KR101443033B1 - Micro Motor Using Magnetic Vortex and nano-ring - Google Patents

Abstract

The present invention relates to a fine motor using a magnetic whirlpool structure and a nano-ring magnetic thin film. The present invention provides a magnetic thin film comprising a first magnetic thin film formed in a ring shape and having a spin arrangement of an onion structure including two magnetic domain walls fixed in position; And a second magnetic thin film which is located inside the first magnetic thin film and in which magnetic vortices are formed.
According to the present invention, it is possible to manufacture a motor that can be manufactured at an ultra-small size and can rotate at a very high speed. Accordingly, the present invention can be widely applied to various miniature precision mechanical technology fields such as semiconductor chips and drug delivery devices.

Description

[0001] The present invention relates to a micro motor using a magnetic vortex structure and a nano-ring magnetic thin film,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fine motor, and more particularly, to a super-fine and ultra-high speed motor using a magnetic vortex and an application device including the same.

Recently, with the remarkable development of information storage and processing and telecommunication industry, the technology development direction of major component device industry has been focused on reduction of device size. Particularly in the field of mechanical devices, attention is focused on the construction of micrometer and sub-size systems.

Micro-precision mechanical technology, which is called "Micro Electro Mechanical System" (MEMS), is a technology that uses a semiconductor micro-fabrication technology to move a circuit from a semiconductor device to a mechanical device. System on Chip (SoC). The technical features of MEMS include miniaturization, light weight, multifunction, high speed, and intelligence, which will be the core of future high technology industry.

In addition, the MEMS industry has been widely used in the aerospace, military, telecommunications, automotive, entertainment, biotechnology, medical, consumer, environmental, and industrial processes, .

However, MEMS products that have been successfully commercialized so far are very limited to inkjet printer heads, pressure sensors, acceleration sensors, and display devices. In particular, the development of actuators that are responsible for mechanical actuation is developing very slowly due to the technical difficulties of forming a three-dimensional structure.

For example, many attempts have been made to miniaturize actuators or motors, but they are only on the order of a few tens of millimeters. Except for magnetic motors, the speed and torque density are required for high-tech applications Of the total population.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a micromotor capable of realizing an extremely high rotation speed with an extremely small size by using a magnetic thin film having a unique shape and a spin arrangement, And to provide an application device.

According to an aspect of the present invention, there is provided a magnetoresistive sensor comprising: a first magnetic thin film formed in a ring shape and having a spin arrangement including two or more domain walls fixed in position; And a second magnetic thin film positioned inside the first magnetic thin film and having a magnetic vortex formed thereon.

In the fine motor, as the core of the magnetic vortex formed in the second magnetic thin film rotates, the first magnetic thin film rotates.

A notch may be formed in the first magnetic thin film to fix the spin arrangement.

Wherein the spin array and the magnetic vortex including the two or more magnetic domain walls are formed by applying a magnetic field in a direction parallel to the first magnetic thin film and the second magnetic thin film surface to form the spin arrangement of the first magnetic thin film and the second magnetic thin film To a saturation magnetization state, and then removing the magnetic field.

The first and second magnetic thin films may be selected from the group consisting of cobalt (Co), iron (Fe), nickel (Ni), iron-nickel alloys, iron-nickel cobalt alloys, iron-nickel-molybdenum alloys, Or the like.

The thickness of the first and second magnetic thin films is preferably 5 to 5,000 nm.

It is preferable that the outer diameter of the first magnetic thin film is 1 to 1,000 μm and the inner diameter of the first magnetic thin film is 1 to 1,000 μm.

The radius of the second magnetic thin film is preferably 50 to 10,000 nm.

The method of applying the rotational motion of the magnetic vortex nucleus formed in the second magnetic thin film may be performed by removing the position of the magnetic vortex nucleus from the center.

The method of applying the rotational motion of the magnetic vortex nucleus to the second magnetic thin film may be performed by applying a magnetic field or current to the second magnetic thin film. Here, the method of applying the magnetic field may be performed by applying a linear magnetic field, a circularly polarizing magnetic field, or a pulsed magnetic field.

The method of applying the current may be performed using a linear current, a pulse current, a circularly polarized current, or a vertical current.

The present invention also provides a semiconductor chip including the fine motor using the magnetic vortex.

The present invention also provides a drug delivery motor including the fine motor using the magnetic vortex.

The micromotor of the present invention comprises a ring-shaped first magnetic thin film having a spin arrangement including two or more magnetic domain walls, and a disk-shaped second magnetic thin film located inside the ring-shaped magnetic thin film and having a magnetic vortex As shown in FIG.

According to such a structure, it is possible to manufacture an ultra-high-speed rotating motor as well as an ultra-small size. Therefore, the micro-motor of the present invention can be widely used in various micro-precision mechanical technology fields such as semiconductor chips and drug delivery devices.

FIG. 1A is a view showing a structure of a fine motor using a magnetic vortex according to an embodiment of the present invention.
1B is a cross-sectional view of the embodiment shown in FIG. 1A.
FIG. 2A is a view showing a structure of a fine motor using a magnetic vortex according to another embodiment of the present invention.
Figure 2B is a cross-sectional view of the embodiment shown in Figure 2A. FIG. 3 is a view showing a magnetization arrangement formed on the ring and the disk constituting the fine motor of FIGS. 1 and 2. FIG.
4A is a diagram schematically showing the structure of a magnetic vortex having a nucleus in the "up" direction.
FIG. 4B is a view schematically showing a structure of a magnetic vortex having a nucleus in a "downward" direction. FIG. 5 is a diagram showing a diameter and a thickness of a thin film for stably forming a magnetic vortex.
6A, 6B, and 7 are views for explaining a method of generating a rotational motion of a magnetic vortex nucleus by applying a circularly polarized magnetic field to the magnetic thin film.
8 is a diagram for explaining a method of generating a rotational motion of a magnetorheological core using a linear current or a pulse current.
FIG. 9 is a diagram for explaining a method of generating rotational motion of the magnetorheological nucleus using a circularly polarized current. FIG.
FIGS. 10A and 10B are diagrams for explaining a method of generating a rotational motion of a magnetic vortex nucleus using a vertical current. FIG.
FIG. 11 is a view for explaining the principle of generating a rotating magnetic field by rotation of the magnetic vortex nucleus, and shows a stray field according to a state in which the magnetic vortex core is deviated from the center of the second magnetic thin film.
12 shows the trajectory of the stray magnetic field generated when the magnetic vortex core rotates at the center of the second magnetic thin film in an out-of-plane position.
FIG. 13 shows the result of computational simulation of changes in the spin arrangement including two or more magnetic domains in response to application of a rotating magnetic field to the first magnetic thin film.
Fig. 14 is a view for explaining the action of the rotation in the case (a) where the groove is not formed in the first magnetic thin film and the case (b) in which the groove is formed.
15A is a view for defining the relative angles of magnetic vortex nuclei formed in the two magnetic domains formed on the first magnetic film and the second magnetic film.
FIG. 15B is a diagram showing the result of computer simulation about the total energy and the torque change according to the relative angles of the magnetic domains of the magnetic vortex nucleus formed on the first magnetic thin film and the two magnetic domains formed on the first magnetic thin film.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and should be construed in accordance with the technical meanings and concepts of the present invention.

The embodiments described in the present specification and the configurations shown in the drawings are preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention and thus various equivalents and modifications Can be.

FIGS. 1A and 2A are views showing a structure of a fine motor using a magnetic vortex according to an embodiment of the present invention, and FIGS. 1A and 2B are sectional views.

As shown in FIGS. 1A and 2A, the fine motor using the magnetic vortex according to the present invention includes first and second magnetic thin films 102 and 202 formed in a ring shape and second magnetic thin films 101 and 102 disposed in the first magnetic thin film, 201). The first magnetic thin films 102 and 202 serve as rotors of the motor and the second magnetic thin films 101 and 201 serve as stator. 1B, the second magnetic thin film 101 is fixed to the substrate 105 by a fixing shaft 104. The first magnetic thin film is separated from the substrate by the rotation shaft 103 and is freely rotatable Do. 2B, the second magnetic thin film 201 is fixed to the substrate 205 by a fixed shaft 204. The first magnetic thin film is supported by a track 206 formed on the substrate 205 and a rotating shaft 203, respectively. In order to smoothly rotate the first magnetic thin films 102 and 202 serving as rotors, lubricant materials are used between the substrates 105 and 205, the fixed shafts 104 and 204, the orbital 206 and the rotating shafts 103 and 203 .

The first magnetic thin films 102 and 202 described above are formed with a spin arrangement including two or more magnetic domain walls and a magnetic vortex is formed in the second magnetic thin films 101 and 201. [ FIG. 3 is a view showing a spin arrangement state formed in the ring (first magnetic thin film) and the disk (second magnetic thin film) constituting the fine motor of FIGS. 1 and 2. In the first magnetic thin film 102, And a magnetic vortex is formed in the second magnetic thin film 101. As shown in FIG. Here, the spin arrangement state formed in the ring (first magnetic thin film) and the disk (second magnetic thin film) is referred to as an onion structure.

The magnetic vortex is a unique spin array structure (see Figs. 4A and 4B) which is formed very stably in a disk-shaped magnetic thin film having a thickness of several tens of nanometers (nm) and a diameter of several tens to several thousand nanometers A nucleus 402 having a diameter of 10 to 20 nanometers and having a magnetization direction in a direction of " upper " or " lower ", and spin components 403 arranged in a circumferential direction around the nucleus. This unusual spin arrangement has the eigenfrequency of the nuclear spin depending on the geometry of the magnetic film and the intrinsic properties of the constituent material. Accordingly, when an external stimulus (magnetic field or current) corresponding to the natural frequency is applied, a small size of magnetic field (for example, a magnetic field of Oe magnitude) due to a resonance effect causes self- Performs rotational motion with frequency. Accordingly, the present invention using such a rotary motion of the magnetic vortex core to generate a rotating magnetic field around the magnetic thin film, by ensuring that convert such a magnetic energy into a mechanical rotational movement, the rotational speed is 10 high speed up to ⁹ RPM, very small We want to implement a motor.

That is, the magnetic vortex nuclei formed on the second magnetic thin films 101 and 201 are rotated to generate a rotating magnetic field around the second magnetic thin films 101 and 201, and the rotation magnetic field causes the first magnetic thin films 102 and 202 to be rotated To rotate the first magnetic thin films (102, 202).

The first and second magnetic thin films may be formed of a ferromagnetic material such as Co, Fe, Ni, iron-nickel alloy, iron-nickel cobalt alloy, and iron- Alloys are representative. Among these materials, permalloy, which is a kind of iron-nickel alloy, can be most preferably used.

The first and second magnetic thin films are preferably formed to have a thickness of 5 to 5,000 nm in order to form a spin array including a magnetic vortex and a magnetic domain wall and to effectively transmit a magnetic field therebetween. The first magnetic thin film preferably has an inner diameter and an outer diameter of 1 to 1,000 μm and 1 to 1,000 μm, respectively. In addition, the radius of the second magnetic thin film is preferably 50 to 10,000 nm. For reference, the diameter and the thickness of the thin film for stably forming the magnetic vortex are as shown in Fig.

The above-described fine motor structure of the present invention can be implemented by patterning a magnetic thin film. The formation of the spin array including the magnetic vortex and two or more magnetic domain walls in the first magnetic thin film 102 and the second magnetic thin film 101 can be achieved by forming a spin array in the first magnetic thin film 102 and the second magnetic thin film 101 3 by applying a strong magnetic field in the y direction to bring the spin arrangement of the first magnetic thin film 102 and the second magnetic thin film 101 into a saturation state and then removing the magnetic field.

The rotation of the first magnetic thin film by the rotation of the magnetic vortex core of the second magnetic thin film will be described in detail as follows.

First, the core of the magnetic vortex formed in the second magnetic thin film is rotated. Here, the rotation of the magnetic vortex nucleus occurs when a static magnetic field or a static current that does not change with time is applied to separate the position of the magnetic vortex nucleus from the center of the magnetic thin film. When the application of static magnetic field or constant current is stopped, the magnetic vortex core deviating from the center rotates and returns to the center, and the magnetic vortex core reaching the center does not rotate any more. Here, "center" refers to the position when the magnetic vortex nucleus is in a stable state without being influenced by an external magnetic field. For example, in the case of a circular thin film, it indicates the center of a circle. In addition, by applying a magnetic field or current that continuously changes its size or direction with time, it can continuously generate the rotation of the magnetic vortex nucleus with low energy consumption.

Here, among the methods of continuously generating the circular motion of the magnetic vortex nucleus, a method of applying a magnetic field to the second magnetic thin film includes, for example, a method of applying a linear magnetic field or a pulsed magnetic field and a method of applying a circular magnetic field have.

In a method of applying a linear magnetic field or a pulsed magnetic field, a magnetic field can be generated by arranging a conductor parallel to the magnetic thin film on or below the magnetic thin film and flowing a current through the conductor. Here, when the frequency of the applied linear magnetic field or the pulsed magnetic field is adjusted to the frequency of the magnetic vortex eigenmode, the continuous vortex nucleus can be generated with a small energy consumption using the resonance phenomenon.

6A and 6B, an alternating current or a pulse current having a phase difference with respect to time is applied to two conductive lines 602 which meet with each other as shown in FIGS. 6A and 6B to form a magnetic field whose direction rotates with time, It is possible to generate a circular motion of the nucleus. More specifically, in the case of a circularly polarizing magnetic field, a sinusoidal current 701 is applied to one conductor and a current 702 having a 90 degree phase difference is applied to another conductor as shown in FIG. 7, But the direction in which the magnetic field is formed rotates with time. In this case, the rotational frequency of the magnetic field can be controlled by controlling the frequency of the applied current, and the direction of rotation of the magnetic field can be adjusted by adjusting the phase difference between the currents. For example, when a current of a sine-wave form is applied in the x direction as shown in Fig. 6 and a current having a phase difference of +90 degrees in the y direction is applied, the rotation direction of the generated circularly polarized magnetic field is counterclockwise . As another example, when a current of a sine shape in the x direction is applied as shown in Fig. 6 and a current having a phase difference of -90 degrees in the y direction is applied, the direction of rotation of the generated circularly polarized magnetic field is clockwise .

Here, using the resonance phenomenon of the magnetic vortex eigenmode, it is possible to generate a continuous circular motion of the self-vortex nucleus with a small power. That is, a circularly polarized magnetic field having a rotational frequency equal to the natural frequency of the magnetic vortex formed on the magnetic thin film is formed and applied to the magnetic thin film, whereby the continuous rotational motion of the magnetic vortex nucleus can be generated with a small energy by resonance. In this case, the applied circularly polarized magnetic field may rotate in the counterclockwise direction in the case of the magnetizing vortex having the nucleus in the "up" direction and in the clockwise direction in the case of the magnetizing vortex having the nucleus in the "lower" direction.

In addition, a method using a current can use a linear current, a pulse current, a circularly polarized current, a vertical current, or the like as a method of generating a motion of the magnetic vortex nucleus by flowing a current through the magnetic thin film.

A method of using a linear current or a pulse current is a method in which an electrode 802 is attached to a magnetic thin film 801 as shown in FIG. 8 to flow a current, and by using a spin torque effect, Circular motion is generated. Here, when the frequency of the applied linear current or pulse current is matched to the frequency of the eigenmode of the magnetic vortex, the resonance phenomenon can be used to generate a continuous rotational motion of the magnetic vortex nucleus with a small energy consumption.

As shown in FIG. 9, when a conductive line 902 is connected to the magnetic film 901 and currents 701 and 702 having a phase difference of 90 degrees are applied as in the case of a circularly polarizing magnetic field, And the magnetic vortex nucleus rotates through it. In this case, the rotational frequency of the circular deflection current can be controlled by controlling the frequency of the applied current, and the rotational direction of the circular deflection current can be adjusted by adjusting the phase difference between the currents. For example, when a current of a sine-shaped form is applied in the x direction as shown in Fig. 9 and a current having a phase difference of +90 degrees in the y direction is applied, the direction of rotation of the generated circularly- . As another example, in the case where a current of a sine shape in the x direction is applied and a current having a phase difference of -90 degrees in the y direction is applied as shown in Fig. 9, the direction of rotation of the generated circularly polarized current is clockwise .

Here, by applying a circularly polarized current having a rotational frequency equal to the natural frequency of the magnetic vortex formed in the magnetic thin film, continuous rotational movement of the magnetic vortex nucleus can be generated with a small energy by the resonance phenomenon. In this case, the applied circularly polarized current may rotate in the counterclockwise direction in the case of the magnetizing vortex having the nucleus in the "up" direction and in the clockwise direction in the case of the magnetizing vortex having the nucleus in the "lower" direction.

According to the method using a perpendicular current, as shown in FIGS. 10A and 10B, the magnetic thin film is configured to have a free layer 1001 having a magnetic vortex structure, an intermediate layer 1002, and a deflection layer 1003. The deflection layer 1003 has a magnetization in the vertical direction opposite to the magnetization direction of the magnetic vortex core and has strong magnetic anisotropy so that the magnetization direction is not easily changed by an external current or a magnetic field. In this structure, when a current is applied, a spin polarized current is formed as it passes through the deflection layer 1003, and a torque is formed in accordance with the correlation between the spin direction of the current and the magnetization direction of the magnetic vortex nucleus, Rotation of the vortex nucleus occurs. Here, the deflecting layer 1003 is made of a material having vertical magnetic anisotropy such as Co / Pt, Co / Pd, CoPt, CoPd, CoCrPt, FePt, FePd and the intermediate layer 1002 is made of a non- Lt; / RTI >

A magnetic field or a current corresponding to the natural frequency of the magnetic vortex formed in the second magnetic thin film is applied to the second magnetic thin film and the magnetic vortex nucleus Can be induced.

Next, when the core of the magnetic vortex formed in the second magnetic thin film is rotated, an elliptical rotating magnetic field is generated around the second magnetic thin film.

When an external magnetic field or current is applied to the second magnetic thin film and the magnetic vortex core deviates from the center, a stray field is formed around the second magnetic thin film (see FIG. 11). When the magnetic vortex nucleus deviates from the center, the stray magnetic field also rotates in an elliptical shape to generate a rotating magnetic field (see FIG. 12). At this time, the rotational frequency of the rotating magnetic field is equal to the rotational frequency of the magnetic vortex core, ranging from several hundred MHz to several GHz. 11 (a) and 11 (b) are views for explaining the principle of generating a rotating magnetic field by rotation of the magnetic vortex nucleus. In accordance with a state in which the magnetic vortex nucleus 1102 deviates from the center of the second magnetic thin film 1101 (The magnetization direction on the plane of the second magnetic thin film, and the green mark inside 1101 indicates the magnetization direction in the z direction) (the arrow outside 1101 indicates the direction of the stray magnetic field, Indicating the magnitude of the magnetic field). Therefore, when the magnetizing vortex nucleus 1102 performs a circular motion with time, a stray magnetic field is formed around the second magnetic thin film 1101, and the locus corresponding to the position of the stray magnetic field is as shown in Fig.

Next, the generated rotating magnetic field is applied to the first magnetic thin film, and a torque is generated between the applied rotating magnetic field and the spin arrangement formed on the first magnetic thin film. As a result, since the spin arrangement of the first magnetic thin film is fixed, mechanical rotation is generated in the first magnetic thin film and the first magnetic thin film rotates.

When the magnetic vortex nucleus of the second magnetic thin film rotates away from the center, rotation is caused by the relative action of the magnetic field and the spin arrangement including two or more magnetic domains formed on the first magnetic thin film, The spin array formed on the magnetic thin film is rotated.

FIG. 13 shows the result of computational simulation of the change in the spin arrangement including the magnetic domain wall due to the application of the rotating magnetic field. In this computer simulation, the rotating magnetic field is directly applied for convenience, and the generation of the rotating stray magnetic field by the circular motion of the magnetic vortex nucleus can be approximated by using the rotating magnetic field. The structure used in this computer simulation is as follows. It is one example and the same result can be obtained even if it has a different structure. The outermost radius of the first magnetic thin film is 260 nm, the width of the first magnetic thin film is 60 nm, and the thickness of the first magnetic thin film is 5 nm. The rotation frequency of the applied rotating magnetic field and the rotation of the magnetic wall according to the intensity are shown in FIG. In Fig. 13A, "O" means that periodic rotation of the magnetic domain wall occurs at the corresponding frequency and intensity, and "X" means that periodic rotation of the magnetic domain wall does not occur at the corresponding frequency and intensity. If the rotational frequency and the intensity of the rotating magnetic field are matched with respect to the given structure, the rotation of the spin array including the two magnetic domain walls can be caused.

13B shows the rotation of the spin array including both the magnetic domain wall by the rotating magnetic field having the intensity of 20 Oe and the rotational frequency of 150 MHz. (The arrow indicates the direction of the rotating magnetic field, and the color indicates the z component size of the spin array including both the magnetic domain walls). The following procedure can be described with reference to FIG. The step of rotating the magnetic vortex nucleus of the second magnetic thin film away from the center. Forming a stray magnetic field that is elliptically rotating around the second magnetic thin film by rotational motion of the magnetic vortex nucleus; The spinning due to the relative direction of the spin array including two or more magnetic domain walls formed in the first magnetic thin film and the stray magnetic field rotating in the elliptical shape occurs. And rotating the two or more magnetic domain walls formed in the first magnetic thin film by the rotation.

13A and 13B, the spin array including two or more magnetic domains formed on the first magnetic thin film is rotated by rotation of the magnetization spiral nuclei formed on the second magnetic thin film, and if two or more magnetic thin films are formed on the first magnetic thin film It can be seen that, when a plurality of magnetic domain walls are fixed, the first magnetic thin film can be rotated by applying mechanical rotation to the first magnetic thin film in accordance with the action-reaction rule.

In order to fix the spin arrangement of the first magnetic thin film, a groove may be formed in the first magnetic thin film. This may be formed during the patterning of the first magnetic thin film.

Fig. 14 is a view for explaining the action of the rotation in the case (a) where the groove 1404 is not formed in the first magnetic thin film and the case (b) in which the groove 1404 is formed. When the groove 1404 is not formed, the first magnetic thin film 1402 is rotated and the spin arrangement is rotated in a state where the first magnetic thin film 1402 is stopped, The first magnetic thin film 1402 itself rotates because the spin array can not be rotated by the grooves 1404 because the first magnetic thin film 1402 is formed at the position of two or more magnetic domain walls 1403 formed in the first magnetic thin film 1402. (a) and (b), the arrow displayed on the second magnetic thin film 1401 indicates the rotational motion of the nucleus. (a), the arrow displayed on the first magnetic thin film 1402 indicates the rotational motion of the magnetic domain wall 1403. (b), the arrow displayed on the first magnetic thin film 1402 indicates the rotational motion of the first magnetic thin film 1402. [

The number and position of the grooves should be the same as the number and position of the magnetic domain walls formed in the first magnetic thin film.

In the micromotor of the present invention, the energy of the entire structure can be determined according to the relative positions of the nuclei of the second magnetic thin film and the two or more magnetic domain walls formed in the first magnetic thin film. If the energy change is differentiated by a relative angle, The rotation due to the rotation of the vortex nucleus can be calculated.

FIG. 15 is a diagram showing a result of computational simulation of the total energy change and rotation according to the relative angles of the magnetic vortex nucleus and the two magnetic domain walls. FIG.

In this simulation, the material of the first magnetic thin film and the second magnetic thin film was permalloy (Ni ₈₀ Fe ₂₀ ), and the thickness of the second magnetic thin film was 20 nm and the diameter was 300 nm. The thickness of the first magnetic thin film was 20 nm, the inner diameter was 400 nm, and the outer diameter was 520 nm. 15A shows the relative positions of the two magnetic domain walls formed in the first magnetic thin film 1502 and the magnetic vortex nucleus 1503 formed in the second magnetic thin film 1501 (the second magnetic field 14B shows the total energy change due to the relative angle between the two magnetic domains formed on the first magnetic thin film and the magnetic vortex nucleus 1503, Lt; RTI ID = 0.0 > 1502 < / RTI > Here, the relative angles of the two magnetic domains formed on the first magnetic thin film 1502 and the magnetic vortex nucleus 1503 represent the angle? Shown in Fig.

The micromotor using the magnetic vortex structure of the present invention can be manufactured in a very small size by replacing it with a rotating magnetic field generated by rotation of the magnetic vortex core instead of a complicated type of coil structure used for forming a magnetic field in a conventional MEMS actuator have.

Further, by applying an external magnetic pole (magnetic field or current) corresponding to the natural frequency of the magnetic vortex, the motor can be rotated by inducing the rotation of the magnetic vortex core with a small-sized magnetic pole by the resonance phenomenon.

Therefore, it is expected that the micro-motor of the present invention can be widely used in a variety of micro-precision mechanical technology fields such as a semiconductor chip and a drug delivery device.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention.

Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

Claims (18)

A first magnetic thin film formed in a ring shape and having a spin arrangement of an onion structure including two magnetic domain walls fixed in position; And
A second magnetic thin film disposed inside the first magnetic thin film and having a magnetic vortex,
And a motor for driving the motor.
The method according to claim 1,
And the first magnetic thin film rotates as the nucleus of the magnetic vortex formed in the second magnetic thin film rotates.
The method according to claim 1,
And a notch is formed in the first magnetic thin film.
The method according to claim 1,
And a single magnetic domain is formed around the first magnetic thin film.
The method according to claim 1,
The spin array and the magnetic vortex of the onion structure including the two magnetic domain walls are formed by applying a magnetic field in a direction perpendicular to the first magnetic thin film and the second magnetic thin film, Wherein the magnetic field is formed by making the spin arrangement into a saturation magnetization state and then removing the magnetic field.
The method according to claim 1,
The first and second magnetic thin films may be selected from the group consisting of cobalt (Co), iron (Fe), nickel (Ni), iron-nickel alloys, iron-nickel cobalt alloys, iron-nickel-molybdenum alloys, Wherein the magnetic material is formed of a material having a high magnetic permeability.
The method according to claim 1,
Wherein the thickness of the first and second magnetic thin films is 5 to 5,000 nm.
The method according to claim 1,
Wherein the first magnetic thin film has an outer diameter of 1 to 1,000 μm and the first magnetic thin film has an inner diameter of 1 to 1,000 μm.
The method according to claim 1,
Wherein the second magnetic thin film has a radius of 50 to 10,000 nm.
The method according to claim 1,
Wherein the method for applying the rotational motion of the magnetic vortex nucleus formed in the second magnetic thin film is to deviate the position of the magnetic vortex nucleus from the center.
11. The method of claim 10,
The method of applying the rotational motion of the magnetic vortex nucleus to the second magnetic thin film is characterized by applying a magnetic field or a current.
12. The method of claim 11,
Wherein the method of applying the magnetic field applies a linear magnetic field, a pulsed magnetic field, or a deflecting magnetic field.
13. The method of claim 12,
Wherein the magnetic field is applied by applying a magnetic field corresponding to a natural frequency of the magnetic vortex formed in the second magnetic thin film.
12. The method of claim 11,
Wherein the method of applying the current uses a linear current, a pulse current, a circularly polarized current, or a vertical current.
15. The method of claim 14,
Wherein the current is applied by applying a current corresponding to a natural frequency of the magnetic vortex formed in the second magnetic thin film.
16. The method of claim 15,
Wherein the magnetic field is applied by applying a magnetic field corresponding to a natural frequency of the magnetic vortex formed in the second magnetic thin film.
A semiconductor chip comprising a fine motor using the magnetic vortex according to any one of claims 1 to 16.
A drug delivery motor comprising a fine motor using the magnetic vortex according to any one of claims 1 to 16.

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