基于压电相和磁致伸缩相的本构方程以及弹性体的运动方程,简要推导了一维机电谐振模式下压电-磁致伸缩双层磁电复合材料横向磁电电压系数的表达式.采用相应的材料参数计算分析了Tb1-xDyxFe2-y(TDF)-Pb(Zr,Ti)O3(PZT)双层磁电复合材料的横向磁电电压系数与交流磁场频率的关系,以及复合材料的长度和压电相体积分数对机电谐振频率的影响.计算与分析结果表明,双层磁电复合材料在机电谐振频率处具有明显的磁电响应特性.当有效机械品质因数为50,在谐振频率55.2 kHz处横向磁电电压系数达到峰值11.2V·cm-1·Oe-1,是低频下峰值(281.9 mV·cm-1·Oe-1)的40倍.机电谐振频率随复合材料长度的减小和压电相体积分数的增加而上升.实验结果说明TDF-PZT双层磁电复合材料在机电谐振频率处具有显著增强的磁电效应,实际有效机械品质因数约为48.
参考文献
| [1] | Suchetelene J V.Product properties:A new application of composite materials[J].Philips Res Rep,1972,27:28-37. |
| [2] | Fiebig M.Revival of the magnetoelectric effect[J].J Phys D:Appl Phys,2005,38(8):123-152. |
| [3] | Ma J,Hu J,Li Z,et al.Recent Progress in multiferroic magnetoelectric composites:From bulk to thin films[J].Adv Mater,2011,23(9)..1062-1087. |
| [4] | Wang Y,Gray D,Berry D,et al.An extremely low equivalent magnetic noise magnetoelectric sensor[J].Adv Mater,2011,23(35)..4111-4114. |
| [5] | Nan C W,Li M,Huang J H.Calculations of giant magnetoelectric effects in ferroic composites of rare-earth-iron alloys and ferroelectric polymers[J].Phys Rev B,2001,63(14):144415-1-144415-9. |
| [6] | Ryu J,Carazo A V,Uchino K,et al.Magnetoelectric properties in piezoelectric and magnetostrictive laminate composites[J].JpnJ ApplPhys,2001,40(8):4948-4951. |
| [7] | Bichurin M I,Petrov V M,Srinivasan G.Theory of low-frequency magnetoelectric effects in ferromagnetic-ferroelectric layered composites[J].J Appl Phys,2002,92(12):7681-7683. |
| [8] | Srinivasan G,Rasmussen E T,Levin B J,et al.Magnetoelectric effects in bilayers and multilayers of magnetostrictive and piezoelectric perovskite oxides[J].Phys Rev B,2002,65(13):134402-1-134402-7. |
| [9] | Srinivasan G,Rasmussen E T,Hayes R.Magnetoelectric effects in ferrite-lead zirconate titanate layered composites:The influence of zinc substitution in ferrites[J].Phys Rev B,2003,67(1):014418-1-014418-10. |
| [10] | Bichurin M I,Petrov V M,Srinivasan G.Theory of low frequency magnetoelectric coupling in magnetostrictive piezoelectric bilayers[J].Phys Rev B,2003,68(5):054402-1-054402-13. |
| [11] | Dong S X,Li J F,Viehland D.Longitudinal and transverse magnetoelectric voltage coefficients of magnetostrictive/piezoelectric laminate composite:Theory[J].IEEE Transaction on Ultrasonics,Ferroelectrics and Frequency Control,2003,50(10):1253-1261. |
| [12] | Bi K,Wang Y G,Wu W,et al.The large magnetoelectric effect in Ni-lead zirconium titanate-Ni trilayers derived by electroless deposition[J].J Phys D:Appl Phys,2010,43(13):132002-1-132002 5. |
| [13] | Vaz C A F,Hoffman J,Segal Y,et al.Origin of the magnetoelectric coupling effect in Pb (Zr0.2 Ti0.8) O3 /La0.8 Sr0.2 MnO3 multiferroic heterostructures[J].Phys Rev Lett,2010,104(12):127202-1-127202-4. |
| [14] | 胡渊,龚国斌,曹东升,等.压电/磁致伸缩/环氧树脂层合复合材料的磁电效应及其频响特性[J].复合材料学报,2007,24(4):29-33.Hu Yuan,Gong Guobin,Cao Dongsheng,et al.Magnetoelectric effect and its frequency response for PZT/Terfenol-D/epoxy laminate composites[J].Acta Materiae Compositae Sinica,2007,24(4):29-33. |
| [15] | 郑洋,谢丹,刘理天.用于磁传感器的新结构磁电复合材料[J].复合材料学报,2011,28(2); 136-141.Zheng Yang,Xie Dan,Liu Litian.A novel structure magnetoelectric composite for magnetic sensor[J].Acta Materiae Compositae Sinica,2011,28(2):136-141. |
| [16] | Bichurin M I,Kornev I A,Petrov V M,et al.Theory of magnetoelectric effects at microwave frequencies in a piezoelectric/magnetostrictive multilayer composite[J].Phys Rev B,2001,64(9):094409-1-094409-6. |
| [17] | Bichurin M I,Petrov V M,Kiliba Yu V,et al.Magnetic and magnetoelectric susceptibilities of a ferroelectric/ferromagnetic composite at microwave frequencies[J].Phys Rev B,2002,66(13):134404-1-134404-10. |
| [18] | Bichurin M I,Filippov D A,Petrov V M,et al.Resonance magnetoelectric effects in layered magnetostrictive piezoelectric composites[J].Phys Rev B,2003,68 (13):132408-1-132408-4. |
| [19] | Filippov D A.Theory of magnetoelectric effect in double-layer ferromagnetic-piezoelectric structures[J].Russian Physics Journal,2004,47(12):1213-1217. |
| [20] | Filippov D A,Bichurin M I,Nan C W,et al.Magnetoelectric effect in hybrid magnetostrictive-piezoelectric composites in the electromechanical resonance region[J].J Appl Phys,2005,97(11):113910-1-113910-4. |
| [21] | Zhang C L,Chen W Q,Li J Y,et al.One-dimensional equations for piezoelectromagnetic beams and magnetoelectric effects in fibers[J].Smart Mater Struct,2009,18 (9):095026-1-095026-12. |
| [22] | Bichurin M I,Petrov V M,Averkin S V,et al.Present status of theoretical modeling the magnetoelectric effect in magnetostrictive piezoelectric nanostructures.Part Ⅱ:Magnetic and magnetoacoustic resonance ranges[J].J Appl Phys,2010,107(5):053905-1-053905-18. |
| [23] | Bayrashev A,Robbins W P,Ziaie B.Low frequency wireless powering of microsystems using piezoelectric magnetostrictive laminate composites[J].Sensors and Actuators A:Physical,2004,114(2/3):244-249. |
| [24] | Laletsin U,Padubnaya N,Srinivasan G,et al.Frequency dependence of magnetoelectric interactions in layered structures of ferromagnetic alloys and piezoelectric oxides[J].Appl Phys A:Materials Science & Processing,2004,78(1):33-36. |
| [25] | Yang F,Wen Y M,Li P,et al.Resonant magnetoelectric response of magnetostrictive/piezoelectric laminate composite in consideration of losses[J].Sensors and Actuators A:Physical,2008,141(1):129-135. |
| [26] | Dong Shuxiang,Cheng Jinrong,Li J F,et al.Enhanced magnetoelectric effects in laminate composites of Terfenol-D/Pb(Zr,Ti)O3 under resonant drive[J].Appl Phys Letters,2003,83(23):4812-4814. |
| [27] | Wang Y,Yu H,Zeng M,et al.Numerical modeling of the magnetoelectric effect in magnetostrictive piezoelectric bilayers[J].Appl Phys A:Materials Science & Processing,2004,81(6):1197-1202. |
| [28] | Cao H X,Zhang N,Wei J J.Doping effect on crystal structure of BaTiO3 and magnetoelectric coupling of layered composites Tb1-x DyxFe2-y-BaTi0.99 M0.01 O3+δ[J].Journal of Alloys and Comounds,2009,472(1/2):257-261. |
| [29] | Zhang N,Liang D,Schneider T,et al.Is the magnetoelectric coupling in stickup bilayers linear?[J].J Appl Phys,2007,101(8):083902-1-083902-5. |
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