RU2653134C1 - Magnetoelectric composite material for magnetic field sensor - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: used for the production of ME composite materials with an internal constant magnetic field. Summary of invention consists in fact, that magnetoelectric composite material for a magnetic field sensor comprises magnetostrictive and piezoelectric materials made of lead zirconate titanate ceramics PbZr_0.53Ti_0.47O₃ components, where the magnetostrictive component contains an internal constant magnetic displacement field, the magnetostrictive layer is formed of the terphenol granules distributed in the epoxy compound Tb_0.12Dy_0.2Fe_0.68, and the internal constant magnetic displacement field is created by dividing the magnetostrictive layer into two regions with different concentrations of granules Tb_0.12Dy_0.2Fe_0.68.

EFFECT: technical result: providing the possibility of obtaining ME composite materials with an internal constant magnetic field, demonstrating optimal ME coefficients, simplifying the conditions for using the material in devices.

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Description

The invention relates to magnetoelectric (ME) materials and can be used in devices where a magnetic field is used to control electrical parameters (direct ME effect), and an external electric field is used to control magnetic parameters (inverse ME effect), for example, in magnetic field sensors , in microwave cavities, in magnetoelectric memory.

Mixed, layered, and thin-film magnetoelectric composite materials are known (M. Fiebig. Revival of the magnetoelectric effect, J. Phys. D: Appl. Phys., V. 38, R 123-R 152, 2005). The disadvantage of these materials are insignificant ME coefficients in the absence of an external constant magnetic bias field.

From the work of the authors of the present invention (A.V. Kalgin, S. A. Gridnev, ZH Gribe. Direct magnetoelectric effect in two-layer composite structures Tb _0.12 Dy _0.2 Fe _0.68 - PbZr _0.53 Ti _0.47 O ₃ during bending and longitudinal vibrations, FTT, T 56, Vol. 11, pp. 2111-2114, 2014) a two-layer ME composite material is known, obtained by applying a magnetostrictive layer of carefully mixed ferromagnetic granules of terphenol Tb _0.12 Dy _0.2 Fe _0.68 (TDF) and an epoxy compound PbZr _0.53 pre-polarized piezoelectric plate made of ceramic zirconate-titanate lead Ti _0.47 O ₃ (PZT). The disadvantage of this material is that in order to ensure optimal efficiency of the ME interaction in it, it is necessary to use a magnetizing external constant magnetic field.

ME composite materials with an internal magnetic bias field are known that do not require an external constant magnetic bias field to obtain practical ME coefficients (Y. Zhou, D. Maurya, Y. Yan, G. Srinivasan, E. Quandt, S. Priya. Self-biased magne-toelectric composites: an overview and future perspectives, Energy harvesting and systems, V. 3, I. 1, 42 pp., 2015).

From the patent of the Russian Federation 2363074 (IPC H01L 41/16, H01F 1/00, published on July 27, 2008), adopted as a prototype, a material for components of electronic devices is known, which is a two-phase composition of a magnetostrictive and ferroelectric component, the magnetostrictive component of which is made of material with saturation magnetization gradient, and the ferroelectric component - from a material with a polarization gradient.

However, difficulties arise here with the regulation and selection of optimal internal magnetic fields. In addition, the proposed method for the preparation of magnetostrictive components is a laborious process.

The objective of the invention is to increase the ME coefficients without applying an external biasing magnetic field H ₌ .

The technical result consists in obtaining ME composite materials with an internal constant magnetic field, demonstrating optimal ME coefficients, and in simplifying the conditions for using the material in devices.

The technical result is achieved by using a two-component material in the form of a magnetostrictive layer of terphenol Tb _0.12 Dy _0.2 Fe _0.68 and piezoelectric ceramic zirconate-titanate lead PbZr _0.53 Ti _0.47 O ₃ glued together. The magnetostrictive component is terphenol granules distributed in an epoxy compound. An internal constant magnetic field is created by dividing the magnetostrictive layer into two regions with different concentration of granules Tb _0.12 Dy _0.2 Fe _0.68 . The optimal concentration of terphenol granules in the first region of the magnetostrictive layer is 0.8 mass. shares, and in the second - from 0.33 to 0.77 mass. share.

To solve the problem of the invention, ME composite materials were obtained (a) Tb _0.12 Dy _0.2 Fe _0.68 - (b) PbZr _0.53 Ti _0.47 O ₃ [(a) TDF - (b) PZT] in in the form of a magnetostrictive layer glued together with a gradient distribution in the epoxy compound of TDF terphenol concentration and a PZT piezoceramic layer.

In FIG. 1 shows schematic representations of samples of (a) TDF - (b) PZT composites, where (a) TDF granules are randomly distributed and (b) there is a concentration gradient of TDF granules along the length of the magnetostrictive layer (invention).

In FIG. Figure 2 shows the dependence of the internal constant magnetic field H ₌ ^int (E) on the concentration of particles x in the second region of the magnetostrictive layer.

In FIG. 3 shows the dependence of the transverse ME coefficient α ₃₁ (mV / cm * E) on the internal constant magnetic field H ₌ ^int (E) at an alternating magnetic field H _~ 5 E and resonant frequency for the 1st harmonic of longitudinal vibrations across the width of the invention 0.9 TDF - 0.7 PZT with different concentration gradients of TDF granules along the length of magnetostrictive layers.

The concentration gradient of magnetic granules leads to a magnetization gradient, which creates an internal constant magnetic field. With an increase in the concentration gradient of magnetic granules, the internal magnetic field increases.

The solution to the problem allows to obtain the following technical result. The choice of the optimal concentration gradient of TDF granules creates a condition for achieving an internal constant magnetic field, which provides an optimal ME coefficient and eliminates the need to use external constant magnetic field sources that complicate the design of ME devices.

Example

In FIG. Figure 1 shows schematic images of samples of (a) TDF - (b) PZT composites that differ in the distribution of medium-sized granules z = 71 μm in magnetostrictive layers. The magnetic layers of the samples of composites are 6 (length, Z _TDF ) * 6 (width, W _TDF ) * a (thickness, a) mm ³ , where a = 0.3-1.5 mm, and the piezoelectric layers are 8 (length , L _PZT ) * 6 (width, W _PZT ) * 0.7 (thickness, b) mm ³ . The arrows indicate the directions of the internal magnetic field H ₌ ^int , polarization P and the intensity of the alternating magnetic field H _~ .

The mass fraction of granules in the magnetostrictive layers of the analog is 0.8, and since the granules in it are distributed statistically uniformly, the internal magnetic bias field H ₌ ^{int is} absent. To obtain non-zero H ₌ ^int , the invention creates a gradient of the distribution of magnetic granules along the length of the magnetostrictive layer. To this end, the magnetostrictive layer is divided into two halves in length, in one of which the mass fraction of granules is 0.8, that is, the same as in the analogue, and in the other is x, which varies in value from 0.33 to 0, 77. This allows one to obtain different in magnitude H ₌ ^int , directed perpendicular to the polarization P in the piezoelectric layer.

The tension H ₌ ^int for the invention of 0.9 TDF - 0.7 PZT varies from 18 to 1794 Oe with a change in x from 0.33 to 0.77 (Fig. 2) and is determined from the dependence of the transverse ME coefficient for voltage α ₃₁ from N ₌ the case of uniform distribution of particles in the magnetostrictive layer of 0.9TDF - 0.7PZT. For this, α ₃₁ (H ₌ ) is used to find α ₃₁ values for composites with a gradient distribution of TDF granules in magnetostrictive layers along the length of the samples and compare them with the corresponding H ₌ values.

The optimal transverse ME voltage coefficient of 24.2 mV / (cm⋅E) in the invention is observed with an internal magnetic field of 720 Oe, which is achieved according to FIG. 2 with optimal x _opt equal to 0.66. Other things being equal, the field H ₌ ^int = 720 Oe leads to an increase in α ₃₁ to 24.2 mV / (cm⋅E) in the invention 0.9TDF - 0.7PZT compared to α ₃₁ = 14 mV / (cm⋅E) with a uniform distribution of particles in the magnetostrictive layer 0.9TDF - 0.7PZT, where H ₌ ^int = 0 E.

A magnetoelectric composite material with a magnetization gradient can find application in various electronic devices and, in particular, in magnetic field sensors. The sensitivity coefficient of the sensor based on the invention is 0.9 TDF - 0.7 PZT with H ₌ ^int = 720 Oe with an alternating magnetic field strength of 5 Oe, the resonance frequency of the 1st harmonic of longitudinal vibrations along the width of the invention 226.3 kHz and a temperature of 20 ° C will be 16 , 9 V / T, which is 3.4 times more than the same coefficient of the most sensitive standard Hall sensors.

The magnetoelectric composite material (a) TDF - (b) PZT with a magnetization gradient is obtained as follows.

Statistical mixtures are created from carefully mixed medium size z ferrous TDF granules and an epoxy compound, which are applied in two sections onto a pre-polarized PZT plate as shown in FIG. 1b. These areas are distinguished by the mass content of TDF granules in order to create an internal bias magnetic field in the material. The magnetostrictive layer is glued to the piezoelectric layer, polymerized at room temperature for 24 hours, and then adjusted to the required geometric dimensions with a sanding sheet. The concentration gradient of magnetic granules and the thickness of the layers are chosen so as to provide the greatest ME effect in the material.

Claims (2)

1. Magnetoelectric composite material for a magnetic field sensor containing magnetostrictive and piezoelectric PbZr _0.53 Ti _0.47 O ₃ components, where the magnetostrictive component has an internal constant magnetic field, characterized in that the magnetostrictive layer is formed from Tb ₀ granules distributed in the epoxy compound _{, 12} Dy _0.2 Fe _0.68 , and the internal constant magnetic displacement field is created by dividing the magnetostrictive layer into two regions with different concentration of granules Tb _0.12 Dy _0.2 Fe _0.68 . 2. The magnetoelectric composite material according to claim 1, characterized in that the concentration of Tb _0.12 Dy _0.2 Fe _0.68 granules in the first region of the magnetostrictive layer is 0.8 mass. shares, and in the second region from 0.33 to 0.77 mass. share.

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