Multiple broadband magnetoelectric response in Terfenol-D/PZT structure

Wen, Jianbiao; Zhang, Juanjuan; Gao, Yuan-Wen

doi:10.1088/1674-1056/27/2/027702

Cited by 6 publications

(6 citation statements)

References 25 publications

(25 reference statements)

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“…Keeping the focus on PZT-based materials and changing the magnetostrictive phase to Terfenol-D, Wen et al [ 66 ] reported a ME coefficient of 10 V·cm − 1·Oe −1 suitable for broadband magnetic field sensors. A lead-free ME laminate composite consisting of thickness-polarized piezoelectric Mn-doped Na 0.5 Bi 0.5 TiO 3 -BaTiO 3 single crystal and length-magnetized magnetostrictive Tb 0.3 Dy 0.7 Fe 1.92 alloy (L-T mode) have been fabricated by Wang et al [ 67 ], exhibiting a linear ME response of 1.32 V·cm −1· Oe −1 that opened up the possibility for environment-friendly magnetic sensors.…”

Section: Ceramic-based Mementioning

confidence: 99%

“…Keeping the focus on PZT-based materials and changing the magnetostrictive phase to Terfenol-D, Wen et al [66] reported a ME coefficient of 10 V•cm − 1•Oe −1 suitable for broadband magnetic field sensors. A lead-free ME laminate composite consisting of thickness-polarized piezoelectric Mn- Upon magnetic field annealing an exceptionally high ME coefficient of 737 V•cm −1• Oe −1 at the mechanical resonance of 753 Hz and 3.1 V•cm −1• Oe −1 out of resonance at 100 Hz, at 6 Oe was demonstrated.…”

Section: Ceramic-based Mementioning

confidence: 99%

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Magnetoelectrics: Three Centuries of Research Heading Towards the 4.0 Industrial Revolution

et al. 2020

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Magnetoelectric (ME) materials composed of magnetostrictive and piezoelectric phases have been the subject of decades of research due to their versatility and unique capability to couple the magnetic and electric properties of the matter. While these materials are often studied from a fundamental point of view, the 4.0 revolution (automation of traditional manufacturing and industrial practices, using modern smart technology) and the Internet of Things (IoT) context allows the perfect conditions for this type of materials being effectively/finally implemented in a variety of advanced applications. This review starts in the era of Rontgen and Curie and ends up in the present day, highlighting challenges/directions for the time to come. The main materials, configurations, ME coefficients, and processing techniques are reported.

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Section: Ceramic-based Mementioning

confidence: 99%

Section: Ceramic-based Mementioning

confidence: 99%

Magnetoelectrics: Three Centuries of Research Heading Towards the 4.0 Industrial Revolution

et al. 2020

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“…Because the elongation of the ferroelectric layer is not directly produced by the applied electric field but instead driven by the ferromagnetic layer, the interface coupling between the two phases becomes the key factor for an enhanced ME effect [34]. In order to reduce the influence of interface properties on the magnetoelectric response, many novel magnetoelectric structures are designed and prepared [34,35,36,37,38,39]. For example, Bi et al made the magnetic material into a groove and placed the piezoelectric layer in the groove.…”

Section: Introductionmentioning

confidence: 99%

“…Wen et al presented a novel ME structure, made up of one Terfenol-D layer and three PZT-5A layers, and showed that the three PZT-5A layers can be driven by one Terfenol-D layer simultaneously. The experimental results showed that multiple resonant frequencies and broad bandwidth characteristics existed in this ME structure [39].…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation of the Magnetoelectric Effect in NdFeB-Driven A-Line Shape Terfenol-D/PZT-5A Structures

et al. 2019

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In this paper, the magnetoelectric (ME) effect is investigated in two kinds of A-line shape Terfenol-D/PZT-5A structures by changing the position of the NdFeB permanent magnet. The experimental results show that both ME composite structures had multiple resonance peaks. For the ME structure with acrylonitrile-butadiene-styrene (ABS) trestles, the resonance peak was different for different places of the NdFeB permanent magnet. Besides, the maximum of the ME coefficient was 4.142 V/A at 32.2 kHz when the NdFeB permanent magnet was on top of the Terfenol-D layer. Compared with the ME coefficient with a DC magnetic field, the ME coefficient with NdFeB magnets still maintained high values in the frequency domain of 65~87 kHz in the ME structure with mica trestles. Through Fourier transform analysis of the transient signal, it is found that the phenomenon of multiple frequencies appeared at low field frequency but not at high field frequency. Moreover, the output ME voltages under different AC magnetic fields are shown. Changing the amplitude of AC magnetic field, the magnitude of the output voltage changed, but the resonant frequency did not change. Finally, a finite element analysis was performed to evaluate the resonant frequency and the magnetic flux distribution characteristics of the ME structure. The simulation results show that the magnetic field distribution on the surface of Terfenol-D is non-uniform due to the uneven distribution of the magnetic field around NdFeB. The resonant frequencies of ME structures can be changed by changing the location of the external permanent magnet. This study may provide a useful basis for the improvement of the ME coefficient and for the optimal design of ME devices.

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“…Resonance is a dynamic problem, and large deformation also tends to occur; its analysis is beyond the scope of this investigation. Besides, the choice of component materials is also important to achieve strong coupling strength [16][17][18][19]. To fully explore this characteristic, ferromagnetic and ferroelectric materials with strong nonlinear hysteretic characteristics under an applied magnetic and electric field, respectively, are frequently investigated [20][21][22][23][24][25].…”

Section: Introductionmentioning

confidence: 99%

Direct and converse nonlinear magnetoelectric coupling in multiferroic composites with ferromagnetic and ferroelectric phases

2019

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In this paper, we develop a theoretical principle to calculate the direct and converse magnetoelectric (ME) coupling response of ferromagnetic/ferroelectric composites with 2–2 connectivity. We first present an experimentally based constitutive equation for Terfenol-D, and then build the mechanism of domain switch for the ferroelectric phase. In the latter, the change of Gibbs free energy, thermodynamic driving force and kinetic equations for domain growth are also established. These two sets of constitutive equations are shown to capture the experimental data of Terfenol-D and PZT, respectively, well. For the direct effect under an applied magnetic field, the induced electric field and the overall ME coupling coefficient are determined. For the converse effect under an applied electric field, the induced magnetization and the excited magnetic field are obtained. Both the induced electric filed under direct effect and the excited magnetic field under converse effect are shown to display the hysteretic characteristics, and also in good agreement with experiments. We conclude that the developed theory can both qualitatively and quantitatively reflect the essential features of nonlinear direct and converse ME coupling of the multiferroic composites.

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Multiple broadband magnetoelectric response in Terfenol-D/PZT structure

Cited by 6 publications

References 25 publications

Magnetoelectrics: Three Centuries of Research Heading Towards the 4.0 Industrial Revolution

Magnetoelectrics: Three Centuries of Research Heading Towards the 4.0 Industrial Revolution

Experimental Investigation of the Magnetoelectric Effect in NdFeB-Driven A-Line Shape Terfenol-D/PZT-5A Structures

Direct and converse nonlinear magnetoelectric coupling in multiferroic composites with ferromagnetic and ferroelectric phases

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