Korea Institute of Materials Science (KIMS) , 797 Changwondaero , Seongsan-gu, Changwon , Gyeongnam 51508 , Republic of Korea.
School of Materials Science & Engineering , Yeungnam University , Gyeongsan , Gyeongbuk 38541 , Republic of Korea.
ACS Appl Mater Interfaces. 2018 Sep 26;10(38):32323-32330. doi: 10.1021/acsami.8b09848. Epub 2018 Sep 12.
We report the effect of epoxy adhesion layers with different mechanical or physical property on a magnetoelectric (ME) composite laminate composed of FeBSi alloy (Metglas)/single-crystal Pb(MgNb)O-Pb(Zr,Ti)O/Metglas to achieve an improved ME conversion performance. Through theoretical simulation, it was revealed that the Young's modulus and the thickness of interfacial adhesives were major parameters that influence the conversion efficiency in ME composites. In the experimental evaluation, we utilized three epoxy materials with a distinct Young's modulus and adjusted the average thickness of the adhesion layers to optimize the ME conversion. The experimental results show that a thin epoxy layer with a high Young's modulus provided the best performance in the inorganic-based ME conversion process. By tailoring the interfacial adhesion property, the ME laminate generated a high conversion coefficient of 328.8 V/(cm Oe), with a mechanical quality factor of 132.0 at the resonance mode. Moreover, we demonstrated a highly sensitive alternating current magnetic field sensor that had a detection resolution below 10 pT. The optimization of the epoxy layers in the ME laminate composite provided significant enhancement of the ME response in a simple manner.
我们报告了具有不同机械或物理性能的环氧粘结层对由 FeBSi 合金(Metglas)/单晶 Pb(MgNb)O-Pb(Zr,Ti)O/Metglas 组成的磁电(ME)复合材料层压板的影响,以实现改善的 ME 转换性能。通过理论模拟,揭示了杨氏模量和界面粘结剂的厚度是影响 ME 复合材料转换效率的主要参数。在实验评估中,我们利用三种杨氏模量明显不同的环氧材料,并调整粘结层的平均厚度来优化 ME 转换。实验结果表明,具有高杨氏模量的薄环氧层在无机基 ME 转换过程中表现出最佳性能。通过调整界面粘结性能,ME 层压板在共振模式下产生了 328.8 V/(cm Oe)的高转换系数和 132.0 的机械品质因数。此外,我们展示了一种具有低于 10 pT 的检测分辨率的高灵敏度交流磁场传感器。通过以简单的方式优化 ME 层压板中的环氧层,显著增强了 ME 响应。
