philips Lumileds Lighting Co., 370 W. Trimble Road, San Jose, CA 95131, USA

Materials Science and Engineering, Virginia Tech, Blacksburg, VA 24061, USA

Received 26 September 2011; Accepted 2 December 2011

Academic Editor: Vladimir Petrov

Copyright © 2012 Rashed Adnan Islam and Shashank Priya. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

The primary aims of this review article are a to develop the fundamental understanding of ME behavior in perovskite piezoelectric-spinel magnetostrictive composite systems, b to identify the role of composition, microstructural variables, phase transformations, composite geometry, and postsintering heat treatment on ME coefficient, and c to synthesize, characterize, and utilize the high ME coefficient composite. The desired range of ME coefficient in the sintered composite is 0.5–1 V-cm·Oe. The studies showed that the soft piezoelectric phase quantified by smaller elastic modulus, large grain size of piezoelectric phase 1 m, and layered structures yields higher magnitude of ME coefficient. It is also found that postsintering thermal treatment such as annealing and aging alters the magnitude of magnetization providing an increase in the magnitude of ME coefficient. A trilayer composite was synthesized using pressure-assisted sintering with soft phase 0.9 PZT–0.1 PZN having grain size larger than 1 m and soft ferromagnetic phase of composition Ni0.8Cu0.2Zn0.2Fe2O4 NCZF. The composite showed a high ME coefficient of 412 and 494 mV-cm·Oe after sintering and annealing, respectively. Optimized ferrite to PZT thickness ratio was found to be 5.33, providing ME coefficient of 525 mV-cm·Oe. The ME coefficient exhibited orientation dependence with respect to applied magnetic field. Multilayering the PZT layer increased the magnitude of ME coefficient to 782 mV-cm·Oe. Piezoelectric grain texturing and nanoparticulate assembly techniques were incorporated with the layered geometry. It was found that with moderate texturing, d33 and ME coefficient reached up to 325 pC-N and 878 mV-cm·Oe, respectively. Nanoparticulate core shell assembly shows the promise for achieving large ME coefficient in the sintered composites. A systematic relationship between composition, microstructure, geometry, and properties is presented which will lead to development of high-performance magnetoelectric materials.





Author: Rashed Adnan Islam and Shashank Priya

Source: https://www.hindawi.com/



DOWNLOAD PDF




Related documents