JP2005129858A - Magnetic storage element and magnetic memory - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a magnetic storage element that is constituted to reduce the power consumption required for recording information, and to provide a magnetic memory. <P>SOLUTION: The magnetic storage element 1 has a storage layer 3 which holds information based on the magnetized state of a magnetic material and is composed of a plurality of magnetic layers 16 and 18. The element 1 is constituted by disposing a magnetization fixing layer 2 composed of a plurality of magnetic layers 12 and 14 on the storage layer 3 through a nonmagnetic layer 15, and selecting the saturation magnetization and film thicknesses of the magnetic layers 12 and 14 of the magnetization fixing layer 2 so that the layer 2 may generate magnetic fields at magnetic poles. The magnetic memory has magnetic storage elements 1 thus constituted, and first and second wiring 5 and 6 intersecting each other. The magnetic storage elements 1 are respectively disposed near the intersecting points of the first and second wiring 5 and 6. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a magnetic memory element and a magnetic memory, and is particularly suitable for use in a nonvolatile memory.

In information equipment such as a computer, a high-speed and high-density DRAM is widely used as a random access memory.
However, since DRAM is a volatile memory in which information disappears when the power is turned off, a nonvolatile memory in which information does not disappear is desired.

With the rapid spread of information communication devices, especially small personal devices such as portable terminals, the elements such as memory and logic that compose this device are becoming more highly integrated, faster, lower power, etc. There is a demand for higher performance.
In particular, the nonvolatile memory is considered as an indispensable component for enhancing the functionality of the device.
For example, the nonvolatile memory can protect important information of the system and individuals even when the power supply is consumed or troubled or the server and the network are disconnected due to some trouble.
In addition, recent portable devices are designed to reduce power consumption as much as possible by putting unnecessary circuit blocks in a standby state, but realize a nonvolatile memory that can serve both as a high-speed work memory and a large-capacity storage memory. If possible, power consumption and memory waste can be eliminated.
Furthermore, if a high-speed, large-capacity nonvolatile memory can be realized, an “instant-on” function that can be instantly activated when the power is turned on will be possible.

Examples of the nonvolatile memory include a flash memory using a semiconductor and an FRAM (Ferro electric Random Access Memory) using a ferroelectric.
However, the flash memory has a drawback in that it is not suitable for high-speed access because the writing speed is as low as the order of microseconds.
On the other hand, the FRAM has a limited number of rewritable times of 10 ¹² to 10 ^14, and therefore, it has been pointed out that the durability is low to completely replace the SRAM and DRAM, and that fine processing of the ferroelectric capacitor is difficult. ing.

  A magnetic random access memory (MRAM) that records information by magnetization of a magnetic material attracts attention as a nonvolatile memory that does not have these drawbacks (see, for example, Non-Patent Document 1). .

The initial MRAM has a configuration based on a spin valve using an AMR (anisotropic magnetoresistive) effect, a GMR (Giant magnetoresistance) effect, or the like (see Non-Patent Document 2 and Non-Patent Document 3).
However, these configurations have a disadvantage that since the load memory cell resistance is as low as 10 to 100Ω, the power consumption per bit during reading is large and it is difficult to increase the capacity.

Therefore, an MRAM having a configuration utilizing a TMR (Tunnel Magnetoresistance) effect has been proposed.
Initially, the resistance change rate at room temperature was only 1 to 2% (see Non-Patent Document 4), but in recent years, a resistance change rate of nearly 20% has been obtained (see Non-Patent Document 5), and the TMR effect is obtained. Attention has been gathered in MRAM using the.

  The MRAM has TMR effect type storage elements arranged in a matrix, and has word write lines and bit write lines that cross the element groups vertically and horizontally in order to record information in specific elements of the element groups. The information is selectively recorded (written) only on the memory element located in the intersecting region.

As a method for recording information in the memory element, there are a method using an asteroid characteristic (for example, refer to Patent Document 1) and a method using a switching characteristic (for example, refer to Patent Document 2).
The method using the asteroid characteristic has a disadvantage that the selectivity depends on the coercive force characteristic of each memory element, and thus is vulnerable to variations in element dimensions and magnetic characteristics.
On the other hand, the method using the switching characteristics has an advantage that a large-scale memory can be easily realized even if there is some characteristic variation for each element because the magnetic field range usable for element selection is wide.

Here, FIG. 8 shows a schematic cross-sectional view of the MRAM using the switching characteristics.
In order to electrically select a memory cell in order to read information recorded in the memory cell, a diode, a MOS transistor, or the like can be used, but the configuration shown in FIG. 8 uses a MOS transistor.

First, the configuration of the magnetic memory element 101 that constitutes the memory cell of the MRAM will be described.
The two magnetic layers of the first magnetization fixed layer 112 and the second magnetization fixed layer 114 are disposed via the nonmagnetic layer 113, and thus are antiferromagnetically coupled. Furthermore, the first magnetization fixed layer 112 is disposed in contact with the antiferromagnetic layer 111, and has a strong unidirectional magnetic anisotropy due to exchange interaction acting between these layers. The four layers 111, 112, 113, and 114 constitute the fixed layer 102.
The two magnetic layers of the first storage layer 116 and the second storage layer 118 are disposed via the nonmagnetic layer 117, thereby being antiferromagnetically coupled. The first storage layer 116 and the second storage layer 118 are configured such that the directions of the magnetizations M1 and M2 rotate relatively easily. These three layers 116, 117, and 118 constitute a storage layer (free layer) 103.
A tunnel insulating layer 115 is formed between the second magnetization fixed layer 114 and the first storage layer 116, that is, between the fixed layer 102 and the storage layer (free layer) 103. The tunnel insulating layer 115 functions to cut the magnetic coupling between the upper and lower magnetic layers 116 and 114 and to flow a tunnel current. Thus, a TMR (Tunneling Magnetoresistance) element is formed by the fixed layer 102 in which the magnetization direction of the magnetic layer is fixed, the tunnel insulating layer 115, and the memory layer (free layer) 103 capable of changing the magnetization direction. Is configured.
The above-described layers 111 to 118, the base film 110, and the top coat film 119 constitute a magnetic memory element 101 made of a TMR element.

A selection MOS transistor 131 is formed in the silicon substrate 130, and an extraction electrode 109 is formed on one diffusion layer 133 of the selection MOS transistor 131 via a connection plug 108. A base film 110 of the magnetic memory element 101 is connected on the extraction electrode 109. Although not shown, the other diffusion layer 132 of the selection MOS transistor 131 is connected to a sense line via a connection plug. The gate 130 of the selection MOS transistor is connected to the selection signal line.
The top coat film 119 of the magnetic memory element 101 is connected to the bit line (BL) 106 thereon. A write word line (WL) 105 is disposed below the magnetic memory element 101 via an insulating film.

In the steady state, the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 are generally in an antiparallel state (a state in which the directions are opposite). Similarly, due to strong antiferromagnetic coupling through the nonmagnetic layer 113, the magnetization M11 of the first magnetization fixed layer 112 and the magnetization M12 of the second magnetization fixed layer 114 are in a substantially complete antiparallel state.
Usually, since the first magnetization fixed layer 112 and the second magnetization fixed layer 114 are configured to have the same saturation magnetization film thickness product, the leakage component of the magnetic pole magnetic field is negligibly small.

Further, FIG. 9 shows a schematic plan view of the MRAM in FIG. 8 viewed from directly above.
The magnetic memory element 101 has an elliptical planar shape, an easy magnetization axis 60 in the major axis direction of the ellipse, a hard magnetization axis 61 in the minor axis direction of the ellipse, and the easy magnetization axis 60 and the hard magnetization axis 61. And are orthogonal.
Further, the bit lines 106 and the word lines 105 are arranged in a lattice shape, and the angle α formed between them is constant (substantially orthogonal in FIG. 9). The magnetic memory element 101 is arranged at the intersection of the word line 105 and the bit line 106 so that the easy axis 60 thereof has an inclination angle θ (0 <θ <90 °) with respect to the word line 105.

In the memory cell having this configuration, when information is recorded in the storage layer 103 of the magnetic storage element 101, the direction of the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 is reversed. The bit current Ib and the word line current Iw are supplied to the bit line 106 and the word line 105, respectively. The bit line current Ib and the word line current Iw induce a bit line current magnetic field Hb and a word line current magnetic field Hw, respectively. The combined magnetic field of the word line current magnetic field Hw and the bit line current magnetic field Hb forms a rotating magnetic field that rotates clockwise or counterclockwise, as will be described later.
Then, by applying the current magnetic fields Hb and Hw, the direction of the magnetization M1 of the first storage layer 116 and the direction of the magnetization M2 of the second storage layer 118 is changed, so that information (for example, information “1” is stored in the storage layer 103). "Or information" 0 ") can be recorded.
The recorded information can be read by detecting a change in tunnel current due to the magnetoresistive effect.

Here, FIG. 10 shows an example of a magnetization curve when an external magnetic field H is applied in the easy axis direction of the magnetic memory element 101 having the configuration shown in FIG.
The magnitude of the combined magnetization M of the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 varies significantly depending on the magnitude of the external magnetic field.
The first threshold value is the spin flopping magnetic field Hsf. If the external magnetic field H is less than or equal to the spin flopping magnetic field Hsf, the magnetization M1 of the first memory layer 116 and the magnetization M2 of the second memory layer 118 always maintain an antiparallel state (↑ ↓).
When the external magnetic field H exceeds Hsf, the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 take a cross magnetization state and antagonize the external magnetic field H. However, the angle formed by the two magnetizations M1 and M2 is 180 degrees or less. If the external magnetic field H is removed from this state, the initial antiparallel state is often restored.
The next threshold value is the saturation magnetic field Hsat. When the external magnetic field H exceeds the saturation magnetic field Hsat, the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 are in a parallel state (↑↑). Once the external magnetic field H equal to or higher than the saturation magnetic field Hsat is applied, the memory layer 103 forgets the memory of the first anti-parallel state, so that even if the external magnetic field is removed, it does not always return to the initial magnetized state.

Subsequently, in the magnetic memory element 101 of the MRAM in FIG. 8, when the word line current magnetic field Hw and the bit line current magnetic field Hb are applied as the external magnetic field H, the magnetization M1 and the second magnetization M1 of the first memory layer 116 of the memory layer 103 are stored. Of the magnetization M2 of the storage layer 118 will be described.
By applying the external magnetic field H, the direction of the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 of the storage layer 103 changes as shown in FIG. Can be roughly divided into three types of operations, depending on the relationship between the state before applying the magnetic field and the state after removing the external magnetic field H.

First, the directions of the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 are reversed between a state before the application of the external magnetic field H and a state after the external magnetic field H is removed ( There is an operation in which the directions of the two magnetizations M1 and M2 are interchanged and change alternately). Hereinafter, such an operation is referred to as a “Toggle operation”.
Further, the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 are in the same direction in the state before the application of the external magnetic field H and the state after the external magnetic field H is removed. (The directions of the two magnetizations M1 and M2 are not interchanged). Hereinafter, such an operation is referred to as a “No switching operation”.
Furthermore, regardless of the state before the application of the external magnetic field H, in the state after the external magnetic field H is removed, the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 are determined. There is a movement that changes in the direction. In this operation, while the external magnetic field H is applied, the magnetizations M1 and M2 of the two layers are in the same direction (parallel), and the memory in the antiparallel state before the external magnetic field H is applied is lost. In the state after the external magnetic field H is removed, the magnetizations M1 and M2 of the two layers rotate one-way and change in a certain direction. Hereinafter, such an operation is referred to as a “Direct operation”.

  Next, in each of the three types of operations, a time change in the direction of the current pulse of the word line current Iw and the bit line current Ib and the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118, The time change of the electrical resistance R of the TMR element of the magnetic memory element 101 accompanying the change of magnetization M1, M2 is shown.

First, FIG. 11 shows an example of a current pulse, a temporal change in the magnetization direction of each storage layer, and a temporal change in the electrical resistance of the TMR element in the Toggle operation.
In FIG. 11, in the cycle in which 1-bit recording is performed, the time origin is set as time T0, the time T1, T2, T3, T4, and the direction of magnetizations M1, M2 until the time finally returns to the steady state. The change of the electrical resistance R of the TMR element is shown. The same applies to the drawings for other operations.

The pulse of the word line current Iw rises at time T1 when a certain time has elapsed from the time origin T0, and falls at time T3. The pulse of the bit line current Ib rises at time T2 and falls at time t4 with a delay from the pulse of the word line current Iw.
By providing a time difference in the current pulse as described above, the direction of the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 is rotated using the combined magnetic field of the current magnetic fields Hw and Hb as a rotating magnetic field. be able to.
The electric resistance R of the TMR element is low resistance (for example, information “0”) when the direction of the magnetization M1 of the first storage layer 116 and the magnetization M12 of the second magnetization fixed layer 114 are equal. When the direction of the magnetization M1 of the first storage layer 116 and the magnetization M12 of the second magnetization fixed layer 114 are antiparallel, the resistance becomes high (for example, information “1”).

First, at time T0, the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 114 are in an antiparallel state, and the angle formed by the two magnetizations M1 and M2 is 180 degrees. It has become.
Between time T1 and time T2, the angle formed by the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 is 180 degrees or less.
Between time T2 and time T3, the angle formed by the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 is an acute angle (90 degrees or less).
After time T3, the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 spin-flop, and return to the antiparallel state again after time T4. At this time, the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 are reversed in direction with respect to the initial state.

Next, FIG. 12 shows an example of a current pulse, a time change in the magnetization direction of each storage layer, and a time change in the electrical resistance of the TMR element in the No switching operation.
In this example, the pulse of the word line current Iw is in the opposite direction to that in FIG. The pulse of the bit line current Ib is the same as in FIG.

The pulse of the word line current Iw rises at time T1 when a certain time has elapsed from time T0 at the time origin, and falls at time T3. The pulse of the bit line current Ib rises at time T2 and falls at time t4 with a delay from the pulse of the word line current Iw.
By providing a time difference in the current pulse as described above, the direction of the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 is rotated using the combined magnetic field of the current magnetic fields Hw and Hb as a rotating magnetic field. be able to.

First, at time T0, the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 114 are in an antiparallel state, and the angle formed by the two magnetizations M1 and M2 is 180 degrees. It has become.
Between time T1 and time T2, the angle formed by the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 is 180 degrees or less.
In this case, between time T2 and time T3, the direction of the rotating magnetic field formed by the word line current magnetic field Hw and the bit line current magnetic field Hb is the direction of the easy axis of magnetization (positive or negative) of the magnetic memory element 101. Spin flopping does not occur because it does not face any direction. As a result, after time T4, the magnetization state does not change with respect to the initial state.

Next, examples of the current pulse, the time change of the magnetization direction of each storage layer, and the time change of the electric resistance of the TMR element in the direct operation are shown in FIGS. 13 and 14, respectively.
In the example shown in FIG. 13, all current pulses are in the same direction as in FIG. On the other hand, in the example shown in FIG. 14, the current pulses are all directed in the direction opposite to that in FIG.

13 and 14, the pulse of the word line current Iw rises at time T1 when a certain time has elapsed from time T0 at the time origin, and falls at time T3. The pulse of the bit line current Ib rises at time T2 and falls at time t4 with a delay from the pulse of the word line current Iw.
By providing a time difference in the current pulse as described above, the direction of the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 is rotated using the combined magnetic field of the current magnetic fields Hw and Hb as a rotating magnetic field. be able to.

First, at time T0, the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 114 are in an antiparallel state, and the angle formed by the two magnetizations M1 and M2 is 180 degrees. It has become.
From time T1 to time T2, spin flopping occurs, and the angle formed by the magnetization M1 of the first memory layer 116 and the magnetization M2 of the second memory layer 118 is 90 degrees or less.
Between time T2 and time T3, the directions of the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 are substantially the same, and the word line current magnetic field Hw and the bit line current are aligned. The direction of the rotating magnetic field formed by the magnetic field Hb is almost equal.
After time T3, the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118 spin-flop and return to the antiparallel state again, but the magnetization state does not depend on the initial state.

  Next, FIG. 15 shows a magnetization rotation mode diagram showing the respective occurrence states of the three types of magnetization rotation operations when the amplitude and direction of the word line current magnetic field Hw and the bit line current magnetic field Hb are changed.

As shown in FIG. 15, if the combined magnetic field of the bit line current magnetic field Hb and the word line current magnetic field Hw is equal to or less than the spin flopping magnetic field Hsf, the entire region is the region 81 of the No switching operation. The second quadrant and the fourth quadrant, in which the combined magnetic field of the bit line current magnetic field Hb and the word line current magnetic field Hw is other than the easy axis direction, are also generally No switching operation regions 81.
On the other hand, the area where the combined magnetic field of the bit line current magnetic field Hb and the word line current magnetic field Hw exceeds the saturation magnetic field Hsat often becomes the area 82 of the Direct operation.
The combined magnetic field of the bit line current magnetic field Hb and the word line current magnetic field Hw is not less than the spin flopping magnetic field Hsf and less than the saturation magnetic field Hsat, and the range belonging to the first quadrant and the third quadrant is the Toggle operation region 80. Can be expected.

  If there is an asymmetry in the two stable states (↑ ↓ and ↓ ↑) formed by the magnetization M1 of the first storage layer 116 and the magnetization M2 of the second storage layer 118, the Toggle operation region 80 and No switching are used. A Direct operation region may appear at the boundary of the operation region 81.

  In a memory cell group arranged in a matrix, in order to selectively reverse magnetization of only a specific memory cell arranged at the intersection of a word line and a bit line, the word line and bit line to which the selected memory cell belongs Current is passed through.

At this time, the combined magnetic field applied to the selected memory cell needs to be included in the range of the region 80 of the Toggle operation or the region 82 of the Direct operation.
On the other hand, in order to avoid the magnetization reversal of the unselected memory cells sharing the word line or the bit line, the combined magnetic field applied to the unselected memory cells is included in the range of the region 81 of the No switching operation. It is necessary to be.

Wang et al., IEEE Trans.Magn., 1997, Vol.33, p.4498 J.M.Daughton, Thin Solid Films, 1992, vol.216, p.162-168 D.D.Tang et al., IEDM Technical Digest, 1997, p.995-997 R. Meservey et al., Pysics Reports, 1994, vol.238, p.214-217 T. Miyazaki et al., J. Magnetism & Magnetic Material, 1995, vol. 139, L231 JP 10-116490 A US Patent Application Publication No. 2003/0072174

  As described above, in the conventional configuration of the MRAM using the switching characteristic, bit information is recorded by using two or more ferromagnetic layers as the storage layer 103.

  However, in the conventional configuration of the MRAM using the switching characteristics described above, the spin flopping magnetic field is large because two or more ferromagnetic layers of these storage layers are antiferromagnetically coupled or magnetostatically coupled between the layers. There is a problem of becoming.

  The magnitude of this spin flopping magnetic field determines the lower threshold value of the current that flows in the bit line and word line that is necessary to reverse the magnetization of the storage layer. Therefore, the power consumption required for recording increases.

  Therefore, for example, in order to apply MRAM to a portable device with large restrictions on power consumption or to make a memory cell finer, this spin flopping magnetic field is reduced and magnetization is reversed at a lower current. Need to be possible.

  In order to solve the above-described problem, the present invention provides a magnetic memory element and a magnetic memory having a configuration capable of reducing power consumption required for recording information.

  In the magnetic storage element of the present invention, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization direction is fixed to the storage layer via the nonmagnetic layer. A fixed layer is arranged, the fixed magnetization layer is composed of a plurality of magnetic layers, and the saturation magnetization and film thickness of each magnetic layer of the fixed magnetization layer are selected so that a magnetic pole magnetic field is generated from the fixed magnetization layer It is.

According to the configuration of the magnetic storage element of the present invention described above, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization of the storage layer is separated from the storage layer via the nonmagnetic layer. A magnetization pinned layer having a fixed orientation is arranged, the magnetization pinned layer is composed of a plurality of magnetic layers, and a saturation magnetization and a film thickness of each magnetic layer of the magnetization pinned layer are generated so that a magnetic pole magnetic field is generated from the magnetization pinned layer. Is selected, it is possible to generate a magnetic pole magnetic field from the magnetization fixed layer and shift the spin flopping magnetic field to the low magnetic field side.
This reduces the threshold value of the current magnetic field (word line current magnetic field and bit line current magnetic field) required for recording information by reversing the magnetization direction of each magnetic layer of the storage layer. Thus, the amount of current required for recording information can be reduced.

  In the magnetic memory of the present invention, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization direction is fixed to the storage layer via the nonmagnetic layer. Magnetic memory in which the saturation magnetization and film thickness of each magnetic layer of the fixed magnetization layer are selected so that the fixed magnetization layer is composed of a plurality of magnetic layers and generates a magnetic pole magnetic field from the fixed magnetization layer An element, a first wiring and a second wiring intersecting each other are provided, and magnetic storage elements are respectively disposed in the vicinity of intersections where the first wiring and the second wiring intersect.

According to the above-described configuration of the magnetic memory of the present invention, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization direction is directed to the storage layer via the nonmagnetic layer. The fixed magnetization layer and the thickness of each magnetic layer of the fixed magnetization layer are arranged such that the fixed magnetization layer includes a plurality of magnetic layers, and generates a magnetic pole magnetic field from the fixed magnetization layer. The selected magnetic memory element, a first wiring and a second wiring intersecting with each other, and the magnetic memory element is disposed in the vicinity of the intersection where the first wiring and the second wiring intersect. Thus, it is possible to apply a magnetic field (current magnetic field) to the magnetic memory element by flowing a current through the first wiring and the second wiring, and the direction of magnetization of each magnetic layer of the memory layer by this magnetic field. It is possible to record information by changing .
In particular, the saturation magnetization and the film thickness of each magnetic layer of the magnetization fixed layer are selected so that the magnetic storage element is composed of a plurality of magnetic layers and generates a magnetic pole magnetic field from the magnetization fixed layer. As described above, it is possible to generate a magnetic pole magnetic field from the magnetization fixed layer and shift the spin flopping magnetic field to the low magnetic field side as described above, and the amount of current required for recording information Can be reduced.

In the magnetic memory element of the present invention and the magnetic memory of the present invention, the fixed magnetization layer may be composed of two magnetic layers having different products of saturation magnetization and film thickness.
With such a configuration, the product of the saturation magnetization and the film thickness of the two magnetic layers of the magnetization fixed layer is different, so that a magnetic pole magnetic field can be generated from the magnetization fixed layer.

In the magnetic memory element of the present invention and the magnetic memory of the present invention, the two magnetic layers are a magnetic layer having a saturation magnetization M1 and a film thickness t1, and a magnetic layer having a saturation magnetization M2 and a film thickness t2. It is also possible to adopt a configuration satisfying the condition of | M1 · t1−M2 · t2 | / | M1 · t1 + M2 · t2 |> 0.1.
With such a configuration, the difference between the product of the saturation magnetization and the film thickness of the two magnetic layers of the magnetization fixed layer is relatively large, and a magnetic pole magnetic field sufficient to reduce the spin-flopping magnetic field is generated. Can be made.

Further, in the magnetic memory element of the present invention and the magnetic memory of the present invention, the magnetization fixed layer and the other magnetization fixed layer are arranged via the nonmagnetic layer with the storage layer interposed therebetween. Is also possible.
In this configuration, the other magnetization fixed layer is composed of a plurality of magnetic layers, and the saturation magnetization and film thickness of each magnetic layer are selected so that a magnetic pole magnetic field is generated from the other magnetization fixed layer. It is also possible to have a configuration. With this configuration, a magnetic pole magnetic field is generated from each of the magnetization fixed layer and the other magnetization fixed layer sandwiching the storage layer, and the spin flopping magnetic field can be reduced.

In the magnetic memory element of the present invention and the magnetic memory of the present invention, the two magnetic layers of the other fixed magnetization layer are a magnetic layer having a saturation magnetization M3 and a film thickness t3, and a saturation magnetization M4 and a film. The magnetic layer may have a thickness t4, and may satisfy the condition of | M3 · t3−M4 · t4 | / | M3 · t3 + M4 · t4 |> 0.1.
With this configuration, the difference between the product of the saturation magnetization and the film thickness of the two magnetic layers of the other magnetization fixed layer is relatively large, and the spin flopping magnetic field is reduced from the other magnetization fixed layer. It is possible to generate a sufficient magnetic pole magnetic field.

  In the magnetic storage element of the present invention, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization direction is fixed to the storage layer via the nonmagnetic layer. A pinned layer is disposed, and a magnetization pinned layer and another magnetization pinned layer are arranged via a nonmagnetic layer with a storage layer interposed therebetween, and the magnetization pinned layer and the other magnetization pinned layer are each composed of one magnetic layer. It consists of layers.

According to the configuration of the magnetic storage element of the present invention described above, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization of the storage layer via the nonmagnetic layer A magnetization pinned layer with a fixed orientation is arranged, and a magnetization pinned layer and another magnetization pinned layer are arranged via a nonmagnetic layer with the storage layer interposed therebetween, and the magnetization pinned layer and other magnetization pinned layers are arranged Each of the magnetic pinned layers and the other pinned magnetic layers can generate a magnetic pole magnetic field from each magnetic layer, and these magnetic pole magnetic fields can generate a spin flopping magnetic field. It can be shifted to the low magnetic field side.
This reduces the threshold value of the current magnetic field (word line current magnetic field and bit line current magnetic field) required for recording information by reversing the magnetization direction of each magnetic layer of the storage layer. Thus, the amount of current required for recording information can be reduced.

  In the magnetic memory of the present invention, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization direction is fixed to the storage layer via the nonmagnetic layer. The magnetic pinned layer and the other magnetic pinned layer are arranged via nonmagnetic layers, respectively, and the magnetic pinned layer and the other magnetic pinned layer are each one magnetic layer. Comprising a magnetic memory element comprising: a first wiring and a second wiring intersecting with each other, each having a magnetic memory element disposed near an intersection where the first wiring and the second wiring intersect It is.

According to the above-described configuration of the magnetic memory of the present invention, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization direction is directed to the storage layer via the nonmagnetic layer. Is fixed, and the fixed magnetization layer and the other fixed magnetization layer are respectively disposed via the nonmagnetic layer with the storage layer interposed therebetween, and the fixed magnetization layer and the other fixed magnetization layer are Each of the magnetic layers is composed of one magnetic layer, so that a magnetic field (current magnetic field) can be applied to the magnetic memory element by flowing a current through the first wiring and the second wiring. Information can be recorded by changing the magnetization direction of each magnetic layer.
In particular, in the magnetic storage element, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization direction is fixed to the storage layer via the nonmagnetic layer. A magnetization fixed layer is disposed, and a magnetization fixed layer and another magnetization fixed layer are disposed via a nonmagnetic layer with a storage layer interposed therebetween, and each of the magnetization fixed layer and the other magnetization fixed layer includes one layer. Due to the configuration composed of the magnetic layer, as described above, in the magnetization fixed layer and the other magnetization fixed layer, it is possible to generate a magnetic pole magnetic field from each of the magnetic layers. The spin flopping magnetic field can be shifted to the low magnetic field side, and the amount of current required for recording information can be reduced.

  In the magnetic storage element of the present invention, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization direction is fixed to the storage layer via the nonmagnetic layer. A pinned layer is disposed, the pinned magnetization layer is composed of two magnetic layers, and one of the magnetic layers is formed in a larger pattern in the direction of the easy magnetization axis than the other magnetic layer.

According to the configuration of the magnetic storage element of the present invention described above, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization of the storage layer is separated from the storage layer via the nonmagnetic layer. A magnetization fixed layer having a fixed orientation is arranged, the magnetization fixed layer is composed of two magnetic layers, and one magnetic layer is formed in a pattern that is larger in the direction of the easy axis than the other magnetic layer, Since the saturation magnetization of one magnetic layer is larger than that of the other magnetic layer, the generation of the magnetic field in the hard axis direction from the pinned layer is suppressed, and the magnetic field in the easy axis direction from the pinned layer is suppressed. Can be generated.
This magnetic pole magnetic field in the easy axis direction can shift the spin flopping magnetic field to the low magnetic field side.
This reduces the threshold value of the current magnetic field (word line current magnetic field and bit line current magnetic field) required for recording information by reversing the magnetization direction of each magnetic layer of the storage layer. Thus, the amount of current required for recording information can be reduced.
Further, by suppressing the generation of the magnetic pole magnetic field in the hard axis direction, the magnetization of each magnetic layer of the storage layer changes to a specific direction and the memory of the original state is lost (the aforementioned Direct operation) Can be suppressed.

  In the magnetic memory of the present invention, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization direction is fixed to the storage layer via the nonmagnetic layer. A magnetic memory element in which a layer is disposed, the magnetization fixed layer is composed of two magnetic layers, and one magnetic layer is formed in a pattern larger in the direction of the easy axis than the other magnetic layer, And a second wiring, and a magnetic memory element is disposed in the vicinity of the intersection where the first wiring and the second wiring intersect.

According to the above-described configuration of the magnetic memory of the present invention, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization direction is directed to the storage layer via the nonmagnetic layer. A magnetic pinned layer in which a pinned layer is arranged, the pinned magnetic layer is composed of two magnetic layers, and one magnetic layer is formed in a pattern larger in the direction of the easy axis than the other magnetic layer; The first wiring and the second wiring intersecting each other, and magnetic storage elements are respectively arranged in the vicinity of the intersection where the first wiring and the second wiring intersect, whereby the first wiring It is possible to apply a magnetic field (current magnetic field) to the magnetic memory element by passing a current through the second wiring, and record information by changing the magnetization direction of each magnetic layer of the memory layer by this magnetic field. It is possible.
In particular, in the magnetic storage element, the storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers, and the magnetization direction is fixed to the storage layer via the nonmagnetic layer. The magnetization pinned layer is arranged, the magnetization pinned layer is composed of two magnetic layers, and one of the magnetic layers is formed in a larger pattern in the direction of the easy magnetization axis than the other magnetic layer, As described above, a magnetic pole magnetic field in the easy axis direction can be generated from the magnetization fixed layer, and the spin flopping magnetic field can be shifted to the low magnetic field side, thereby reducing the amount of current required for recording information. It becomes possible. Further, the generation of the magnetic pole magnetic field in the hard axis direction can be suppressed, and the expansion of the direct operation region can be suppressed.

According to the present invention described above, a magnetic pole magnetic field can be generated from the magnetization fixed layer, and the spin flopping magnetic field can be shifted to the low magnetic field side, so that the amount of current required for information recording can be reduced. Therefore, it becomes possible to record information with a current amount lower than that in the prior art.
Accordingly, it is possible to reduce power consumption required for recording information.

In addition, according to the present invention, it is possible to easily reduce the size of the magnetic memory and increase the storage capacity by miniaturizing the magnetic storage elements constituting the magnetic memory.
Further, since it becomes possible to reduce the amount of current required for recording information, it is possible to reduce the occurrence of electron migration breaks in the wiring through which the recording current flows, thereby improving the reliability. be able to.

FIG. 1 shows a schematic configuration diagram (schematic cross-sectional view) of an MRAM using switching characteristics as an embodiment of the present invention.
Also in this embodiment, a selection MOS transistor is used for reading out a memory cell, as in the conventional configuration shown in FIG.

First, the structure of the magnetic memory element 1 which comprises the memory cell of MRAM is demonstrated.
The two magnetic layers of the first magnetization fixed layer 12 and the second magnetization fixed layer 14 are disposed via the nonmagnetic layer 13 and thus are antiferromagnetically coupled. Furthermore, the first magnetization fixed layer 12 is disposed in contact with the antiferromagnetic layer 11 and has a strong unidirectional magnetic anisotropy due to exchange interaction acting between these layers. The fixed layer 2 is constituted by these four layers 11, 12, 13, and 14.
The two magnetic layers of the first storage layer 16 and the second storage layer 18 are disposed via the nonmagnetic layer 17 and thus are antiferromagnetically coupled. The first storage layer 16 and the second storage layer 18 are configured such that the directions of the magnetizations M1 and M2 rotate relatively easily. These three layers 16, 17 and 18 constitute a storage layer (free layer) 3.
A tunnel insulating layer 15 is formed between the second magnetization fixed layer 14 and the first storage layer 16, that is, between the fixed layer 2 and the storage layer (free layer) 3. The tunnel insulating layer 15 functions to cut the magnetic coupling between the upper and lower magnetic layers 16 and 14 and to flow a tunnel current. Thus, a TMR (Tunneling Magnetoresistance) element is formed by the fixed layer 2 in which the magnetization direction of the magnetic layer is fixed, the tunnel insulating layer 15, and the storage layer (free layer) 3 capable of changing the magnetization direction. Is configured.

A top coat film 19 is formed on the second memory layer 18. The topcoat film 19 has a role of preventing mutual diffusion with the wiring (bit line) 6 connected to the magnetic memory element 1, reducing contact resistance, and preventing oxidation of the second memory layer 18.
A base film 10 is formed under the antiferromagnetic layer 11. The base film 10 has an effect of increasing the crystallinity of the layer stacked above.

The first and second magnetization fixed layers 12 and 14 and the first and second storage layers 16 and 18 are made of, for example, a ferromagnetic material mainly composed of nickel, iron, cobalt, or an alloy thereof. Used.
As a material of the nonmagnetic layers 13 and 17, for example, tantalum, chromium, ruthenium or the like can be used.
As a material of the antiferromagnetic layer 11, for example, a manganese alloy such as iron, nickel, platinum, iridium, and rhodium, cobalt, nickel oxide, or the like can be used.
For the base film 10, for example, chromium, tantalum or the like can be used.
For the top coat film 19, for example, a material such as copper, tantalum, or TiN can be used.

These magnetic layers 12, 14, 16, and 18 and conductor films 10, 13, 17, and 19 are mainly formed by sputtering.
The tunnel insulating layer 15 can be obtained by oxidizing or nitriding a metal film formed by sputtering.

  The above-described layers 11 to 18, the base film 10 and the top coat film 19 constitute the magnetic memory element 1 made of a TMR element.

A selection MOS transistor 31 is formed in the silicon substrate 30, and an extraction electrode 9 is formed on one diffusion layer 33 of the selection MOS transistor 31 via a connection plug 8. A base film 10 of the magnetic memory element 1 is connected on the extraction electrode 9. Although not shown, the other diffusion layer 32 of the selection MOS transistor 31 is connected to a sense line via a connection plug. The gate 30 of the selection MOS transistor is connected to the selection signal line.
The top coat film 19 of the magnetic memory element 1 is connected to the bit line (BL) 6 thereon. A write word line (WL) 5 is arranged below the magnetic memory element 101 via an insulating film.

  In the steady state, the magnetization M1 of the first storage layer 16 and the magnetization M2 of the second storage layer 18 are generally in an antiparallel state (a state in which the directions are opposite). Similarly, due to strong antiferromagnetic coupling through the nonmagnetic layer 13, the magnetization M11 of the first magnetization fixed layer 12 and the magnetization M12 of the second magnetization fixed layer 14 are in a substantially complete antiparallel state.

In the present embodiment, in particular, the saturation of the first magnetization fixed layer 12 and the second magnetization fixed layer 14 is made by changing the thicknesses of the two magnetization fixed layers 12 and 14 constituting the fixed layer 2. The magnetic memory element 1 is configured so that the magnetization film thickness product (M × t) is different. Specifically, the second magnetization fixed layer 14 is formed thicker than the first magnetization fixed layer 12.
Thereby, as will be described later, the spin flopping magnetic field Hsf can be reduced as compared with the conventional configuration shown in FIG.

In a magnetic memory element of an MRAM, when the fixed layer is composed of two magnetization fixed layers, generally, the two magnetization fixed layers constituting the fixed layer are made of the same magnetic material and have a film thickness. It is set as equal composition. For this reason, the saturation magnetization film thickness product (M × t) of the two magnetization fixed layers constituting the fixed layer is equal.
In the conventional configuration shown in FIG. 8, the saturation magnetization film thickness product (first magnetization fixed layer 112 (saturation magnetization M11 / film thickness t1) and second magnetization fixed layer 114 (saturation magnetization M12 / film thickness t2) ( M × t) are equal.

By the way, in the MRAM using the switching characteristics, since the above-described Toggle operation is based on the principle of magnetization reversal, it is not necessary to use all the quadrants of the magnetization rotation mode diagram shown in FIG.
In the magnetization rotation mode diagram shown in FIG. 15, the range is included in either the first quadrant or the third quadrant, and the amplitude of the bit line current pulse or the word line current pulse is adjusted so as to enter the region 80 of the Toggle operation. For example, a desired operation can be performed in the storage layer 3 of the magnetic storage element 1.

In order to reduce the spin flopping magnetic field Hsf, which is the cause of preventing the reduction of the word line current and the bit line current, the magnetization curve shown in FIG. 10 is shifted on the horizontal magnetic field axis H. It is effective to make the spin flopping magnetic field Hsf as close to the origin as possible.
Since the spin flopping magnetic field Hsf itself exists on both the positive side and the negative side of the magnetic field axis H, the magnetization rotation mode diagram of FIG. The same result can be obtained by moving to either the quadrant side.

  Therefore, in the present embodiment, for the purpose of shifting the spin flopping magnetic field Hsf to the low magnetic field side, the film thicknesses of the first magnetization fixed layer 12 and the second magnetization fixed layer 14 are made different to each other. The saturation magnetic film thickness product (M × t) of the fixed layers 12 and 14 is broken, and a magnetic pole magnetic field is generated from the fixed layer 2. With this magnetic pole magnetic field from the fixed layer 2, the spin flopping magnetic field Hsf can be shifted to the low magnetic field side.

In order to sufficiently obtain the effect of reducing the current required for the magnetization reversal, the first magnetization fixed layer 12 having the saturation magnetization M11 and the thickness t1 and the second magnetization t2 having the saturation magnetization M12 and the thickness t2. In the magnetization fixed layer 14,
| M11 · t1−M12 · t2 | / | M11 · t1 + M12 · t2 |> 0.1 (1)
It is desirable to satisfy the following conditions.

FIG. 2 shows a schematic plan view of the MRAM shown in FIG.
The magnetic memory element 1 has an elliptical planar shape, similar to the magnetic memory element 101 of FIG.
There is an easy magnetization axis 60 in the major axis direction of the ellipse, a hard magnetization axis 61 in the minor axis direction of the ellipse, and the easy magnetization axis 60 and the hard magnetization axis 61 are orthogonal to each other.
Further, the bit line (BL) 6 and the word line (WL) 5 have a constant angle α (substantially orthogonal). The magnetic memory element 1 is disposed at the intersection of the word line 5 and the bit line 6 such that the easy axis 60 has an inclination angle θ (0 <θ <90 °) with respect to the word line 5.

  In the memory cell having this configuration, when information is recorded in the storage layer 3 of the magnetic storage element 1, in order to reverse the directions of the magnetization M1 of the first storage layer 16 and the magnetization M2 of the second storage layer 18 The bit current Ib and the word line current Iw are supplied to the bit line 6 and the word line 5, respectively. The bit line current Ib and the word line current Iw induce a bit line current magnetic field Hb and a word line current magnetic field Hw, respectively. The combined magnetic field of the word line current magnetic field Hw and the bit line current magnetic field Hb forms a rotating magnetic field that rotates clockwise or counterclockwise, as will be described later.

  When reading information recorded in the storage layer 3 of the magnetic storage element 1, a voltage is applied between the bit line 6 and the sense line connected to the diffusion layer 32 of the selection MOS transistor 31. By turning on the gate 7 of the selection MOS transistor 31, a current flows in the film thickness direction of the magnetic memory element 1. Thus, the direction of magnetization of the magnetic layer of the storage layer 3 is detected using the tunnel magnetoresistance effect in the magnetic layers (the second magnetization fixed layer 14 and the first storage layer 16) sandwiching the tunnel insulating layer 15. As a result, the information recorded in the storage layer 3 can be read out.

Then, by using the memory cell having the configuration shown in FIG. 1, the magnetic memory element 1 is arranged at each intersection with respect to a large number of word lines (WL) 5 and bit lines (BL) 6, thereby A magnetic memory (magnetic storage device) having a memory cell and a large storage capacity can be configured.
When the magnetic memory is configured as described above, in order to record information in the storage layer 3 of the magnetic storage element 1 of a certain memory cell, it is possible to use a large number of word lines 5 and bit lines 6 corresponding to the recording memory cell. One word line 5 and one bit line 6 are selected, and a current is applied to the word line 5 and the bit line 6 to apply current magnetic fields Hw and Hb to the magnetic memory element 1 of the memory cell to be recorded. . As a result, a rotating magnetic field is applied to the storage layer 3 of the magnetic storage element 1 of the memory cell, and in the storage layer 3, the magnetization M1 of the first storage layer 16 and the magnetization M2 of the second storage layer 18 are reversed ( Information is written (recorded) by the Toggle operation).
On the other hand, since at least one of the word line 5 and the bit line 6 is not selected in the memory cell that does not record information, the magnetization M1 of the first storage layer 16 and the magnetization M2 of the second storage layer 18 are reversed. Information that is already recorded in the storage layer 3 is held because a rotating magnetic field sufficient for (Toggles operation) is not applied and information is not written (recorded).

Here, the effect of improving the magnetization rotation mode obtained by the present embodiment was examined.
The film thickness of the nonmagnetic layer 13 is configured such that the fixed layer 2 of the magnetic memory element 1, CoFe is used for the first magnetization fixed layer 12 and the second magnetization fixed layer 14, and Ru is used for the nonmagnetic layer 13. Is fixed at 0.8 nm, and the film thickness t1 of the first magnetization fixed layer 12 and the film thickness t2 of the second magnetization fixed layer 14 are changed under t1 + t2 = 4.0 nm, respectively. The distribution of magnetization rotation mode was investigated.
The results are shown in FIGS. 3A to 3D. FIG. 3A shows a case where t1 = 2.2 nm and t2 = 1.8 nm (in contrast to FIG. 1, the second magnetization fixed layer 14 is slightly thinner than the first magnetization fixed layer 12), and FIG. FIG. 3C shows the case of t1 = 1.0 nm and t2 = 3.0 nm, and FIG. 3D shows the case of t1 = 0.5 nm and t2 = 3.5 nm. Show.
In FIGS. 3A to 3D, the range of the magnetic field is 0 to 100 Oe, which is smaller than that in FIG. 15, and therefore the area of the Direct operation when the magnetic field is large does not appear.

As shown in FIGS. 3A to 3D, when the difference in film thickness between the first magnetization fixed layer 12 and the second magnetization fixed layer 14 is increased and the balance is lost, the Toggle operation region 80 moves to the low magnetic field side. I can see that
In FIG. 3A, it can be seen that the threshold value in the region 80 of the Toggle operation is as high as about 60 Oe, whereas in FIG. 3D, it is reduced to about 20 Oe.
That is, it can be seen that the current amplitude can be reduced to 1/3 by moving the threshold value spin flopping magnetic field Hsf to the low magnetic field side. This indicates that the power consumption can be reduced to 1/9.

  3A to 3D, since the two stable states described above formed by the magnetizations M1 and M2 of the first storage layer 16 and the second storage layer 18 of the storage layer 3 are asymmetric. The Direct operation region 82 appears at the boundary between the Toggle operation region 80 and the No switching operation region 81. In particular, as the second magnetization fixed layer 14 on the side closer to the storage layer 3 is thickened, the direct operation region 82 at this boundary becomes wider.

According to the configuration of the present embodiment described above, the first magnetic pinned layer 12 and the second magnetic pinned layer 14 constituting the pinned layer 2 constitute the magnetic memory element 1 having different thicknesses. Since the saturation magnetization film thickness product of the first magnetization pinned layer 12 and the second magnetization pinned layer 14 is different, a magnetic pole magnetic field can be generated from the pinned layer 2, and the action of this magnetic pole magnetic field causes spin flopping. The magnetic field Hsf can be shifted to the low magnetic field side.
As a result, the current magnetic field (word line current magnetic field or bit line current magnetic field) necessary for recording information by reversing the directions of the magnetizations M1 and M2 of the storage layers 16 and 18 of the storage layer 3 is obtained. The threshold value can be reduced, and the amount of current required for recording information can be reduced.
Therefore, with the configuration of the present embodiment, it is possible to reduce power consumption required for recording information.

Further, as described above, in order to miniaturize the magnetic memory element, it is necessary to reduce the power consumption necessary for recording information. Therefore, the memory cell of the MRAM is configured by the configuration of this embodiment. It is possible to easily reduce the size of the MRAM and increase the storage capacity by miniaturizing the magnetic memory element 1.
Further, since it becomes possible to reduce the amount of current required for recording information, it is possible to reduce the occurrence of electron migration breaks in the wiring through which the recording current flows, thereby improving the reliability. be able to.

In the above-described embodiment, the film thickness t1 of the first magnetization fixed layer 12 and the film thickness t2 of the second magnetization fixed layer 14 are different from each other, but the saturation magnetization film thickness product is different. Even if the first magnetization fixed layer and the second magnetization fixed layer have different saturation magnetization, the saturation magnetization film thickness product is similarly varied, and the generated magnetic field generates the spin flopping magnetic field Hsf on the low magnetic field side. By shifting, it is possible to reduce the amount of current required for recording information. Thereby, it becomes possible to reduce the power consumption required for recording information.
In order to change the saturation magnetization of the two magnetization fixed layers, for example, it is conceivable to use different magnetic materials or have different alloy compositions.

  Similarly, even when the first magnetization pinned layer and the second magnetization pinned layer have different saturation magnetization and different film thicknesses, and thus have different saturation magnetization film thickness products, information recording is similarly performed. The effect of reducing the amount of current required for the is obtained.

  Next, as another embodiment of the present invention, a schematic configuration diagram (schematic cross-sectional view) of an MRAM using switching characteristics is shown in FIG.

In the present embodiment, in particular, the magnetic storage element 41 constituting the memory cell of the MRAM is provided with the fixed layer 4 also above the storage layer 3, and the storage layer 3 is formed by the lower fixed layer 2 and the upper fixed layer 4. The structure is sandwiched between top and bottom.
The upper fixed layer 4 is formed by stacking a third magnetization fixed layer 20, a nonmagnetic layer 21, a fourth magnetization fixed layer 22, and an antiferromagnetic layer 23. The magnetization M13 of the third magnetization fixed layer 20 and the magnetization M14 of the fourth magnetization fixed layer 22 are opposite to each other. Further, the magnetization M13 of the third magnetization fixed layer 20 of the fixed layer 4 is the same as the direction of the magnetization M11 of the first magnetization fixed layer 12 of the fixed layer 2.

  Further, a tunnel insulating layer 25 is provided between the storage layer 3 and the upper fixed layer 4, and a double magnetic tunnel is formed together with the tunnel insulating layer 18 between the storage layer 3 and the lower fixed layer 2. It is a resistance element.

In the lower fixed layer 2, the film thickness t 1 of the first magnetization fixed layer 12 and the film thickness t 2 of the second magnetization fixed layer 14 are different, as in the previous embodiment. In the present embodiment, the first magnetization fixed layer 12 is thicker (t1> t2).
Also in the upper fixed layer 4, the film thickness t3 of the third magnetization fixed layer 20 and the film thickness t4 of the fourth magnetization fixed layer 22 are different, and the third magnetization fixed layer 20 is thicker (t3> t4). It has become.

By configuring the magnetic memory element 41 in this manner, the lower fixed layer 2 and the upper fixed layer 4 have different saturation magnetization film thickness products of the two fixed magnetization layers, and the lower fixed layer 2 and The spin flopping magnetic field Hsf can be shifted to the low magnetic field side by the action of the magnetic pole magnetic field generated from the upper fixed layer 4.
Thereby, the current required to reverse the magnetizations M1 and M2 of the storage layers 16 and 18 of the storage layer 3 can be reduced.

In order to sufficiently obtain the effect of reducing the current required for the magnetization reversal, the third magnetization fixed layer 20 having the thickness t3 with the saturation magnetization M13 and the fourth magnetization fixed with the thickness t4 having the saturation magnetization M14. In layer 22,
| M13 · t3-M14 · t4 | / | M13 · t3 + M14 · t4 |> 0.1 (2)
It is desirable to satisfy the following conditions.
Further, as in the previous embodiment, it is desirable to satisfy the condition of the above-described formula (1).
Then, the magnetization fixed layers 12, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14 b, and 20 and 22 are preferably configured.

  Other configurations are the same as those of the previous embodiment, and thus the same reference numerals are given and redundant description is omitted.

According to the configuration of the present embodiment described above, in the lower fixed layer 2, the film thickness t 1 of the first magnetization fixed layer 12 and the film thickness t 2 of the second magnetization fixed layer 14 are different, and the upper fixed layer 4. In the lower fixed layer 2 and the upper fixed layer 4, the magnetic storage element 41 is configured such that the film thickness t 3 of the third magnetization fixed layer 20 and the film thickness t 4 of the fourth magnetization fixed layer 22 are different. Since the saturation magnetization film thickness products of the two magnetization fixed layers are different, the spin flopping magnetic field Hsf can be shifted to the low magnetic field side by the action of the magnetic pole magnetic field generated in each of the fixed layers 2 and 4.
As a result, the threshold value of the current magnetic field required for recording information by reversing the directions of the magnetizations M1 and M2 of the first storage layer 16 and the second storage layer 18 of the storage layer 3 is reduced. It is possible to reduce the amount of current required for recording information.
Therefore, with the configuration of the present embodiment, it is possible to reduce power consumption required for recording information.

  Further, it is possible to easily reduce the size of the MRAM and increase the storage capacity, thereby improving the reliability.

  Next, as still another embodiment of the present invention, a schematic configuration diagram (schematic cross-sectional view) of an MRAM using switching characteristics is shown in FIG.

In the present embodiment, similarly to the embodiment shown in FIG. 4, the fixed layer 4 is provided on the upper layer of the storage layer (free layer) 3, and the third magnetization fixed layer 20 constituting the upper fixed layer 4 is provided. The magnetic memory element 42 is configured so that the film thickness of the fourth magnetization fixed layer 22 is different.
Similarly to the previous embodiment shown in FIG. 4, the lower fixed layer 2 is different in the film thickness t1 of the first magnetization fixed layer 12 and the film thickness t2 of the second magnetization fixed layer 14. The first pinned magnetic layer 12 is thicker (t1> t2), and the upper pinned layer 4 has a film thickness t3 of the third pinned magnetic layer 20 and a film thickness t4 of the fourth pinned magnetic layer 22. In contrast, the third magnetization fixed layer 20 is thicker (t3> t4).

In the present embodiment, the nonmagnetic layer 19 is formed between the storage layer 3 and the upper fixed layer 4.
Thereby, compared with the case where two tunnel insulating layers are provided as in the embodiment shown in FIG. 4, the resistance of the entire magnetic memory element can be lowered.

  By configuring the magnetic memory element 42 as described above, the spin flopping magnetic field Hsf is generated by the action of the magnetic pole magnetic field generated from the lower fixed layer 2 and the upper fixed layer 4 as in the embodiment shown in FIG. Can be shifted to the low magnetic field side, whereby the current required to reverse the magnetizations M1 and M2 of the storage layers 16 and 18 of the storage layer 3 can be reduced.

Also in the present embodiment, in order to sufficiently obtain the effect of reducing the current required for the magnetization reversal, it is desirable that the conditions of the above-described formula (1) and the formula (2) are satisfied.
Then, the magnetization fixed layers 12, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14, 14 b, and 20 and 22 are preferably configured.

  Since the other configuration is the same as that of the embodiment shown in FIG. 4, the same reference numerals are given and redundant description is omitted.

According to the configuration of the present embodiment described above, the film thickness t1 of the first magnetization fixed layer 12 and the second magnetization fixed layer in the lower fixed layer 2 as in the previous embodiment shown in FIG. 14 is different from the film thickness t2 in FIG. 14 in that the thickness t3 of the third magnetization fixed layer 20 and the film thickness t4 of the fourth magnetization fixed layer 22 are different in the upper fixed layer 4. The spin flopping magnetic field Hsf can be shifted to the low magnetic field side by the action of the magnetic pole magnetic field generated respectively in the lower fixed layer 2 and the upper fixed layer 4.
As a result, it is possible to reduce the amount of current required for recording information, and it is possible to reduce the power consumption required for recording information.
Further, it is possible to easily reduce the size of the MRAM and increase the storage capacity, thereby improving the reliability.

In each of the embodiments shown in FIGS. 4 and 5, the first magnetization fixed layer 12 and the second magnetization fixed layer 14 of the lower fixed layer 2 and the third magnetization of the upper fixed layer 4 are used. Both the fixed layer 20 and the fourth magnetization fixed layer 22 have different thicknesses.
On the other hand, the effect of the present invention can be obtained in the same manner even when the lower fixed layer 2 or the upper fixed layer 4 has a different thickness of the two magnetization fixed layers. .
Also, the effect of the present invention can be obtained in the same manner even if the saturation magnetization is changed instead of the configuration in which the film thickness is changed.

  Next, as another embodiment of the present invention, a schematic configuration diagram (schematic perspective view) of an MRAM using switching characteristics is shown in FIG. In FIG. 6, the bit line, the word line, and the selection MOS transistor are not shown, and only the magnetic memory element is illustrated.

In this embodiment, similarly to the magnetic memory element 41 shown in FIG. 4, the magnetic memory element 43 constituting the memory cell of the MRAM is provided with the fixed layer 4 above the memory layer 3, and the lower fixed layer. The memory layer 3 is sandwiched between the upper and lower fixed layers 4.
Further, similarly to the magnetic memory element 41 shown in FIG. 4, a tunnel insulating layer 25 is formed between the memory layer 3 and the upper fixed layer 4 to form a double magnetic tunnel resistance element.

Preferably, the lower tunnel insulating layer 15 and the upper tunnel insulating layer 25 have the same thickness.
Thereby, the action of the magnetic pole magnetic field from the lower fixed layer 2 to the storage layer 3 and the action of the magnetic pole magnetic field from the upper fixed layer 4 to the storage layer 3 can be made substantially the same.

  In the present embodiment, in particular, the magnetic layer of the lower pinned layer 2 is only one layer of the pinned magnetic layer 12, and the magnetic layer of the upper pinned layer 4 is only one layer of the pinned magnetic layer 20. It has become. Further, the storage layer 3 is composed of three magnetic layers of the first storage layer 16, the second storage layer 18, and the third storage layer 26. The third storage layer 26 is disposed on the second storage layer 18 via the nonmagnetic layer 19.

The magnetization M1 of the first storage layer 16, the magnetization M3 of the third storage layer 26, and the magnetization M2 of the second storage layer 18 are opposite to each other.
The direction of the magnetization M21 of the magnetization fixed layer 20 of the upper fixed layer 4 is the same as the direction of the magnetization M11 of the magnetization fixed layer 12 of the lower fixed layer 2.

By configuring the magnetization memory element 43 in this manner, the spin flopping magnetic field Hsf is generated by the action of the magnetic pole magnetic field generated from the magnetization fixed layer 12 of the lower fixed layer 2 and the magnetization fixed layer 20 of the upper fixed layer 4. Can be shifted to the low magnetic field side.
Thereby, the current required for reversing the magnetizations M1, M2, M3 of the storage layers 16, 18, 26 of the storage layer 3 can be reduced.

In addition, the first storage layer 16 having a saturation magnetization M16 and a thickness t16, the second storage layer 18 having a saturation magnetization M18 and a thickness t18, and the third storage layer having a saturation magnetization M26 and a thickness t26. 26,
| M18 · t18-M16 · t16-M26 · t26 | / | M16 · t16 + M18 · t18 + M26 · t26 | ≦ 0.1 (3)
It is desirable to satisfy the following conditions.

Further, in order not to excessively shift the region of the Toggle operation, a lower magnetization fixed layer 12 having a saturation magnetization M12 and a film thickness t12, and an upper magnetization fixed layer 24 having a saturation magnetization M20 and a film thickness t20, In each magnetic layer 16, 18, 26 of the storage layer (free layer) 3,
M12 · t12 + M20 · t20 | / | M16 · t16 + M18 · t18 + M26 · t26 | <1.0 (4)
It is desirable to satisfy the following conditions.

  Then, each magnetization fixed layer 12, 20 is strengthened so that the action of the magnetic pole magnetic field from the lower fixed layer 2 and the action of the magnetic pole magnetic field from the upper fixed layer 4 do not cancel each other but strengthen each other. It is desirable to configure.

According to the configuration of the above-described embodiment, each of the fixed layer 2 and the upper fixed layer 4 of the lower layer is configured by one magnetic layer (the fixed magnetization layer 12 and the fixed magnetization layer 20). The spin flopping magnetic field Hsf can be shifted to the low magnetic field side by the action of the magnetic pole field generated in the layers 2 and 4.
As a result, information is recorded by reversing the directions of the magnetizations M1, M2, and M3 of the magnetic layers of the storage layer 3 (the first storage layer 16, the second storage layer 18, and the third storage layer 26). Therefore, it is possible to reduce the threshold value of the current magnetic field that is necessary for this purpose, and it is possible to reduce the amount of current required for recording information.
Therefore, with the configuration of the present embodiment, it is possible to reduce power consumption required for recording information.

  Further, it is possible to easily reduce the size of the MRAM and increase the storage capacity, thereby improving the reliability.

  Furthermore, the magnitude of the leakage magnetic field induced from the lower fixed layer 2 to the storage layer 3 and the magnitude of the leakage magnetic field induced from the upper fixed layer 4 to the storage layer 3 are made substantially equal to each other. A symmetrical bias magnetic field can be applied to each of the magnetic layers 16, 18, and 26. Thereby, a favorable Toggle operation can be performed.

  In the present embodiment, similarly to the magnetic memory element 41 shown in FIG. 4, the tunnel insulating layer 25 is used as the tunnel insulating layer 25 between the memory layer (free layer) 3 and the upper fixed layer 4, thereby providing a double magnetic tunnel resistance element. However, a conductive nonmagnetic layer may be provided between the storage layer (free layer) 3 and the upper fixed layer 4 as in the magnetic storage element 42 shown in FIG.

Also in this case, it is preferable that the conductive nonmagnetic layer has the same thickness as that of the lower tunnel insulating layer.
Thereby, the action of the magnetic pole magnetic field from the lower fixed layer 2 to the storage layer 3 and the action of the magnetic pole magnetic field from the upper fixed layer 4 to the storage layer 3 can be made substantially the same.

  Next, as yet another embodiment of the present invention, a schematic configuration diagram (schematic perspective view) of an MRAM using switching characteristics is shown in FIG. In FIG. 7, the bit lines, the word lines, and the selection MOS transistors are not shown, and only the magnetic memory element is illustrated.

  In the present embodiment, in particular, compared to the pattern of the storage layer (free layer) 3, the pattern of a part of the fixed layer 2, specifically, the antiferromagnetic layer 11 and the first magnetization fixed layer 12. The magnetic memory element 51 is configured such that the pattern is enlarged in the easy magnetization axis direction.

  The magnetic memory element 51 having such a configuration is patterned so that only a part of the fixed layer 2 (the antiferromagnetic layer 11 and the first magnetization fixed layer 12) is exposed in the easy axis direction. Can be produced.

As described above, the word line current and the bit line current can be reduced by applying the magnetic pole magnetic field in the direction of the easy axis of magnetization of the memory element and shifting the spin flopping magnetic field to the low magnetic field side.
However, when a magnetic pole magnetic field is applied in the direction of the hard axis, an unnecessary direct operation region may be expanded.

  Therefore, as in the present embodiment, by performing patterning so that only a part of the fixed layer 2 is exposed in the direction of the easy axis of magnetization, it is possible to prevent the area of the Direct operation from expanding.

According to the configuration of the present embodiment described above, the pattern of the antiferromagnetic layer 11 and the first magnetization fixed layer 12 is larger in the easy axis direction than the pattern of the storage layer (free layer) 3. Compared with the pattern of the second magnetization fixed layer 14, the pattern of the first magnetization fixed layer 12 is larger in the direction of the easy axis of magnetization.
As a result, the saturation magnetization of the first magnetization fixed layer 12 becomes larger than the saturation magnetization of the second magnetization fixed layer 14, and the saturation magnetization film thickness product of the first magnetization fixed layer 12 and the second magnetization fixed layer 14. Is different.

  Accordingly, the saturation magnetization film thickness products of the two magnetization fixed layers 12 and 14 of the fixed layer 2 are different, and the pattern of the first magnetization fixed layer 12 is increased in the easy axis direction. Thus, a magnetic pole magnetic field can be generated to shift the spin flopping magnetic field Hsf to the low magnetic field side, and the effect of reducing the power consumption required for recording can be obtained as in the above-described embodiment.

  Further, as shown in FIG. 7, the two fixed magnetization layers 12 and 14 of the fixed layer 2 have the same pattern of the end portions in the hard axis direction, so that the magnetic pole magnetic field applied in the hard axis direction is kept small. Accordingly, it is possible to suppress the expansion of the area of the unnecessary Direct operation.

Then, similarly to each of the embodiments described above, a word line, a bit line, and a selection MOS transistor are provided for the magnetic memory element 51 of the present embodiment shown in FIG. 7 to constitute a memory cell. be able to.
Furthermore, a magnetic memory element (MRAM) can be configured by providing a magnetic memory element near each intersection of a large number of word lines and bit lines.

  In addition, with respect to the configuration of each of the above-described embodiments, the extraction electrode under the magnetic memory element may be formed of an antiferromagnetic material and may also be used as an antiferromagnetic layer.

In each of the above-described embodiments, a magnetic storage element composed of a TMR element is configured by providing a tunnel insulating layer between the storage layer 3 and the lower fixed layer 2, but instead of the tunnel insulating layer, A magnetic memory element composed of a GMR element may be formed by providing a nonmagnetic conductive layer.
Even when the present invention is applied to a case where a magnetic memory element composed of a GMR element is configured, the effect of the present invention can be obtained.

  The present invention is not limited to the above-described embodiment, and various other configurations can be taken without departing from the gist of the present invention.

It is a typical sectional view of MRAM using the switching characteristic of one embodiment of the present invention. It is the typical top view which looked at the MRAM of FIG. 1 from right above. A to D are diagrams for comparing distributions of magnetization rotation modes. It is a typical sectional view of MRAM using the switching characteristic of other embodiments of the present invention. It is a typical sectional view of MRAM using the switching characteristic of further another embodiment of the present invention. It is a typical sectional view of MRAM using the switching characteristic of another embodiment of the present invention. It is a typical perspective view of MRAM using the switching characteristic of further another embodiment of this invention. It is a typical sectional view of MRAM using a switching characteristic. It is the typical top view which looked at the MRAM of FIG. 8 from right above. 9 is an example of a magnetization curve when an external magnetic field is applied in the easy axis direction of the magnetic memory element of FIG. 8. It is a figure which shows an example of the time change of the electric current pulse, the magnetization direction of each memory | storage layer, and the electrical resistance of a TMR element in Toggle operation. It is a figure which shows an example of the time change of the electric current pulse, the magnetization direction of each memory | storage layer, and the electrical resistance of a TMR element in No switching operation. It is a figure which shows an example of the time change of the electric current pulse, the magnetization direction of each memory | storage layer, and the electrical resistance of a TMR element in a Direct operation | movement. It is a figure which shows an example of the time change of the electric current pulse, the magnetization direction of each memory | storage layer, and the electrical resistance of a TMR element in a Direct operation | movement. It is a figure which shows distribution of the magnetization rotation mode of the magnetic memory element of FIG.

Explanation of symbols

  1, 41, 42, 43, 51 Magnetic storage element, 2, 4 fixed layer, 3 storage layer (free layer), 5 word line, 6 bit line, 11 antiferromagnetic layer, 12 first magnetization fixed layer, 13 , 17 Nonmagnetic layer, 14 Second magnetization fixed layer, 15, 25 Tunnel insulating layer, 16 First storage layer, 18 Second storage layer, 20 Third magnetization fixed layer, 22 Fourth magnetization fixed layer , 30 Silicon substrate, 31 MOS transistor for selection

Claims (22)

The storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers,
A magnetization pinned layer in which the direction of magnetization is pinned is arranged with respect to the storage layer via a nonmagnetic layer,
The saturation magnetization and film thickness of each magnetic layer of the magnetization fixed layer are selected so that the magnetization fixed layer includes a plurality of magnetic layers and generates a magnetic pole magnetic field from the magnetization fixed layer. Magnetic storage element.   The magnetic memory element according to claim 1, wherein the magnetization fixed layer is composed of two magnetic layers having different products of saturation magnetization and film thickness.   The magnetic memory element according to claim 1, wherein the nonmagnetic layer is a tunnel insulating layer.   The magnetic memory element according to claim 1, wherein the magnetization fixed layer and the other magnetization fixed layer are arranged via a nonmagnetic layer with the storage layer interposed therebetween.   The magnetic memory element according to claim 4, wherein at least one of the nonmagnetic layers is a tunnel insulating layer.   The other magnetization fixed layer is composed of a plurality of magnetic layers, and the saturation magnetization and the film thickness of each of the magnetic layers are selected so that a magnetic pole magnetic field is generated from the other magnetization fixed layer. The magnetic memory element according to claim 4.   7. The magnetic memory element according to claim 6, wherein the other magnetization fixed layer is composed of two magnetic layers having different products of saturation magnetization and film thickness.   The two magnetic layers are composed of a magnetic layer having a saturation magnetization M1 and a film thickness t1, and a magnetic layer having a saturation magnetization M2 and a film thickness t2, and | M1 · t1−M2 · t2 | / | M1 · t1 + M2 3. The magnetic memory element according to claim 2, wherein a condition of t2 |> 0.1 is satisfied.   The two magnetic layers of the other magnetization fixed layer are composed of a magnetic layer having a saturation magnetization M3 and a film thickness t3, and a magnetic layer having a saturation magnetization M4 and a film thickness t4, and | M3 · t3−M4 · 8. The magnetic memory element according to claim 7, wherein a condition of t4 | / | M3 · t3 + M4 · t4 |> 0.1 is satisfied. The storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers,
A magnetization pinned layer in which the direction of magnetization is pinned is arranged with respect to the storage layer via a nonmagnetic layer,
The magnetization pinned layer and the other magnetization pinned layer are arranged via nonmagnetic layers, respectively, across the storage layer,
The magnetic pinned layer and the other pinned magnetic layer are each composed of one magnetic layer. The storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers,
A magnetization pinned layer in which the direction of magnetization is pinned is arranged with respect to the storage layer via a nonmagnetic layer,
The magnetic pinned layer is composed of two magnetic layers, and one magnetic layer is formed in a pattern that is larger in the direction of the easy magnetization than the other magnetic layer. The storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers,
A magnetization pinned layer in which the direction of magnetization is pinned is arranged with respect to the storage layer via a nonmagnetic layer,
A magnetic memory element in which the magnetization pinned layer is composed of a plurality of magnetic layers, and the saturation magnetization and the film thickness of each of the magnetization pinned layers are selected such that a magnetic pole magnetic field is generated from the magnetization pinned layer When,
A first wiring and a second wiring intersecting each other;
The magnetic memory, wherein each of the magnetic memory elements is disposed near an intersection where the first wiring and the second wiring intersect.   The magnetic memory according to claim 12, wherein the magnetization fixed layer of the magnetic memory element is composed of two magnetic layers having different products of saturation magnetization and film thickness.   13. The magnetic memory according to claim 12, wherein in the magnetic memory element, the nonmagnetic layer is a tunnel insulating layer.   13. The magnetic memory according to claim 12, wherein in the magnetic memory element, the magnetization fixed layer and another magnetization fixed layer are arranged via nonmagnetic layers with the storage layer interposed therebetween. .   16. The magnetic memory according to claim 15, wherein in the magnetic memory element, at least one of the nonmagnetic layers is a tunnel insulating layer.   In the magnetic memory element, the saturation magnetization and the film thickness of each of the magnetic layers are selected so that the other magnetization fixed layer includes a plurality of magnetic layers and generates a magnetic pole magnetic field from the other magnetization fixed layer. The magnetic memory according to claim 15, wherein the magnetic memory is provided.   18. The magnetic memory according to claim 17, wherein, in the magnetic memory element, the other magnetization fixed layer includes two magnetic layers having different products of saturation magnetization and film thickness.   In the magnetization fixed layer of the magnetic memory element, the two magnetic layers are composed of a magnetic layer having a saturation magnetization M1 and a film thickness t1, and a magnetic layer having a saturation magnetization M2 and a film thickness t2. The magnetic memory according to claim 13, wherein the condition of t 1 −M 2 · t 2 | / | M 1 · t 1 + M 2 · t 2 |> 0.1 is satisfied.   In the magnetic memory element, the two magnetic layers of the other magnetization fixed layer include a magnetic layer having a saturation magnetization M3 and a film thickness t3, and a magnetic layer having a saturation magnetization M4 and a film thickness t4. 19. The magnetic memory according to claim 18, wherein the condition of M3.t3-M4.t4 | / | M3.t3 + M4.t4 |> 0.1 is satisfied. The storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers,
A magnetization pinned layer in which the direction of magnetization is pinned is arranged with respect to the storage layer via a nonmagnetic layer,
The magnetization pinned layer and the other magnetization pinned layer are arranged via nonmagnetic layers, respectively, across the storage layer,
The magnetic pinned layer and the other magnetic pinned layer are each composed of one magnetic layer;
A first wiring and a second wiring intersecting each other;
The magnetic memory, wherein each of the magnetic memory elements is disposed near an intersection where the first wiring and the second wiring intersect. The storage layer that holds information according to the magnetization state of the magnetic material is composed of a plurality of magnetic layers,
A magnetization pinned layer in which the direction of magnetization is pinned is arranged with respect to the storage layer via a nonmagnetic layer,
The magnetic pinned layer is composed of two magnetic layers, and one magnetic layer is formed in a larger pattern in the direction of the easy axis than the other magnetic layer;
A first wiring and a second wiring intersecting each other;
The magnetic memory, wherein each of the magnetic memory elements is disposed near an intersection where the first wiring and the second wiring intersect.

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