RU205097U1 - FILTER BASED ON 3D MAGONIC STRUCTURE - Google Patents

Abstract

The useful model relates to microwave radio engineering, in particular to devices based on magnetostatic waves, and can be used as a filter of magnetostatic waves. A technical problem is the creation of a filter that controls the number of FMR peaks. The technical result is to expand the functionality while simplifying the method of manufacturing the filter. The technical result is achieved by the fact that the filter based on a multilayer periodic 3D-magnon structure contains a non-magnetic organic substrate in the form of a meander, the longitudinal axis of the slots of which is perpendicular to the direction of propagation of magnetostatic spin waves (MSW), a ferromagnetic film placed on it, microstrip converters for exciting and receiving MSW in the film, the source of the magnetic field, the filter is configured to change the orientation of the longitudinal axis of the slots parallel to the direction of propagation of the MSW, while the film is made of permalloy. To change the orientation, the filter can be equipped with a drive or the magnetic field source can be configured to control both the magnitude and direction of the external magnetic field. The backing can be made of polycarbonate. Permalloy is a composite structure made up of 20% iron (Fe) and 80% nickel (Ni) atoms. 3 ill.

Description

The useful model relates to microwave radio engineering, in particular to devices based on magnetostatic waves, and can be used as a filter of magnetostatic waves.

Known functional microwave devices for various purposes, using magnonic crystals as a medium for the propagation of MSW (S.A. Nikitov, Yu.A. Filimonov, S.L. Vysotsky, E.S. Pavlov, N.N. Novitsky, A. I. Stogniy. “Physical foundations of filtering microwave signals using magnonic crystals.” // Collection of scientific papers “Heteromagnetic microelectronics.” - 2008. - V. 5. - P. 78-86 Magnonic crystals are YIG films with etched surface structures in the form of grooves, the axis of which is perpendicular to the direction of propagation of the MSW.A film of YIG is placed between the input and output microstrip microwave transducers.

However, in these functional microwave devices using one-dimensional and two-dimensional magnon crystals, the waveguide structures for MSWs are planar, which does not allow increasing the density of the arrangement of functional elements by connecting them into multilayer structures. The technology for performing periodic nanostructures is generally known and described in application to a magnetic recording medium (see, for example, US 6351339, RU 2391717).

A device based on a magnonic crystal is known, used to control the frequency of spin waves (WO 2009145579, IPC H03H2 / 00, publ. 03.12.2009). The device consists of a waveguide based on a thin magnetic film. The waveguide has three sections, one of which is a periodic structure - a magnonic crystal formed by periodically changing the width or thickness of a ferromagnetic film.

The disadvantage of this device is the inability to control the properties of the spectrum of spin waves by changing the control parameters.

The closest to the claimed device is a spin-wave switch (RU2697724, IPC HO1P5 / 18, 08/19/2019), which contains a non-magnetic substrate, placed on it a ferromagnetic film of yttrium iron garnet (YIG), microstrip converters for exciting and receiving magnetostatic spin waves (MSW) in YIG film, magnetic field source. On the surface of the substrate adjacent to the YIG film, a structure is formed in the form

meander of grooves, the longitudinal axis of which is perpendicular to the direction of propagation of the MSW.

The disadvantage of this device is the inability to control the number of ferromagnetic resonance (FMR) peaks.

A technical problem is the creation of a filter that controls the number of FMR peaks.

The technical result is to expand the functionality of the filter.

The technical result is achieved by the fact that a filter based on a multilayer periodic 3D-magnon structure containing a nonmagnetic organic substrate in the form of a meander, the longitudinal axis of the slots of which is perpendicular to the direction of propagation of magnetostatic spin waves (MSW), a ferromagnetic film placed on it, microstrip converters for excitation and reception An MSW in a film, a source of a magnetic field, a filter is configured to change the orientation of the longitudinal axis of the slots parallel to the direction of propagation of the MSV, while the film is made of permalloy.

To change the orientation, the filter can be equipped with a drive or the source of the magnetic field can be configured to control both the magnitude and direction of the external magnetic field.

The backing can be made of polycarbonate.

Permalloy is a composite structure made up of 20% iron (Fe) and 80% nickel (Ni) atoms.

The utility model is illustrated by drawings, where:

fig. 1 - a segment of a periodic 3D-magnonic structure in cross-section;

fig. 2 - dependence of the intensity on the external magnetic field;

fig. 3 - angular dependence of FMR on the magnitude of the external magnetic field.

The positions in the drawing indicate:

1 - a segment of a periodic structure;

2 - permalloy film;

3 - meander groove;

4 - meander protrusion;

5 - organic substrate - polycarbonate;

6 - the dependence of the intensity with the direction of the external magnetic field along

Z axis;

7 - the dependence of the intensity in the direction of the external magnetic field along the X axis;

8 - a group of low-field peaks of the FMR response;

9 - group of high-field FMR response peaks.

The filter contains a 3d-magnon structure in the form of a meander with grooves 3 and protrusions 4. Each segment of the structure consists of a non-magnetic substrate 5 made of organic material with a ferromagnetic film 2 of permalloy placed on it (Fig. 1). The film 2 repeats the contour of the groove 3 and the protrusions 4. The filter contains microstrip transducers for exciting and receiving MCBs in the film and a magnetic field source (not shown in the figure).

General dimensions of the structure: length p = 755 nm, thickness of the permalloy film h = 50 nm, thickness of the structure w = 170 nm. The groove depth is k = 120 nm. The length of the projection is m = 235 nm. The length of the horizontal part of the groove is n = 285 nm.

For this permalloy film, the saturation magnetization is M = 830 G, and film thickness - 50 nm.

This filter functions as follows: the structure is placed in an external magnetic field applied in the XZ plane of the magnon structure. A microwave signal with a fixed frequency of 9.7 GHz is supplied to the input microstrip converter located on the surface of film 2. By controlling the magnitude and direction of the external magnetic field along the XZ plane, the ferromagnetic resonance (FMR) response is measured. The result is a characteristic with maxima - signal passage and minima - signal non-transmission. The proposed filter can operate at another selected fixed frequency, while the FMR dependences will be rearranged on frequency.

FIG. 2 shows the dependence of the intensity on the external magnetic field. Curve 6 corresponds to the case when the external field is directed along the Z axis (along the slots), and one FMR peak is observed. Dashed curve 7 shows 4 FMR peaks; this corresponds to the case when the field is directed along the X axis (across the slots). There is a shift of the high-field peak in the region of higher fields and the appearance of peaks in the region of low fields. These characteristics can be associated with the fact that the vertical and horizontal parts of the meander make different contributions to the FMR.

FIG. 3 shows the angular dependence of the FMR on the magnitude of the external magnetic field. Splitting of peaks in the range of the angle of rotation of the external magnetic field 10 - 170 degrees into high-field (0.13-0.15 T) and low-field (0.05-0.13 T) is observed. When the angle changes, the properties of the film change.

The filter is easy to manufacture, since the permalloy film is organic in nature, which makes it easy to fabricate the structures. In this case, by changing the direction of the external magnetic field, it is possible to obtain different FMR contributions. When the field is directed along the slots, one FMR peak with a higher intensity is obtained, in contrast to the case when the field is directed along the X axis (across the slots), it is possible to obtain several FMR peaks.

The saturation magnetization of the permalloy films was M = 800 G.

The source of the controlling external magnetic field is configured to change the magnitude and polarity of the magnetic field. It is also possible to change the position of the structure relative to the magnetic field by rotating it with a drive.

Thus, when the angle of the direction of the external magnetic field changes, the properties of the film change, and as the angle increases, the peak splits into high-field and low-field peaks. This makes it possible to control the properties of propagating spin waves in a given structure.

Claims (5)

1. A filter based on a multilayer periodic 3D magnon structure, containing a nonmagnetic organic substrate in the form of a meander, the longitudinal axis of the groove of which is perpendicular to the direction of propagation of magnetostatic spin waves (MSW), a ferromagnetic film placed on it, microstrip converters for exciting and receiving MSWs in a film, a magnetic field source, characterized in that the filter is configured to change the orientation of the longitudinal axis of the groove parallel to the direction of propagation of the MSW, while the film is made of permalloy. 2. The filter according to claim 1, characterized in that it is equipped with a drive for changing the position of the structure relative to the direction of the magnetic field. 3. The filter according to claim 1, characterized in that the source of the magnetic field is configured to control both the magnitude and direction of the external magnetic field. 4. The filter according to claim 1, characterized in that the substrate is made of polycarbonate. 5. The filter according to claim 1, characterized in that the saturation magnetization of the permalloy films is M = 830 G, and the film thickness is 50 nm.

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