The present invention relates to a process for producing a magnetoresistive effect element.
Magnetic Random Access Memory (MRAM) is a nonvolatile memory having a TMR element using a magnetoresistive effect (Tunneling Magneto Resistive: TMR) and has integration density similar to Dynamic Random Access Memory (DRAM) and a highspeed performance similar to Static Random Access Memory (SRAM), and the world pays attention to MRAM as a revolutionary next-generation memory in which data is rewritten repeatedly.
As the TMR element for MRAM, a perpendicular magnetization TMR element (hereinafter also referred to as a P-TMR element) suitable for high integration has been extensively used (see, Non-Patent Literature 1).
As a method of processing the TMR element, an ion beam etching (IBE) technique and a reactive ion etching (RIE) technique are used. It is known that processing is performed using an RIE method using a mixed gas of hydrocarbon and oxygen as an etching gas, for example, whereby a metal film in a magnetoresistive effect element can be selectively etched (see, Patent Literature 1).
When the TMR element is element-isolated using the above-described etching technique, a re-deposited film formed of an etched material deposited after etching is formed on a side wall of the element-isolated TMR element. Such a re-deposited film contains many metal materials, and when the re-deposited film is adhered to a side wall of a tunnel barrier layer, a current passing through a reference layer and a free layer passes through the re-deposited film on the side wall, so that a function as the element is lost.
In order to prevent short-circuiting of the current, the re-deposited film adhered to the side wall is required to become an insulator through oxidation reaction, nitriding reaction, or the like.
Meanwhile, the P-TMR element includes a film formed of a large number of noble metals such as Pd, Pt, and Ru, and the re-deposited film after etching contains a large amount of noble metal atoms. Since such noble metal atoms are chemically stable, the rates of reactions of oxidation and nitriding are slow in comparison with other atoms. Thus, when the noble metal atoms in the re-deposited film are to be completely converted into an isolator, oxidation and nitriding of other atoms in the element are progressed to deteriorate element characteristics.
The present invention has been made based on the above problem, and an object of the invention is to provide a process for producing a TMR element including a process for selectively removing noble metal atoms in a re-deposited film adhered to a side wall of the TMR element after etching process.
In order to solve the above problem, according to the present invention, noble metal atoms contained in a re-deposited film formed on a side wall of a TMR element are selectively etched from other metal atoms, using an ion beam using a Kr gas or a Xe gas.
More specifically, the present invention provides a process for producing a magnetoresistive effect element having two ferromagnetic layers and a tunnel barrier layer located between the two ferromagnetic layers. This production process includes a process for applying anion beam to a metal material adhered to the side wall of the tunnel barrier layer.The ion beam is formed using a plasma of a Kr gas or a Xe gas.
In the present invention, in the process for applying the ion beam using a Kr gas or a Xe gas to the re-deposited film adhered to the side wall of the TMR element after etching process, noble metal atoms in the re-deposited film can be selectively removed. Thus, according to this invention, short-circuiting due to the re-deposited film can be reduced by selective removal of the noble metal atoms. It is possible to reduce a time, when the ion beam is applied to the re-deposited film, for reducing the short-circuiting or a reaction time for converting a metal material, contained in the re-deposited film, into an insulator, so that a TMR element having more excellent element characteristics can be produced.
Hereinafter, although embodiments of the present invention will be described with reference to the drawings, this invention is not limited to the embodiments and may be suitably modified without departing from the scope of the invention. In the drawings to be described below, the same functional elements are indicated by the same reference numerals, and descriptions thereof will not be repeated.
(First Embodiment)
The grid 9 is constituted of a plurality of sheets of electrodes. In the present invention, the grid 9 is constituted of three sheets of electrodes as shown in, for example,
The grid 9 is preferably formed of a material having resistance against a reactive gas. Examples of the material of the grid 9 include molybdenum and titanium, or the like. The grid 9 may be formed of other material than those exemplified, and its surface may be coated with molybdenum or titanium.
The substrate processing chamber 1 includes a substrate holder 15 connected to an Electrostatic Chuck (ESC) electrode (not shown). The ESC electrode allows a substrate 11 placed on the substrate holder 15 to be fixed by electrostatic attraction. As other substrate fixing means, various fixing means such as clamp supporting may be used. A process gas is introduced from the gas introduction portion 5, and a high frequency wave is applied to the RF antenna 6, whereby a plasma of the process gas can be generated in the plasma generation chamber 2. Then, a direct-current voltage is applied to the grid 9 to extract ions as a beam from the plasma generation chamber 2, and, thus, to apply the ion beam to the substrate 11, whereby the substrate 11 is processed. The extracted ion beam is electrically neutralized by the neutralizer 13 and applied to the substrate 11.
The substrate holder 15 allows the substrate 11 to rotate (on its axis) in its in-plane direction. The substrate holder 15 has rotation control means for controlling a rotation speed of the substrate, the number of times of rotation of the substrate, and inclination of the substrate holder 15 relative to the grid 9 and means for detecting a rotation position of the substrate 11. The substrate holder 15 may further have means allowing detection of inclination of the substrate holder 15 relative to the grid 9 and a rotation start position of the substrate 11. In this embodiment, the substrate holder 15 is equipped with a position sensor 14 as position detection means, and the position sensor 14 can detect the rotation position of the substrate 11. As the position sensor 14, a rotary encoder is used.
The substrate 11 is carried into the substrate processing chamber 1 through a substrate carry-in entrance 16 and held on a placing surface of the substrate holder 15 while keeping its horizontal state. The substrate holder 15 can arbitrarily incline relative to an ion beam. The substrate 11 is constituted of a disk-shaped silicon wafer, for example.
Next, an example of a structure of a TMR element produced according to the present invention will be described using FIG. 2.
Then, an Ru layer as a nonmagnetic interlayer 30, a fourth reference layer 31, and a Ta layer 32 as a cap layer 32 are film-formed. The fourth reference layer 31 has a laminate structure containing Co and Pd alternately laminated fourteen times.
As shown in
The element isolation according to the present invention means a state in which films deposited on a substrate are patterned in sequence from the top, and at least films up to an insulating film functioning as a tunnel barrier layer arc patterned.
An IBE method according to the present invention for efficiently removing noble metal atoms contained in the re-deposited film will be hereinafter described using
The sputtering rate to various rare gases of each material was calculated by using a method described in “Energy Dependence of the Yields of Ion-Induced Sputtering of Monatomic Solids” (N. Matsunami and eight other persons, IPPJ-AM-32 (Institute of Plasma Physics, Nagoya University, Japan, 1983)).
As seen in
As seen in
As seen in
As seen in
Meanwhile, for Kr and Xe, it is found that Pt is electively etched with respect to Co. In particular, when the energy is reduced to not more than 100 eV, the selectivity of Pt to Co is more noticeable.
As seen in the results shown in
The lower the ion energy, the greater each selectivity of Kr and Xe to noble metal. Meanwhile, the lower the ion energy, the lower the etching rate of each material. Therefore, it is preferable for improving the productivity that the ion energy is as high as possible. When IBE is performed using Xe, noble metal can be selectively etched even with relatively high energy in comparison with Kr, and therefore, it is very advantageous in terms of the productivity.
Considering to the selectivity of etching to noble metal and etching rate, it is preferable that the ion energy is set to not less than 10 eV and not more than 100 eV. This is because in the ion energy set to not more than 10 eV, the sputtering rate to a re-deposited film is small, and processing takes time.
The removal of noble metal atoms in a re-deposited film by IBE is excellent in terms of process stability.
Meanwhile, in IBE, a spread of the energy of each ion in the ion beam is small as shown in
Hereinafter, the process for producing a TMR element according to the present invention including a process for removing noble metal atoms from a re-deposited film will be described using a specific production process.
As shown in
After the film formation of the cap layer 45, element isolation is performed through a predetermined lithography process and a predetermined etching process, as shown in
Then, the TMR element formed with the re-deposited film 46 is irradiated with ion beams using Xe ions, as shown in
(Second Embodiment)
In the above embodiment, the re-deposited film 46 is removed by the IBE processing using Xe ions, or the noble metal material is selectively removed from the re-deposited film 46 to reduce the short-circuiting between the free layer 42 and the reference layer 44. Meanwhile, in this embodiment, the IBE processing using an O2 gas is performed after the IBE processing using Xe ions, whereby the re-deposited film 46 becomes an insulator. According to this embodiment, since the re-deposited film 46 is actively changed into an insulator by chemical reaction, the short-circuiting between the free layer 42 and the reference layer 44 can be reduced more reliably.
The process shown in
In this embodiment, the TMR element formed with a re-deposited film 46 is irradiated with ion beams using Xe ions, as shown in
After that, as shown in
In the process shown in
As to an oxidation process after the process using a Xe gas shown in
However, it is preferable that the process using the Xe gas in
(Third Embodiment)
In the above embodiment, the IBE processing using the O2 gas is performed after the IBE processing using Xe ions, whereby the re-deposited film 46 becomes an insulator. Meanwhile, in this embodiment, a plasma of a mixed gas of Xe and O2 is formed, and an ion beam is formed from the plasma to apply the IBE processing to the re-deposited film 46, whereby removal of noble metal atoms from the re-deposited film 46 and conversion of the re-deposited film 46 into an insulator are performed simultaneously.
The process shown in
As shown in
As in this embodiment, when a mixed gas of Xe and O2 is supplied into a plasma generation chamber to form a plasma, the behavior of atoms in the plasma will be described.
As ions extracted from a plasma of an O2 gas, there are mainly two kinds of ions. One is O2+ produced by ionization of an oxygen molecule, and the other is O+ produced by dissociative ionization of an oxygen molecule. The abundance of O2+ is larger than the abundance of O+. The abundance ratio of rare gas ions to oxygen molecule ions determined when an O2 gas and a rare gas are mixed is determined by a ratio of an ionization cross section area of the oxygen molecule to the ionization cross section area of the rare gas. Although the ionization cross section area of Xe is about three times the ionization cross section area of oxygen, the ionization cross section area of Ar is about 0.9 time the ionization cross section area of oxygen, and therefore, the abundance ratio of oxygen ions and rare gas ions in a plasma is different between Xe and Ar, as shown in
As seen in
It is preferable that the re-deposited film 46 formed on a side wall of the TMR element is generally thin thickness, and that the oxidation reaction of the re-deposited film 46 is precisely controlled. When the re-deposited film 46 is excessively oxidized, the oxidation reaction occurs in a film constituting the TMR element inside the re-deposited film 46, and this deteriorates the element characteristics.
As in this embodiment, when the mixed gas of a Xe gas and an O2 gas is used, the rate of oxygen ions in a plasma can be reduced in comparison with a case of using a mixed gas of an Ar gas and an O2 gas or using an O2 gas singly. Thus, a ratio of oxidizability to an O2 gas introduction amount is reduced, and when the O2 gas introduction amount fluctuates, oxidation processing of the re-deposited film 46 is less likely to be affected. Consequently, it is possible to improve uniformity of TMR element characteristics for each substrate.
Further, it is possible to stably perform oxidation processing with respect to fluctuation of each introduction amount of an O2 gas and a Xe gas, a change in a plasma density, and a minute change in process conditions, such as temperature changes in the bell jar 4 and the grid 9, determined when the IBE processing is performed.
Meanwhile, when the supply of active oxygen fails in the processing using a mixed gas of a Xe gas and an O2 gas, a supply source may be provided separately. When an excessive amount of active oxygen is supplied, the content of an O2 gas is reduced to the minimum necessary, whereby damage due to oxygen ion irradiation can be further reduced. When the content of an O2 gas in a mixed gas is reduced, a change in oxidizability due to fluctuation of the O2 gas introduction amount easily appears, and therefore this embodiment is effective particularly.
In the above embodiment, although an O2 gas is used for oxidizing the re-deposited film 46, other oxygen-containing gases such as N2O, CO2, O3, and H2O may be used.
(Fourth Embodiment)
In the second embodiment, the IBE processing is performed using an oxygen-containing gas to oxidize the re-deposited film 46, and, thus, to convert the re-deposited film 46 into an insulator. Meanwhile, in this embodiment, the IBE processing is performed using a nitrogen-containing gas to convert the re-deposited film 46 as a nitride into an insulator. More specifically, in the process shown in
In this process, only an N2 gas may be introduced into a plasma generation chamber to produce a plasma, and, thus, to apply an ion beam. However, it is preferable in terms of control of a nitriding rate of the re-deposited film 46, a mixed gas of an N2 gas and a rare gas is preferably used. At this time, as a gas to be mixed with the N2 gas, any rare gas may be used.
The process for removing noble metal atoms from the re-deposited film 46 using a Xe gas and the process for nitriding the re-deposited film 46 using an N2 gas may be continuously performed by changing a gas introduced into the plasma generation chamber. For example, after the IBE process using a Xe gas is performed for a certain time, an N2 gas is introduced into the plasma generation chamber in addition to the Xe gas, and the nitriding process may be performed subsequently. When the N2 gas is thus introduced into the plasma generation chamber while maintaining the plasma by the Xe gas in the plasma generation chamber, processing time can be reduced.
(Fifth Embodiment)
In the fourth embodiment, after the IBE processing using Xe ions is performed, the IBE processing is performed using an N2 gas, whereby the re-deposited film 46 becomes an insulator. In this embodiment, a plasma of a mixed gas of Xe and N2 is formed, and an ion beam is formed from the plasma to apply the IBE processing to the re-deposited film 46, whereby removal of noble metal atoms from the re-deposited film 46 and conversion of the re-deposited film 46 into an insulator are performed simultaneously. More specifically, in the process shown in
As in this embodiment, when a mixed gas of Xe and N2 is supplied into a plasma generation chamber to form a plasma, the behavior of atoms in the plasma will be described.
As ions extracted from a nitrogen gas plasma, there are mainly two kinds of ions. One is N2+ produced by ionization of a nitrogen molecule, and the other is N+ produced by dissociative ionization of a nitrogen molecule. The abundance of N2+ is arger than the abundance of N+. Since the ionization cross section area of the nitrogen molecule is substantially equal to the ionization cross section area of an oxygen gas, the abundance ratio of rare gas ions to nitrogen molecule ions determined when an N2 gas and a rare gas are mixed is different between Xe and Ar, substantially similarly to the case of mixing an O2 gas in
As seen in
It is preferable that the re-deposited film 46 formed on a side wall of the TMR element is generally thin thickness, and that nitrogen reaction of the re-deposited film 46 is precisely controlled. Usually, a nitriding reaction rate of metal is extremely lower than an oxidation reaction rate, and it is difficult to perform surface nitriding using only an N2 gas. However, nitriding is achieved by using nitrogen ions in a plasma or atomic nitrogen.
When the nitriding rate of the re-deposited film 46 is very high, when an etching process including nitrogen is performed, nitriding reaction occurs in a film constituting a TMR element inside the re-deposited film 46, and the element characteristics may be deteriorated.
As in this embodiment, when a mixed gas of a Xe gas and an N2 gas is used, it is possible to prevent the process for converting the re-deposited film 46 into an insulator from being applied to inside of the element in comparison with a case of using a mixed gas of an Ar gas and an O2 gas or using an N2 gas singly. Consequently, it is possible to improve uniformity of TMR element characteristics for each substrate.
Further, it is possible to stably perform nitriding processing with respect to fluctuation of each introduction amount of an N2 gas and a Xe gas, a change in a plasma density, and a minute change in process conditions, such as temperature changes in the bell jar 4 and the grid 9, determined when the IBE processing is performed.
Meanwhile, when the supply of active nitrogen fails in the processing using a mixed gas of an Ar gas and an N2 gas, a supply source may be provided separately. When an excessive amount of active nitrogen is supplied, the content of nitrogen is reduced to the minimum necessary, whereby damage due to nitrogen ion irradiaLion can be further reduced. When the content of an N2 gas in a mixed gas is reduced, a change in a nitriding power due to fluctuation of an N2 gas introduction amount easily appears, and therefore this embodiment is effective particularly.
When nitriding reaction is performed, a nitrogen-containing gas other than an N2 gas is introduced into the plasma generation chamber to form a plasm, and an ion beam extracted from the plasma can be applied to the re-deposited film 46. In order to perform nitriding at a practical rate, atomic nitrogen or its ion is used rather than a nitrogen molecule or its ions. Accordingly, when an amount of atomic nitrogen produced by dissociation of an N2 gas is small, a mixed gas of ammonia or nitrogen and hydrogen is preferably used as a gas containing nitrogen. In a gas, such as N2O, containing nitrogen and oxygen, a generation speed of an oxide is significantly higher than the generation speed of a nitride, and thus this gas is not suitable for a nitriding gas.
Number | Date | Country | Kind |
---|---|---|---|
2012-254446 | Nov 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2013/080374 | 11/11/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2014/080782 | 5/30/2014 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
7745324 | Yang | Jun 2010 | B1 |
8975089 | Jung | Mar 2015 | B1 |
20040020894 | Williams | Feb 2004 | A1 |
20050048675 | Ikeda | Mar 2005 | A1 |
20080073750 | Kanaya | Mar 2008 | A1 |
20100155231 | Watanabe et al. | Jun 2010 | A1 |
20110198314 | Wang | Aug 2011 | A1 |
20120052258 | Op De Beeck | Mar 2012 | A1 |
20120244639 | Ohsawa | Sep 2012 | A1 |
20120326252 | Yamakawa | Dec 2012 | A1 |
20130069182 | Ohsawa et al. | Mar 2013 | A1 |
20130248355 | Ohsawa | Sep 2013 | A1 |
20130288394 | Kontos | Oct 2013 | A1 |
Number | Date | Country |
---|---|---|
1 926 158 | May 2008 | EP |
11-330589 | Nov 1999 | JP |
2003-078184 | Mar 2003 | JP |
2005-268349 | Sep 2005 | JP |
2011-166157 | Aug 2011 | JP |
2013-069788 | Apr 2013 | JP |
2013-197397 | Sep 2013 | JP |
I 413117 | Oct 2013 | TW |
Entry |
---|
Written Opinion of the International Searching Authority (PCT/ISA/237) mailed on Feb. 4, 2014, by the Japanese Patent Office as the International Searching Authority for International Application No. PCT/JP2013/080374 (w/English translation—8 total pages). |
English Translation of the Taiwan Office Action for Taiwan Application No. 102142082 dated Mar. 27, 2015. |
D.C. Worledge et al., “Spin torque switching of perpendicular Ta | CoFeB | MgO-based magnetic tunnel junctions”, Applied Physics Letters, 2011, 022501-1 through 022501-3, vol. 98. (3 pages). |
International Search Report (PCT/ISA/210) mailed on Feb. 4, 2014, by the Japanese Patent Office as the International Searching Authority for International Application No. PCT/JP2013/080374. |
Taiwan Office Action for Taiwan Application No. 102142082 dated Mar. 27, 2015. |
Office Action (Notification of Reasons for Refusal) issued on Jul. 5, 2016, by the Japanese Patent Office in corresponding Japanese Patent Application No. 2014-548515, and English Translation of the Office Action. (6 pages). |
Office Action issued in corresponding Chinese Patent Application No. 201380060677.8, dated Sep. 8, 2016, and English Translation (12 pages). |
Number | Date | Country | |
---|---|---|---|
20150311432 A1 | Oct 2015 | US |