Semiconductor memory device comprising magneto resistive element and its manufacturing method
A semiconductor memory device including a memory cell having a first ferromagnetic film, a tunnel barrier film formed on the first ferromagnetic film, and a second ferromagnetic film formed on the tunnel barrier film, the tunnel barrier film having a larger film thickness in its in-surface edge portion than in its in-surface central portion, a side wall insulating film formed so as to surround at least sides of the second ferromagnetic film, and an interlayer insulating film formed so as to cover the memory cell and the side wall insulating film.
This application is a divisional of and claims the benefit of priority under 35 U.S.C. § 120 from U.S. Ser. No. 11/109,675, filed Apr. 20, 2005, which claims the benefit of priority under 35 U.S.C. § 119 from prior Japanese Patent Applications No. 2003-080586, filed Mar. 24, 2003; and No. 2003-207564, filed Aug. 14, 2003, the entire contents of both of which are incorporated herein by reference.
BACKGROUND OF THE INVENTION1. Field of the Invention
The present invention relates to a semiconductor memory device and its fabricating method, e.g. a magneto resistive element provided in a magneto resistive random access memory (MRAM) and its peripheral structure.
2. Description of the Related Art
The MRAM is a general term for solid state memories which act as recorded information carriers utilizing the direction of magnetization of ferromagnetic material and which enable recorded information to be rewritten, retained, and read as required.
A memory cell in the MRAM normally has a structure in which a plurality of ferromagnetic materials are stacked together. Information is recorded by using binary information “1” and “0” to represent the relative arrangement of magnetizations of the plurality of ferromagnetic materials in the memory cell, i.e. to indicate whether the directions of the magnetization are parallel or antiparallel with one another. Recording information is written to the memory by using current magnetic fields to reverse the directions of magnetization of ferromagnetic materials of each memory cell.
The MRAM is perfectly nonvolatile and enables information to be rewritten 1015 times or more. Furthermore, the MRAM enables nondestructive reading and does not require any refresh operations. Accordingly, it enables a read cycle to be reduced. It is also resistant to radiations compared to charge accumulation type memory cells. Thus, the MRAM has a large number of advantages in terms of functions compared to conventional semiconductor memories using dielectrics. The degree of integration per unit area of the MRAM and the time required by the MRAM for a write or read are expected to be generally equivalent to those of a DRAM (Dynamic Random Access Memory). Accordingly, the non-volatility of the MRAM, its major characteristic, is expected to be utilized to use it as an external storage device for portable equipment, embedding it in an LSI, or apply it to a main memory of a personal computer.
An MRAM that is now examined so as to be put to practical use uses a magnetic tunnel junction (hereinafter simply referred to as an “MTJ”) for the memory cell. Such an example is described in, for example, “IEEE International Solid-State Circuits Conference 2000 Digest Paper”, TA7.2. The MTJ mainly comprises a three-layer film including a ferromagnetic layer, an insulating layer, and a ferromagnetic layer. A current tunnels the insulating layer. The resistance value of the junction varies in proportion to the cosine of the relative angle between the directions of magnetization in both ferromagnetic metal layers. The resistance value of the junction is largest when the directions of magnetization in both ferromagnetic layers are antiparallel with each other. This is a tunnel magneto resistive effect. One type of MTJ has a structure that retains data utilizing a difference in magnetic coercive force between both ferromagnetic materials. Another type of MTJ has a so-called spin valve structure in which an antiferromagnetic material is arranged adjacent to one of the ferromagnetic materials to pin the directions of magnetization. The spin valve structure aims reduction of write current and improve the magnetic field sensitivity. An MRAM having the spin valve structure is described in, for example, “Japanese Journal of Applied Physics”, 1997, No. 36, p.200.
A brief description will be given of a conventional method of forming an MTJ element having the spin valve structure.
First, a switching transistor is formed on a semiconductor substrate. Subsequently, an interlayer insulating film, a local interconnect layer, a write interconnect layer, and a contact plug are formed in this order. Then, a nonmagnetic conductive film is formed on the interlayer insulating film as a leading interconnect layer.
Next, a ferromagnetic layer is formed on the leading interconnect layer as a pinning layer. Furthermore, an insulating layer is formed on the pinning layer as a tunnel barrier film. Subsequently, a ferromagnetic layer is formed on the tunnel barrier film as a free layer.
Moreover, the free layer, the tunnel barrier film, and the pinning layer are patterned using a photolithography technique and ion milling. This completes an MTJ element.
Next, an SiO2 film is formed on the MTJ element in order to protect the MTJ element. Then, the SiO2 film and the nonmagnetic conductive film are patterned using the photolithography technique and etching. This completes a leading interconnect layer.
Subsequently, an interlayer insulating film is formed so as to cover the MTJ element. Furthermore, a contact plug is formed in the interlayer insulating film so as to reach the free layer.
The MTJ element is formed as described above.
However, in the conventional MRAM, the upper and lower ferromagnetic layers, arranged opposite each other via the tunnel barrier film, may be electrically short-circuited at their ends. Thus, the yield of the MRAM decreases significantly. This is mainly because when a junction is etched using ion milling, residue containing metal remains near the tunnel barrier at a certain probability. The tunnel barrier film has a very small thickness of about 1 to 1.5 nm. That is, the upper and lower substrates are adjacent to each other at a very small distance of 1 to 1.5 nm. Thus, if the residue is larger than 1 to 1.5 run in size, a short circuit may occur. However, for a large-scale MRAM, it is substantially impossible to avoid this defect. As the degree of integration of the MRAM increases, it tends to become increasingly difficult to obtain acceptable products.
It is contemplated that the above short circuit problem may be solved by, for example, allowing ions to be incident at about 45° during an ion milling step. In this case, the sides of the MTJ are tapered. As a result, the probability of occurrence of a defect is expected to decrease. However, in an MRAM of a Gbit class, an MTJ element has a size of, for example, 0.1×0.2 μm. The distance between adjacent MTJ elements is about 0.1 μm. Then, to avoid an electric short circuit between the adjacent MTJ elements, ions are desirably allowed to enter the substrate surface as perpendicularly to it as possible during the ion milling step. That is, the short circuit between the MTJ elements and the short circuit between the ferromagnetic layers are traded off with each other.
BRIEF SUMMARY OF THE INVENTIONA semiconductor memory device according to an aspect of the present invention comprises:
a memory cell comprising a first ferromagnetic film, a tunnel barrier film formed on the first ferromagnetic film, and a second ferromagnetic film formed on the tunnel barrier film;
a side wall insulating film formed so as to surround at least sides of the second ferromagnetic film; and
an interlayer insulating film formed so as to cover the memory cell and the side wall insulating film.
A method for fabricating a semiconductor memory device according to an aspect of the present invention comprises:
forming a first ferromagnetic layer on a semiconductor layer;
forming a tunnel barrier film on the first ferromagnetic layer;
forming a second ferromagnetic layer on the tunnel barrier film;
patterning the second ferromagnetic layer to expose a part of the tunnel barrier film;
forming a side wall insulating film on the tunnel barrier film so that the side wall insulating film surrounds side walls of the second ferromagnetic layer; and
patterning the tunnel barrier film and the first ferromagnetic layer.
BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING
With reference to
As shown in this figure, an element isolating region STI is formed in a semiconductor substrate 10. A switching transistor 11 is formed in an element area AA the periphery of which is surrounded by the element separating area STI. The switching transistor 11 comprises impurity diffusion layers 12 formed in a surface region of the semiconductor substrate 10, a gate insulating film (not shown), and a gate electrode 13. The gate electrode 13 functions as a word line and is formed like a stripe extending along the direction of an easy axis (a direction perpendicular to the sheet of the drawing).
Further, an interlayer insulating film 14 is formed on the semiconductor substrate 10. The interlayer insulating film 14 covers the switching transistor 11.
A contact plug 15 is formed in the interlayer insulating film 14. The contact plug 15 is connected to one (a drain region) of the impurity diffusion layers 12 of the switching transistor 11.
A metal interconnect layer 16 connected to the contact plug 15 is formed on the interlayer insulating film 14. Furthermore, an interlayer insulating film 17 is formed on the interlayer insulating film 14. The interlayer insulating film 17 covers the metal interconnect layer 16. A contact plug 18 is formed in the interlayer insulating film 17. The contact plug 18 is connected to the metal interconnect layer 16.
Metal interconnect layers 19 and 20 are formed on the interlayer insulating film 17; the metal interconnect layer 19 is connected to the contact plug 18, and the metal interconnect layer 20 is electrically separated from the metal interconnect layer. The metal interconnect layer 20 functions as a write word line and is formed like a stripe extending along the direction of the easy axis. Furthermore, an interlayer insulating film 21 is formed on the interlayer insulating film 17. The interlayer insulating film 21 covers the metal interconnect layers 19 and 20. A contact plug 22 is formed in the interlayer insulating film 21. The contact plug 22 is connected to the metal interconnect layer 19.
A nonmagnetic conductive film 23 connected to the contact plug 22 is formed on the interlayer insulating film 21. The nonmagnetic conductive film 23 functions as a leading interconnect layer. It is formed of a multilayer film including a Ta layer of, for example, film thickness 3 nm, an Al layer 25 of, for example, film thickness 30 nm, and a Ta layer 26 of, for example, film thickness 30 nm which are sequentially formed. Further, a magneto resistive element 27 is formed on the nonmagnetic conductive film 23. The magneto resistive element 27 is formed to lie on top of the metal interconnect layer 20 so as to sandwich the interlayer insulating film 21 and the nonmagnetic conductive film 23 between itself and the metal interconnect layer 20. The magneto resistive element 27 is designed so that an insulating film is sandwiched between magnetic material films and is, for example, an MTJ element.
The structure of the magneto resistive element 27 will be described with reference to
As shown in this figure, the magneto resistive element 27 is shaped like a general ellipse the major axis of which extends along the direction of the easy axis. The magneto resistive element 27 includes a pinning layer 28 formed on the nonmagnetic conductive layer 23, a tunnel barrier film 29 formed on the pinning layer 28, and a free layer 30 formed on the tunnel barrier film 29. The pinning layer 28 is formed of a stacked film in which the following layers are sequentially formed: a seed layer (or buffer layer) 31 formed of permalloy (Py: NiFe alloy) of, for example, film thickness 3 nm, an antiferromagnetic layer 32 formed of IrMn of, for example, film thickness 15 nm, and a pinning ferromagnetic layer 33 formed of a CoFe layer of, for example, film thickness 5 nm. The tunnel barrier film 29 is formed of an Al2O3 layer of, for example, film thickness about 1 to 1.5 nm. The free layer 30 is formed of a stacked film including a CoFe layer 34 of, for example, 4 nm film thickness and a Py layer 35 of, for example, 20 nm film thickness which are sequentially formed.
The pinning layer 28 and the tunnel barrier film 29 have substantially the same surface area and completely overlap each other. The free layer 30 has a smaller surface area than the pinning layer 28 and the tunnel barrier film 29 and is provided, as a whole, on the tunnel barrier film 29. The magneto resistive element 27 is thus formed.
A cap layer 36 is formed on the free layer 30. The cap layer 36 is formed of a multilayer film including a Ta layer of, for example, 20 nm film thickness, an Al layer 38 of, for example, 50 nm film thickness, and a Ta layer 39 of, for example, 10 nm film thickness which are sequentially formed. Further, a side wall insulating film 40 is formed on the tunnel barrier film 29 so as to surround at least the periphery of the free layer 30. The side wall insulating film 40 is formed of, for example, an Al2O3 film.
Further, an SiO2 film 41 is formed on the nonmagnetic conductive film 23 so as to cover the magneto resistive element 27, the cap layer 36, and the side wall insulating film 40. The SiO film 41 serves to protect the magneto resistive element 27. Furthermore, an interlayer insulating film 42 is formed on the interlayer insulating film 21 so as to cover the nonmagnetic conductive film 23 and the SiO2 film 41. A contact plug 43 is formed in the interlayer insulating film 42 and the SiO2 film 41. The contact plug 43 extends from the surface of the interlayer insulating film 42 to the Ta layer 39 in the cap layer 36. A bit line 44 connected to the contact plug 43 is formed on the interlayer insulating film 42.
The memory cell including the magneto resistive element 27 and the switching transistor 11 is formed as described above. Spins in the pinning layer 28 in the magneto resistive element 27 are set beforehand to have predetermined orientations. The orientations of spins in the free layer 30 are then set to be parallel or antiparallel with the pinning layer 28. This creates two states to cause “0” or “1” data to be written in the magneto resistive element 27.
Now, with reference to
First, in step S1 in
Then, the metal interconnect layer 16 is formed on the interlayer insulating film 14. The metal interconnect layer 16 is connected to the contact plug 15. Then, the interlayer insulating film 17 is formed on the interlayer insulating film 14. Subsequently, the contact plug 18 is formed in the interlayer insulating film 17. The contact plug 18 is connected to the metal interconnect layer 16.
Then, the metal interconnect layers 19 and 20 are formed on the interlayer insulating film 17. The metal interconnect layer 19 is connected to the contact plug 18. The metal interconnect layer 20 is separated from the metal interconnect layer 19 and is formed like a stripe extending along the direction of the easy axis. It is located immediately above the gate electrode 13. Subsequently, the interlayer insulating film 21 is formed on the interlayer insulating film 17. The interlayer insulating film 21 covers the metal interconnect layers 19 and 20. Subsequently, the contact plug 22 is formed in the interlayer insulating film 21. The contact plug 22 is connected to the metal interconnect layer 19.
Then, in step S2 in
Furthermore, the tunnel barrier film 29 is formed on the pinning ferromagnetic layer 33 (step S3). The tunnel barrier film 29 is formed, for example, in the following manner. An Al layer of, for example, film thickness 1 to 1.5 nm is formed on the pinning ferromagnetic layer 33 using the sputtering method. The Al layer is then plasma-oxidized using an ICP (Inductively Coupled Plasma) method. As a result, the Al layer is oxidized to form an Al2O3 layer forming the tunnel barrier film 29. Of course, instead of oxidizing Al, it is possible to form an Al2O3 layer on a ferromagnetic layer using, for example, the sputtering method or a CVD (Chemical Vapor Deposition). As a result, the structure shown in
Then, in step S4 in
Then, in step S5 in
Then, in step S6 in
Subsequently, the resist 50 is removed (step S7).
Then, in step S8 in
Then, in step S9 in
In steps S8 and S9, the Al layer 51 is desirably formed and oxidized without exposing the substrate to the atmosphere. To accomplish this, a semiconductor fabricating apparatus must be provided which can continuously carry out sputtering and a plasma oxidization process. This fabricating apparatus has, for example, a sputtering chamber and a oxidization chamber as well as a mechanism that can carry the semiconductor substrate between these chambers without exposing it to the atmosphere. Then, after the Al layer 51 has been formed in the sputtering chamber, the substrate is carried to the oxidization chamber without being removed from the semiconductor fabricating apparatus. The Al layer 51 is then plasma-oxidized.
Then, in step S10 in
Then, in step S12 in
Then, in step S13 in
Subsequently, in step S14, a photo resist 52 is applied to the surface of the SiO2 film 41. Then, the photo resist 52 is patterned using the photolithography technique as shown in
Then, in step S115 in
Then, in step S17 in
Subsequently, the interlayer insulating film 42 is formed on the interlayer insulating film 21. Then, the photolithography technique or the RIE method is used to make a contact hole that reaches the magneto resistive element 27. Furthermore, a conductor is filled into the contact hole to form the contact plug 43. Subsequently, the bit line 44 is formed on the interlayer insulating film 42 to complete the MRAM shown in
As described above, according to the first embodiment of the present invention, the yield of the MRAM can be improved. This will be described below.
First, the side wall insulating film 40 is formed on the sides of at least one of the two ferromagnetic layers arranged opposite each other with the tunnel barrier film 29 interposed therebetween. In the present embodiment, the side wall insulating film 40 is formed on the sides of the free layer 30 to surround its periphery. Accordingly, even if residue remains around the periphery of the magneto resistive element 27, it is possible to prevent a short circuit between the pinning layer 28 and the free layer 30 unless the residue is large enough to contact with both the pinning layer 28 and the cap layer 36, located higher than the side wall insulating film 40. For example, in the present embodiment, the side wall insulating film 40 has a height of about 80 nm. Consequently, it is possible to hinder a short circuit between the pinning layer 28 and the free layer 30 unless the residue remaining after the Ar ion milling is about 80 nm or more in size. With the conventional configuration, a short circuit may be caused by residue of size 1 to 1.5 nm, which is substantially equal to the film thickness of the tunnel barrier film. Therefore, the configuration according to the present embodiment allows the residue to be removed much more easily than the conventional one. As a result, the yield of MRAMs, notably large-scale MRAMs can be effectively improved.
Further, the formation of the side wall insulating film 40 serves to hinder a short circuit between the free layer and pinning layer. This eliminates the need to carry out the Ar ion milling described in
Furthermore, with the fabricating method according to the present embodiment, the Al layer 51, formed on the side walls of the magneto resistive element 27, is oxidized to form the side wall insulating film 40. With this fabricating method, the oxidation gradually proceeds from the outer sides of the Al layer 51. Finally, all of the Al layer 51 is oxidized to form the Al2O3 layer 40. In this case, oxygen is introduced into an end of the Al2O3 layer, the tunnel barrier film 29. When the free layer 30 is patterned by the Ar ion milling, the tunnel barrier film 29 has its surface beaten by Ar ions and is thus damaged. As a result, the oxygen may be lost at the end of the tunnel barrier film 29. Then, the insulating property of the Al2O3 layer 40 may be markedly lost to cause a short circuit between the free layer 30 and the pinning layer 28. With the fabricating method according to the present embodiment, when the Al layer 51 is oxidized, oxygen is also introduced into the end of the tunnel barrier film 29. Accordingly, the Al2O3 layer 40 has a sufficient insulating property. As a result, the free layer 30 and the pinning layer 28 can be electrically sufficiently separated from each other. That is, it is possible to prevent a short circuit in the magneto resistive circuit 27. Therefore, the yield of the MRAM can be improved.
Furthermore, according to the first embodiment of the present invention, the operational reliability of the MRAM is improved. This will be described below.
With the fabricating method according to the present embodiment, the Ar ion milling described in
Moreover, the shape of the free layer 30 in the magneto resistive element 27 can be easily controlled as described above, so that it is easy to control the horizontal extension of the pinning layer 28 with respect to the free layer 30. It is thus possible to reduce differences among magneto resistive elements in the adverse effects of leakage magnetic fields from the pinning layer 28, or the like. As a result, the write operation margin for the MRAM can be increased to improve the operational reliability of the MRAM.
Now, with reference to
First, the structure shown in
Then, in step S21 in
In the fabricating method according to the present embodiment, steps S8, S20, and S21 are also desirably executed without exposing the substrate to the atmosphere. To accomplish this, a semiconductor fabricating apparatus must be provided which can continuously execute the sputtering, plasma oxidization process, and RIE or ion milling. The series of processes are executed within this semiconductor fabricating apparatus. However, if the RIE is compared with the ion milling, the former is more preferable.
Then, in step S11, the tunnel barrier film 29 is patterned to obtain the structure shown in
According to the present embodiment, effects similar to those of the above first embodiment are obtained. At the same time, the operational reliability of the MRAM can be further improved. This will be described below.
With the fabricating method according to the present embodiment, after the Al layer 51 has been etched, it is oxidized to form the Al2O3 layer 40. Accordingly, the step of etching the Al2O3 layer 40 need not be executed before the pinning layer 28 is patterned in contrast with the first embodiment. During the Ar ion milling, Al can be etched faster than Al2O3. Consequently, the etching operation can be easily stopped once the Ta layer 26, forming the leading interconnect layer, is exposed when the ferromagnetic layer is etched by the Ar ion milling in order to form the pinning layer 28. As a result, the resistance distribution of the leading interconnect layer 23 is improved. Furthermore, if the Al is etched using the RIE, the resistance distribution of the leading interconnect layer 23 can be further improved. This is because the use of the RIE enables the Al layer 51 to be selectively etched and enables the etching to be reliably stopped at the surface of the tunnel barrier film 29. In this case, only the tunnel barrier film 29 and the pinning layer 28 must be etched by the Ar ion milling. As a result, the write operation margin for the MRAM can be increased to improve the operational reliability of the MRAM.
Now, with
First, the structure shown in
Then, in step S31 in
Then, in step S32 in
Then, in step S35 in
Then, in step S8 in
Then, in step S20 in
Then, in step S21 in
In the fabricating method according to the present embodiment, steps S35, S8, S20, and S21 are also desirably executed without exposing the substrate to the atmosphere. To accomplish this, a semiconductor fabricating apparatus must be provided which can continuously execute the sputtering, plasma oxidization process, and RIE or ion milling.
Then, in step S11 in
Subsequently, as described in the above first embodiment, steps S13 to S17 are executed to complete the MRAM.
With the fabricating method according to the present embodiment, effects similar to those of the above first and second embodiments are obtained.
Then, with reference to
As shown in the figure, the magneto resistive element 27 of the MRAM according to the present embodiment corresponds to the arrangement according to the first to third embodiments in which the composition of Al2O3 as the tunnel barrier film 29 is improved. That is, the tunnel barrier film 29 has a higher oxygen content at the end than in the center of the magneto resistive element 27. Specifically, the composition of the tunnel barrier film is Al2Ox in the center of the magneto resistive element and is Al2Oy at its end, where x and y are both close to 3 and y>x.
The present structure can be formed by increasing, in the above first to third embodiments, the time required for the oxidizing process to provide excessive oxidization when the Al layer 51 is oxidized. The excessive oxidization causes oxygen to enter the tunnel barrier film 29. As a result, the oxygen content in Al2O3 is higher at the end of the magneto resistive element. More specifically, in the steps in
With the configuration according to the present embodiment, effects similar to those of the above first and second embodiments are obtained. At the same time, the operational reliability of the MRAM can be further improved. This will be described below.
However, the formation of a magneto resistive element of 0.1 μm size requires a very difficult machining technique. Accordingly, as shown in
However, with the configuration according to the present embodiment, as shown in
Now, with reference to
As shown in this figure, the magneto resistive element 27 of the MRAM according to the present embodiment corresponds to the arrangement according to the above first to third embodiments in which the tunnel barrier film 29 has a larger film thickness at the end of the magneto resistive element. That is, the tunnel barrier film 29 has a film thickness d1 in the center of the magneto resistive element and a film thickness d2 at its end. In this case, d2>d1.
The present structure can be formed by increasing, in the above first to third embodiments, the time required for the oxidizing process to provide excessive oxidization when the Al layer 51 is oxidized. The excessive oxidization causes oxygen to enter not only the tunnel barrier film 29 but also an area of the in-surface edge of the free layer 30 which contacts with the tunnel barrier film 29. As a result, a part of the CoFe layer 34, forming the free layer 30, is oxidized to form a CoOx layer and an FeOx layer. The CoOx layer and the FeOx layer are insulators and function as a part of the tunnel barrier film. That is, at the end of the magneto resistive element, the tunnel barrier film 29 is formed of an Al2O3 layer, a CoOx layer, and an FeOx layer. Consequently, the tunnel barrier film 29 apparently has a larger film thickness in the center than at the end of the magneto resistive element.
With the present embodiment, not only the effects described in the above first and second embodiments but also the effects described in the fourth embodiment are obtained. That is, with the structure according to the present embodiment, the tunnel barrier film 29 has a larger film thickness in the periphery of the magneto resistive element 27, which tends to be notched. Consequently, the tunnel resistance per unit area is low in the center of the magnet resistive element, while it is high at the end of the element. That is, a tunnel current flows easily through the center of the magneto resistive element but not through its end. As a result, the effects described in the above fourth embodiment contribute to reducing the adverse effects on the MR ratio of the disturbed spin orientations at the end of the magneto resistive element. This in turn serves to provide a reliable NRAM having a large read margin.
Now, with reference to
As shown in this figure, the magneto resistive element 27 of the MRAM according to the present embodiment corresponds to the arrangement according to the above first to third embodiments in which the tunnel barrier film 29 has a much larger film thickness at the end of the magneto resistive element. That is, the tunnel barrier film 29 has the film thickness d1 in the center of the magneto resistive element and a film thickness d3 at its end. In this case, d3>d2>d1.
The present structure can be formed by increasing, in the above first to third embodiments, the time required for the oxidizing process to provide excessive oxidization when the Al layer 51 is oxidized. The excessive oxidization causes oxygen to enter not only the tunnel barrier film 29 but also the pinning layer 28 and the free layer 30. As a result, a CoOx layer and an FeOx layer are formed by oxidizing a part of the pinning ferromagnetic layer 33, forming the pinning layer 28, and a part of the CoFe layer 34, forming the free layer 30. Thus, at the end of the magneto resistive element, the tunnel barrier film 29 is formed of an Al2O3 layer, and a CoOx and FeOx layers formed by oxidizing the CoFe layers 33 and 34. Consequently, the tunnel barrier film 29 apparently has a larger film thickness in the center than at the end of the magneto resistive element.
With the present embodiment, effects similar to those of the fifth embodiments are obtained. Further, the tunnel resistance at the end of the magneto resistive element can be further increased compared to the fifth embodiment. Therefore, the read margin can be further increased to provide a reliable MRAM.
Now, with reference to
As shown in the figure, the magneto resistive element 27 comprises the pinning layer 28, the tunnel barrier film 29 formed on the pinning layer 28, and the free layer 30 formed on the tunnel barrier film 29. The pinning layer 28 has a stacked structure including the seed layer 31 formed of, for example, Py, the antiferromagnetic layer 32 formed of, for example, IrMn, and the pinning ferromagnetic layer 33 formed of, for example, CoFe. Further, the free layer 30 has a multilayer structure Py 35/CoFe 34. The tunnel barrier film 29 has the film thickness d1 in the center of the magneto resistive element and a film thickness d4 at its end (d4>d1).
Now, with reference to
First, the structure shown in
Then, the magneto resistive element is exposed to an oxidization atmosphere. More specifically, the magneto resistive element is oxidized, for example, for about 5 minutes in an oxygen atmosphere at a pressure of about 200 Torr. Then, the CoFe layers 33 and 34, arranged over and under the tunnel barrier film 29, respectively, are oxidized at a higher speed in their areas which correspond to the end of the magneto resistive element and which are also close to their interfaces. Thus, the structure shown in
With the configuration according to the present embodiment, in contrast with the above first to third embodiments, the side wall insulating film 40 is not formed. However, a CoOx layer and an FeOx layer are formed by oxidizing the CoFe layers 33 and 34, arranged over and under the tunnel barrier film 29, respectively, in their areas corresponding to the end of the magneto resistive element. Accordingly, the tunnel barrier film 29 is considered to have a larger film thickness at the end of the magneto resistive element. Consequently, as in the above first embodiment, a short circuit can be hindered from occurring between the pinning layer 28 and the free layer 30 owing to residue. Further, the magneto resistive element described in
Now, with reference to
As shown in the figure, the magneto resistive element 27 is formed on the nonmagnetic conductive film 23, functioning as a leading interconnect layer. The magneto resistive element 27 is, for example, an MTJ element. The structure of the magneto resistive element 27 will be described with reference to
As shown in the figures, the magneto resistive element 27 is shaped like a general ellipse the major axis of which extends along the easy axis. It includes the free layer 30 formed on the nonmagnetic conductive film 23, the tunnel barrier film 29 formed on the free layer 30, and the pinning layer 28 formed on the tunnel barrier film 29. The free layer 30 is formed of a stacked film including a seed layer 60 formed of Cu of, for example, film thickness 5 nm and a permalloy (Py: NiFe) layer 65 of, for example, film thickness 5 nm which are sequentially formed. The tunnel barrier film 29 is formed of an Al2O3 layer of, for example, film thickness 1 to 1.5 nm. The pinning layer 28 is formed of a stacked film including a CoFe layer 61 of, for example, film thickness 1.5 nm, an Ru layer 62 of film thickness 1 nm, and a CoFe layer 63 of, for example, film thickness 2 nm which are sequentially stacked.
The free layer 30 and the tunnel barrier film 29 have substantially the same surface area and completely overlap each other. The pinning layer 28 has a smaller surface area than the free layer 30 and the tunnel barrier film 29 and is provided, as a whole, on the tunnel barrier film 29. The magneto resistive element 27 is thus formed.
An antiferromagnetic layer 64 is formed on the pinning layer 28. The antiferroelectric layer 64 is formed of an IrMn layer of, for example, film thickness 15 nm. Furthermore, the cap layer is formed on the antiferromagnetic layer 64. The cap layer 36 is formed of a Ta layer of, for example, film thickness 5 nm. Further, the side wall insulating film 40 is formed on the tunnel barrier film 29 so as to surround at least the periphery of the pinning layer 28. The side wall insulating film 40 is formed of, for example, an Al2O3 film.
The other arrangements are similar to those of the first embodiment.
Now, with reference to
First, as described in the first embodiment, in step S1 in
Furthermore, in step S3, the tunnel barrier film 29 is formed on the ferromagnetic layer 65. Subsequently, in step S41, a ferromagnetic layer is formed on the tunnel barrier film 29. That is, the CoFe layer 61 of, for example, film thickness 1.5 nm, the Ru layer 62 of, for example, film thickness 1 nm, and the CoFe layer 63 of, for example, film thickness 2 nm are sequentially formed on the tunnel barrier film 29 using the sputtering method. The ferromagnetic layer formed of the multilayer film CoFe/Ru/CoFe is used to form a pinning layer of the magneto resistive layer. Subsequently, an antiferromagnetic layer, for example, the IrMn layer 64 of film thickness 15 nm is formed on the CoFe layer 63. Furthermore, a nonmagnetic conductive film, for example, the Ta layer 36 of film thickness 5 nm is formed on the IrMn layer 64. This nonmagnetic conductive film 36 is used to form a cap layer. As a result, the structure shown in
Then, in step S5, a photo resist is applied to the surface of the nonmagnetic conductive film 36. Then, the photolithography technique is used to pattern the photo resist so that the resist has a pattern for forming the magneto resistive element. Subsequently, in step S42, the nonmagnetic conductive film 36, the antiferromagnetic layer 64, and the ferromagnetic layers 61 to 63 are patterned using the RIE method or the Ar ion milling. As a result, the pinning layer 28 of the magneto resistive element is formed as shown in
Then, in step S8, the Al layer 51 is formed to obtain the structure shown in
Then, in step S10 in
Then, in step S43, the ferromagnetic layer 65 and the metal layer 60 are patterned. As a result, the free layer 30 is formed as shown in
Subsequently, the structure shown in
As described above, with the structure and fabricating method according to the present embodiment, effects similar to those of the above first embodiment are obtained even with an MRAM of a top pin type structure in which a pinning layer is formed on a free layer.
Now, with reference to
First, the structure shown in
Then, in step S21, the Al layer 51 is oxidized to form an Al2O3 layer. As a result, as shown in
Then, in step S11, the tunnel barrier film 29 is patterned to obtain the structure shown in
With the structure and fabricating method according to the present embodiment, the effects described in the above second embodiment are obtained even with a top pin type MRAM.
Now, with reference to
First, the structure shown in
Then, in steps S31 and S32, a photo resist is applied to the surface of the hard mask layer 53. As shown in
Then, in step S8, an Al layer is formed to obtain the structure shown in
Then, in step S11, the tunnel barrier film 29 is patterned. Furthermore, in step S43, the ferromagnetic layer 65 and the metal layer 60 are patterned. As a result, the free layer 30 is completed to obtain the structure shown in
Subsequently, steps S13 to S17 are executed as described in the above first embodiment to complete the MRAM.
Also with the fabricating method according to the present embodiment, effects similar to those of the above first and second embodiments are obtained even with a top pin type MRAM.
Now, with reference to
As shown in the figure, the magneto resistive element 27 of the MRAM according to the present embodiment corresponds to the arrangement according to the eighth to tenth embodiments in which the composition of Al2O3 as the tunnel barrier film 29 is improved. That is, the tunnel barrier film 29 has a higher oxygen content at the end than in the center of the magneto resistive element 27. Specifically, the composition of the tunnel barrier film is Al2Ox in the center of the magneto resistive element and is Al2Oy at its end, where x and y are both close to 3 and y>x.
With the configuration according to the present embodiment, the effects described in the above fourth embodiment are obtained even with a top pin type MRAM.
Now, with reference to
As shown in the figure, the magneto resistive element 27 of the MRAM according to the present embodiment corresponds to the arrangement according to the above eighth to tenth embodiments in which the tunnel barrier film 29 has a larger film thickness at the end of the magneto resistive element. That is, the tunnel barrier film 29 has the film thickness d1 in the center of the magneto resistive element and the film thickness d2 at its end. In this case, d2>d1.
The present structure can be formed by increasing, in the above eighth to tenth embodiments, the time required for the oxidizing process to provide excessive oxidization when the Al layer 51 is oxidized. The excessive oxidization causes oxygen to enter not only the Al2O3 layer 29 but also an area of the in-surface edge of the pinning layer 28 which contacts with the tunnel barrier film 29. As a result, a part of the CoFe layer 61, forming the pinning layer 30, is oxidized to form a CoOx layer and an FeOx layer. That is, at the end of the magneto resistive element, the tunnel barrier film 29 is formed of an Al2O3 layer, a CoOx layer, and an FeOx layer. Consequently, the tunnel barrier film 29 apparently has a larger film thickness in the center than at the end of the magneto resistive element.
With the above configuration, the effects described in the above fifth embodiment are obtained even with a top pin type MRAM.
Now, with reference to
As shown in this figure, the magneto resistive element 27 of the MRAM according to the present embodiment corresponds to the arrangement according to the above eighth to tenth embodiments in which the tunnel barrier film 29 has a much larger film thickness at the end of the magneto resistive element.
The present structure can be formed by increasing, in the above eighth to tenth embodiments, the time required for the oxidizing process to provide excessive oxidization when the Al layer 51 is oxidized. The excessive oxidization causes oxygen to enter not only the Al2O3 layer 29 but also the pinning layer 28 and the free layer 30. As a result, a part of the CoFe layer 34, forming the free layer 30, is oxidized to form a CoOx layer and an FeOx layer. Further, a part of the NiFe layer 65, forming the free layer 30, is oxidized to form an NiFe oxide film. Thus, at the end of the magneto resistive element, the tunnel barrier film 29 is formed of an Al2O3 layer, and an insulating film formed by oxidizing the CoFe layer 61 and NiFe layer 65. Consequently, the tunnel barrier film 29 apparently has a larger film thickness in the center than at the end of the magneto resistive element.
According to the present embodiment, effects similar to those of the above sixth embodiment are obtained even with a top pin type MRAM.
Now, with reference to
As shown in the figure, the magneto resistive element 27 comprises the free layer 30, the tunnel barrier film 29 formed on the free layer 30, and the pinning layer 28 formed on the tunnel barrier film 29. The free layer 30 has a stacked structure including the seed layer 60 formed of, for example, Cu and the ferromagnetic layer 30 formed of, for example, Py. The pinning layer 28 also has a stacked structure including, for example, the CoFe layer 61, the Ru layer 62, and the CoFe layer 63, which are sequentially formed. The tunnel barrier film 29 has the film thickness d1 in the center of the magneto resistive element and the film thickness d4 at its end (d4>d1).
A method of forming the magneto resistive element according to the present embodiment is similar to that of the above seventh embodiment. That is, the structure shown in
According to the present embodiment, effects similar to those of the above seventh embodiment are obtained even with a top pin type MRAM.
Now, with reference to
As shown in the figure, the fabricating method according to the present embodiment corresponds to the fabricating steps described in the above first embodiment, variation of the third embodiment, eighth embodiment, and variation of the tenth embodiment wherein the Al layer is oxidized in step S9 and then annealed in step S60.
The fabricating method according to the present embodiment improves the insulating property of the side wall insulating film 40. The Al2O3 film forming the side wall insulating film 40 may have the loss of oxygen or include an area with an excessive amount of Al or oxygen. However, by oxidizing and then annealing the Al layer as in the present embodiment, Al and oxygen atoms can be made uniform. As a result, the insulating property of the Al2O3 can be improved. Further, once the Al layer is oxidized, the composition of the resultant side wall insulating film is not completely Al2O3. However, the annealing operation helps complete the composition of the side wall insulating film. Therefore, the insulating property is improved.
As described above, according to the first to sixth embodiments of the present invention, the side wall insulating wall 40 is formed on the tunnel barrier film 29 so as to surround the periphery of the free layer 30. It is thus possible to hinder a short circuit between the pinning layer 28 and the free layer 30 caused by residue resulting from the Ar ion milling. Further, since the side wall insulating film 40 prevents a short circuit between the pinning layer 28 and the free layer 30, ions can enter the semiconductor substrate surface substantially perpendicularly to it during the Ar ion milling step executed to form the pinning layer 28. Thus, the shape of the pinning layer 28 can be easily controlled to ensure a sufficient operation margin for the MRAM. Furthermore, the side wall insulating film 40 is formed by oxidizing the Al layer 51. In this case, oxygen is also supplied to the end of the tunnel barrier film 29. Consequently, those areas of the tunnel barrier film 29 which correspond to the ends of the magneto resistive element can sufficiently maintain their insulating property. This makes it possible to prevent a short circuit between the pinning layer 28 and the free layer 30.
Further, according to the seventh and fourteenth embodiments, a part of the pinning layer 28 and free layer 30 are oxidized. As a result, the tunnel barrier film 29 has a larger film thickness at the end of the magneto resistive element, thus producing the above effects.
Furthermore, according to the eighth to thirteenth embodiments, effects similar to those of the above first to sixth embodiments are obtained even with a top pin type MRAM. That is, the side wall insulating film 40 is formed on the tunnel barrier film 29 so as to surround the periphery of the pinning layer 28. It is thus possible to prevent a short circuit between the pinning layer 28 and the free layer 30. Further, ions can enter the semiconductor substrate surface substantially perpendicularly to it during the Ar ion milling step executed to form the free layer 30. Thus, the shape of the free layer 30 can be easily controlled to ensure a sufficient operation margin for the MRAM.
Furthermore, according to the fifteenth embodiment, the Al layer 51 is oxidized and then annealed. This results in the uniform composition of the Al2O3 layer forming the side wall insulating film 40. Thus, the insulating property of the side wall insulating film 40 can be improved.
In the description of the above embodiments, Al is cited as an example of material used to form the side wall insulating film 40. However, the present embodiment is not particularly limited to Al. Other metal or alloy may be used. Preferably, it is desirable to use material that is easier to oxidize than the ferromagnetic material used for the free layer or the pinning layer. Further, the formation of the side wall insulating film 40 is not limited to oxidization. For example, nitridization or fluoridization may be used. However, in view of the yield and manufacturing costs, the side wall insulating film 40 and the tunnel barrier film 29 are desirably an oxide, a nitride, or a fluoride containing the same metal element. For example, Al2O3, AlN, MgO, HfO2, GaO, LaAlO3, MgF2, CaF2, or the like may be used. These compounds may have a small loss of oxygen (nitrogen or fluorine). Further, the above fabricating steps are not limited to the above order. The order can be changed as drastically as possible. Furthermore, in the description of the above eighth to thirteenth embodiments, the pinning layer 28 has a multilayer structure including the CoFe layers 61 and 63 and the Ru layer 62. However, the pinning layer 28 may be formed only of a CoFe layer.
Further, in the description of the above embodiments, the magneto resistive element is a memory cell using an MTJ element. However, a GMR (Giant Magneto Resistive) element, a CMR (Colossal Magneto Resistive) element, or the like may be used.
Various applications are possible in magneto resistive random access memories (semiconductor memory) according to the first to fifteenth embodiments of the present invention. FIGS. 27 to 33 show some examples of applications thereof.
APPLICATION EXAMPLE 1 As an example,
In this example, two memories of the magneto resistive random access memory and EEPROM are used as memories for holding the line code programs. However, the EEPROM may be replaced by another magneto resistive random access memory. Further, only a magneto resistive random access memory may be used, instead of using two memories.
APPLICATION EXAMPLE 2 As another example,
Further, as shown in
Although the ROM 222, MRAM 223, and flash memory 224 are used in this application example, the flask memory 224 may be replaced by a magneto resistive random access memory according to the first to fifteenth embodiments of the present invention. Further, the ROM 222 may also be replaced by a magneto resistive random access memory according to the first to fifteenth embodiments of the present invention.
APPLICATION EXAMPLE 3
In
In the embodiments described above, the side wall insulating film 40 covers either side of the pinning layer 28 or free layer 30 entirely. Nonetheless, the sides of the layer 28 or layer 30 need not be entirely covered.
If the free layer 30 provided on the tunnel barrier film 29 is thick, the insulating film 40 may cover only a part of the side of the free layer 30 as shown in
In the case of the top pin type MRAM, the insulating film 40 may cover only a part of the side of the pinning layer 28 as illustrated in
Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.
Claims
1. A semiconductor memory device comprising:
- a memory cell comprising a first ferromagnetic film, a tunnel barrier film formed on the first ferromagnetic film, and a second ferromagnetic film formed on the tunnel barrier film, the tunnel barrier film having a larger film thickness in its in-surface edge portion than in its in-surface central portion;
- a side wall insulating film formed so as to surround at least sides of the second ferromagnetic film; and
- an interlayer insulating film formed so as to cover the memory cell and the side wall insulating film.
2. A semiconductor memory device comprising:
- a memory cell comprising a first ferromagnetic film, a tunnel barrier film formed on the first ferromagnetic film, and a second ferromagnetic film formed on the tunnel barrier film, the tunnel barrier film having a larger film thickness in its in-surface edge portion than in its in-surface central portion; and
- a side wall insulating film formed so as to surround at least sides of the second ferromagnetic film and containing a metal element.
3. A semiconductor memory device comprising:
- a memory cell comprising a first ferromagnetic film, a tunnel barrier film formed on the first ferromagnetic film, and a second ferromagnetic film formed on the tunnel barrier film, the tunnel barrier film having a larger film thickness in its in-surface edge portion than in its in-surface central portion; and
- a side wall insulating film formed on the tunnel barrier film so as to surround a periphery of the second ferromagnetic film.
4. A semiconductor memory device comprising:
- a memory cell comprising a first ferromagnetic film, a tunnel barrier film formed on the first ferromagnetic film and containing oxygen elements, and a second ferromagnetic film formed on the tunnel barrier film, the tunnel barrier film having a larger tunnel resistance per unit area in its in-surface edge portion than in its in-surface central portion, the tunnel barrier film having a larger film thickness in its in-surface edge portion than in its in-surface central portion.
5. The device according to claim 4, wherein the tunnel barrier film contains in its in-surface edge portion a magnetic metal element contained in at least one of the first and second magnetic films.
6. The device according to claim 4, wherein the tunnel barrier film is formed of aluminum oxide.
Type: Application
Filed: Sep 14, 2006
Publication Date: Jan 11, 2007
Inventor: Yoshiaki Fukuzumi (Yokohama-shi)
Application Number: 11/520,686
International Classification: H01L 29/94 (20060101);