Paper Titles

Synthesis of Laser Beam Rapidly Solidified Novel Surfaces on D2 Tool Steel
p.493

Influence of Solid Particle Size on Burning and Mechanical Properties of AP/Al/HTPB Composites
p.500

Development of Fe-Cr-Co Permanent Magnets by Single Step Thermo-Magnetic Treatment
p.507

Failure Analysis of Engine Bearing
p.513

Piezoelectricity in 0-3 PZT-PVDF Nano Composites Prepared via a Modified Solution Casting Process
p.520

Synthesis and AC Electrical Characterization of Co Doped Bismuth Manganite Nanoparticles
p.527

Effect of Carbon Black on Curing Behavior, Mechanical Properties and Viscoelastic Behavior of Natural Sponge Rubber-Based Nano-Composites
p.532

Effect of Air Plasma Spraying Parameters on WC-Co Cermet Coating
p.540

Plasma Sprayed Alumina Coating on Ti6Al4V Alloy for Orthopaedic Implants: Microstructure and Phase Analysis
p.547

HomeKey Engineering MaterialsKey Engineering Materials Vols. 510-511Piezoelectricity in 0-3 PZT-PVDF Nano Composites...

Piezoelectricity in 0-3 PZT-PVDF Nano Composites Prepared via a Modified Solution Casting Process

Article Preview

Abstract:

0-3 nanocomposites of PVDF with varying volume percents of strontium doped PZT have been synthesized using a combination of a modified solution casting process and the hot press technique. The nanocrystalline PZT used prepared from the sol gel route and was in the calcined state. An increase in the volume percent of PZT caused an increase in the dielectric constant, dielectric loss and piezoelectric charge coefficients. The experimental dielectric constants gave a perfect fit to the theoretical Furukawa model. However, no significant trend is perceived for the dielectric loss. SEM and XRD aided in determining the morphology and the crystalline phases in PVDF, PZT and PVDF/PZT composite. TG/DSC was done to confirm the percentage crystallinity of PVDF. A comparison with samples prepared from the conventional solution casting process has also been given. Composites prepared from the modified solution casting process using nanocrystalline strontium doped PZT give better piezoelectric properties as compared to earlier works.

You might also be interested in these eBooks

Advanced Materials XII

Info:

Periodical:

Key Engineering Materials (Volumes 510-511)

Pages:

520-526

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.510-511.520

Citation:

Cite this paper

Online since:

May 2012

Authors:

S. Aftab, H. Nawaz, M.S. Mirza, Muhammad Shuaib, Muhammad Siddiq

Keywords:

Modified Solution Casting, Nanocomposite, Polymer-Matrix Composites, SEM

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2012 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

[1] R.E. Newnham, D.P. Skinner, and L.E. Cross: Mat. Res. Bull Vol. 13, (1978), p.525.

[2] C. J. Dias and D.K.D. Gupta: IEEE. Trans Vol. 3(5), (1996), p.706.

[3] C. Cui, US patent WO/035348. (1997).

[4] H.L.W. Chan, S.T. Lau, K.W. Kwok, Q.Q. Zhang, Q.F. Zhou and C.L. Choy: Sens. and. Actuat Vol. 75, (1999), p.252.

[5] E. Venkatragavaraj, B. Satish, P.R. Vinod and M.S. Vijaya: J. Phys. D. Appl. Phys Vol. 34, (2001), p.487.

[6] L.M. Zhang, Q. Shen and D. You: (Preparation and Properties of 0-3 PZT/PVDF Piezoelectric Composite Trans Tech Publications 2003).

[7] R. Senthilkumar, K. Sridevi, J. Venkatesa, V. Annamalai, and M.S. Vijaya: Ferroelectrics Vol. 325, (2005), p.121.

[8] A. Seema, K.R. Dayas and J.M. Varghese: J. Appl. Polym. Sci Vol. 106, (2007), p.146.

[9] D.Q. Zhang, D.W. Wang, J. Yuan, Q.L. Zhao, Z.Y. Wang and M.S. Cao: Chin. Phys. Lett Vol. 2(12), (2008), p.4410.

[10] M. Wegener, and K. Arlt: J. Phys. D (Appl. Phys) Vol. 41(16), (2008).

[11] T. Greeshma, R. Balaji, M.M. Nayak, and S. Jayakumar: Ferroelectrics Vol. 39, (2009), p.88.

[12] A. Safari: J. Phys. III Vol. 4, (1994), p.1129.

[13] W. Nhuapeng, J. Tontrakoon and T. Tunkasiri: CMU. J Vol. 1(1), (2002), p.61.

[14] R.W. Schwartz, J. Ballato, and G.H. Haertling, in: Piezoelectric and electro-optic ceramics, edited by R. C. Buchanan Ceramic materials for electronics, Marcel & Dekker USA, (2004).

[15] M. Shoaib, Y. Faheem and A. Rauf: J. Aust. Ceram. Soc Vol. 42(2), (2006), p.67.

[16] H.L.W. Chan, Y. Chen, and C.L. Choy: Study on PZT4 VF2/VF3 piezoelectric 0-3 composites, 9th Intl Symp on Appl of Ferroelectrics (ISAF IX) Proc, (1995), pp.198-20.

[17] J. Unsworth, (Piezoelectricity and Piezoelectric Materials Trans Tech Publications 1992).

[18] M.B. Suresh, T.H. Yeh, C.C. Yu and C.C. Chou: Ferroelectrics Vol. 38, (2009), p.80.

[19] D.D.L. Chung, in: Composite materials for dielectric application, Composite materials, Buffalo, Newyork, (2002), pp.125-166.

[20] V. Sencadas, R.G. Filho, and S. Lanceros-Mendez: J. Noncryst. Sol Vol. 352, (2006), p.2226.

[21] W.Y. Chang, T.H. Fang, S.H. Liu and Y.C. Lin: Mat. Sci. and. Eng. A Vol. 480, ( 2008), p.477.

[22] G. Botelho, S. Lanceros-Mendez, A.M. Goncalvez, V. Sencadas and J.G. Rocha: J. Noncryst. Sol Vol. 354, (2008), p.72.

[23] B. Ploss, W.Y. Ng, H.L.W. Chan, B. Ploss and C.L. Choy: Comp. Sci. Tech Vol. 61, (2001), p.957.