Citation: | LIU Gao-Min, DU Jin-Mei, LIU Yu-Sheng, TAN Hua, HE Hong-Liang. Shock Wave Compression of PZT 95/5 Ferroelectric Ceramic[J]. Chinese Journal of High Pressure Physics, 2008, 22(1): 30-34 . doi: 10.11858/gywlxb.2008.01.007 |
Neilson F W. Effects of Strong Shocks in Ferroelectric Materials [J]. Bull Am Phys Soc, 1957, 2: 30.
|
Fleddermamm C B, Nation J A. Ferroelectric Sources and Their Application to Pulsed Power: A Review [J]. IEEE Trans on Plasma Science, 1997, 25(2): 212-220.
|
Прищепенко А Б, Третьяков Д В. Функционирование Генератора Частоты с Рабочим Теломиз Ферромагнетика и Сегнетоэлектрика [J]. Электричество, 2000, 4: 61-66. (in Russian)
|
Doran D G. Shock-Wave Compression of Barium Titanate and 95/5 Load Zirconate Titanate [J]. J Appl Phys, 1968, 39(1): 40-47.
|
Chhabildas L C. Dynamic Shock Studies of PZT 95/5 Ferroelectric Ceramic [R]. SAND84-1729, 1984.
|
Dick J J, Vorthman J E. Effect of Electrical State on Mechanical and Electrical Response of a Ferroelectric Ceramic PZT 95/5 to Impact Loading [J]. J Appl Phys, 1978, 49(4): 2494-2498.
|
Setchell R E. Shock Wave Compression of the Ferroelectric Ceramic Pb0. 99(Zr0. 95Ti0. 05)0. 98Nb0. 02O3: Hugoniot States and Constitutive Mechanical Properties [J]. J Appl Phys, 2003, 94(1): 573-588.
|
Barker L M, Hollenbach R E. Shock-Wave Studies of PMMA, Fused Silica, and Sapphire [J]. J Appl Phys, 1970, 41(10): 4208-4226.
|