JP4259000B2 - Dielectric thin film forming solution raw material and dielectric thin film forming method using the raw material. - Google Patents

Description

【００３２】
表１より明らかなように、添加剤を含まない溶液原料を用いた比較例１では成膜再現性が悪く、表面モフォロジーも安定していない。また、添加剤である水の添加量が本発明の範囲外である比較例２及び３では、図３〜図５に示すように、膜質にばらつきが見られ、トレンチ底部のみに膜が形成されたり、トレンチ以外での薄膜が異常成長したりして、表面モフォロジーも安定していなかった。これに対して実施例１及び２では、図１に示すように、本発明の溶液原料を用いて形成された誘電体薄膜は、成膜再現性が良く、表面モフォロジーも安定化していることが判る。
【００３３】
【発明の効果】
以上述べたように、本発明の誘電体薄膜形成用溶液原料は、有機金属化合物原料と、テトラヒドロフランからなる有機溶媒とを混合してなる原料液に添加剤として水を１０〜２００ｐｐｍ含む誘電体薄膜形成用溶液原料であって、有機金属化合物がビス（ジピバロイルメタナト）バリウム錯体、ビス（ジピバロイルメタナト）ストロンチウム錯体及びビスイソプロポキシビスジビバロイルメタナートチタン錯体からなることにより、この水が有機金属化合物の分子内及び分子間相互作用を抑制するため、この溶液原料を用いて形成した誘電体薄膜の成膜再現性を向上し、かつ表面モフォロジーを安定化される。
【図面の簡単な説明】
【図１】本発明の誘電体薄膜形成用溶液原料を用いて基板上に形成された誘電体薄膜のトレンチ周辺の表面モフォロジーを示す図。
【図２】ＭＯＣＶＤ装置の概略図。
【図３】従来の誘電体薄膜形成用溶液原料を用いて基板上に形成された誘電体薄膜のトレンチ周辺の表面モフォロジーを示す図。
【図４】従来の別の誘電体薄膜形成用溶液原料を用いて基板上に形成された誘電体薄膜のトレンチ周辺の表面モフォロジーを示す図。
【図５】従来の更に別の誘電体薄膜形成用溶液原料を用いて基板上に形成された誘電体薄膜のトレンチ周辺の表面モフォロジーを示す図。
【符号の説明】
１３ 基板
１５ 誘電体薄膜[0001]
BACKGROUND OF THE INVENTION
In the present invention, a complex oxide dielectric thin film used for a dielectric memory such as a DRAM (Dynamic Random Access Memory) or a dielectric filter is referred to as a metal organic chemical vapor deposition (hereinafter referred to as MOCVD). ) Is a solution raw material for forming a dielectric thin film. More specifically, the present invention relates to a solution raw material for forming a dielectric thin film that improves the reproducibility of the formed film and stabilizes the surface morphology.
[0002]
[Prior art]
In recent years, high integration has been progressing rapidly for the purpose of increasing the speed, lowering power consumption, and reducing the cost of memory devices such as DRAMs in semiconductors. However, no matter how much the degree of integration is improved, a capacitor, which is a component such as a DRAM, must have a certain capacity. As the degree of integration of memory devices increases at a rapid pace, it is necessary to reduce the thickness of the dielectric thin film used as a capacitor. With conventional SiO ₂ , it is difficult to ensure a certain capacity at the same time as the film thickness is reduced. is there. Therefore, if the dielectric constant can be increased by changing the material, it is possible to secure the same capacity as in the case of thinning. Therefore, research on the use of dielectric materials with a high dielectric constant as the dielectric film of capacitors for memory devices. Has recently attracted attention. As performance required for such a memory capacitor material, it is most important that the thin film has a high dielectric constant as described above and that the leakage current is small. That is, as long as a high dielectric constant material is used, it is necessary to make the film as thin as possible and minimize the leakage current.
[0003]
From this point of view, use of a composite oxide-based dielectric material made of an oxide containing two or more metals having a higher dielectric constant has been studied. Examples of such dielectric materials include lead titanate (PT), lead zirconate titanate (PZT), lead lanthanum zirconate titanate (PLZT), strontium titanate (ST), barium titanate (BT), titanium And barium strontium acid (BST).
As an organic metal compound used as a raw material for the dielectric thin film, a β-diketone compound such as dipivaloylmethane ((CH ₃ ) ₃ CCOCH ₂ COC (CH ₃ ) ₃ , hereinafter referred to as dpm) is used as a ligand. Organometallic complexes and metal alkoxides such as [Zr (Ot-Bu) ₄ ] are generally used. Both metal alkoxides and β-diketonato complexes are used for metal raw materials such as Ti, Zr, and Ta, and β-diketonato complexes are mainly used as metal raw materials for Sr and Ba.
[0004]
β-diketonato complexes are generally susceptible to deterioration under the influence of moisture and carbon dioxide in the air. In addition, it tends to be altered, for example, an oligomer is formed during storage, the molecular weight is increased, and the evaporation temperature is increased. For example, although dpm is a typical β-diketone compound, its metal complexes [Ba (dpm) ₂ ] and [Sr (dpm) ₂ ] are stored in a desiccator when they are stored. Even if it is paid, a change is observed in TG (Thermogravimetry), and it is extremely unstable. Accordingly, the β-diketonato complex requires careful attention to prevent deterioration during storage and handling, and has poor operability as a raw material.
Therefore, long-term storage stability has been achieved by increasing the purity of the organometallic compound as a means for suppressing deterioration of the organometallic compound as a raw material.
[0005]
As a method of forming a complex oxide dielectric thin film, a sol-gel method in which a metal alkoxide raw material is formed on a substrate by spin coating has been actively studied so far. In the sol-gel method, the composition of the film is easy to control because the metal component is not vaporized. However, DRAM capacitor electrodes have a step, and the higher the degree of integration, the larger the step and the more complicated. Therefore, it is difficult to form a dielectric thin film uniformly on the electrode serving as a substrate by the spin coating method. Therefore, in the past few years, in anticipation of high device integration, a dielectric thin film is formed by the MOCVD method which has excellent step coverage (= step coverage, coverage to a complicated surface with steps). Research has been activated.
[0006]
The MOCVD method heats and vaporizes organometallic compounds, which are raw materials for various metals, under reduced pressure, transports the vapor to a film formation chamber, and thermally decomposes the resulting metal oxide on the substrate. It is the method of attaching to. The MOCVD method is generally performed because it has excellent step coverage as compared with other film manufacturing methods.
In the formation of the dielectric thin film by this MOCVD method, the raw material organometallic compound was initially heated and vaporized as it was, and the generated vapor was sent to the film forming chamber to form a film. However, organometallic compound raw materials, especially compounds such as dpm complexes recommended for MOCVD, do not have good long-term storage stability and vaporization characteristics, and can stably transport the raw materials to the CVD reaction section by heating at low temperatures. Was impossible. Further, if heating is performed at a high temperature in order to increase the vaporization efficiency of the raw material, the raw material is transported while thermally decomposing before reaching the film formation chamber, resulting in poor crystallinity and compositional deviation of the film. Therefore, it is difficult to stably transport organometallic compound raw materials to the film formation chamber, expensive raw materials become disposable after each film formation, and film composition control is difficult, and good dielectric properties. There is also a problem that a dielectric film having a thickness cannot be formed. Further, in this method, when the vaporization rate is suppressed and the synthesis (reaction) time is lengthened, the stability of the raw material deteriorates with time and the vaporization property gradually decreases. It was inevitable that the composition in the thickness direction became inhomogeneous and the leakage current increased.
[0007]
As a method for solving such a problem, a solution vaporization CVD method capable of stably supplying a raw material organometallic compound to a film formation chamber is widely used. This solution vaporization CVD method is an improvement of the MOCVD method, in which a solid CVD raw material is dissolved in various organic solvents and supplied as a liquid to a CVD apparatus.
[0008]
[Problems to be solved by the invention]
However, although the effect of improving the long-term storage stability of the solution raw material was obtained by purifying the organometallic compound as a raw material, a dielectric thin film was formed on the substrate using this highly purified raw material by the MOCVD method. In this case, variation in film quality between material lots, as shown in FIGS. 3 to 5, the thin film 2 is formed only on the trench and the bottom of the substrate 1, or significant grain growth occurs on the film surface. So-called abnormal film growth has been observed. 3 is a diagram in which no thin film is formed at the bottom of the trench, and the thin film formed outside the trench is abnormally grown, FIG. 4 is a diagram in which the thin film formed at the bottom of the trench is abnormally grown, and FIG. It is the figure which the thin film grew abnormally so that a trench might be covered.
[0009]
An object of the present invention is to provide a solution raw material for forming a dielectric thin film capable of improving the film reproducibility of the formed dielectric thin film and stabilizing the surface morphology.
[0010]
[Means for Solving the Problems]
The invention according to claim 1, the organic metal compound precursor, tetrahydrofuran dielectric thin film formation containing water 10~200ppm as an additive to the raw material solution formed by combining an organic solvent consisting of (hereinafter. Referred to THF) A solution raw material, wherein the organometallic compound is composed of a bis (dipivaloylmethanato) barium complex, a bis (dipivaloylmethanato) strontium complex, and a bisisopropoxybisdibivaloylmethanate titanium complex It is a solution raw material for forming a dielectric thin film.
In the invention which concerns on Claim 1, this water suppresses the intramolecular and intermolecular interaction of an organometallic compound by including 10-200 ppm of water as an additive in the raw material liquid which melt | dissolved the organometallic compound raw material in the organic solvent. Therefore, the dielectric thin film formed using this solution raw material has good film formation reproducibility, and the surface morphology is stabilized. The amount of water added is 10 to 200 ppm. Preferably it is 90-150 ppm. When the addition amount is less than the lower limit value, intramolecular and intermolecular interactions of the organometallic compound cannot be suppressed, and effects such as improvement in film reproducibility and stabilization of surface morphology do not appear. When the addition amount exceeds the upper limit value, the formed thin film causes abnormal growth.
[0012]
The invention according to claim 2, as shown in FIG. 2, in a way to form a composite oxide dielectric thin film 15 on the substrate 13 by metal organic chemical vapor deposition using a raw material solution according to claim 1 Symbol placement is there.
The invention according to claim 3 is the invention according to claim 2 , wherein the formation of the dielectric thin film by the metal organic chemical vapor deposition method is performed by supplying a solution raw material to the vaporization chamber in a liquid state.
The invention according to claim 4 is the invention according to claim 3 , which is a method of supplying separate solution raw materials for each metal to the vaporizing chamber.
In the invention according to 4 or to claims 2, good deposition reproducibility by forming a dielectric thin film of a composite oxide on a substrate by MOCVD method using the raw material solution according to claim 1 Symbol placement, surface A dielectric thin film having a stabilized morphology can be obtained.
[0013]
The invention according to claim 5 is a dielectric thin film made of barium strontium titanate formed on a substrate by the method according to any one of claims 2 to 4 .
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Next, an embodiment of the present invention will be described.
The dielectric thin film of a composite oxide which may be formed according to a solution raw material according to the present invention, a titanium barium strontium (BST).
[0015]
In the case of a BST thin film, Ti, Ba, and Sr organometallic compounds are used as raw materials.
[0016]
The organic metal compound raw material is vaporizable and is thermally decomposed by heating and easily converted into an oxide by introducing an oxidant (oxygen). Such an organometallic compound is generally a compound having a structure in which a metal atom is bonded to an organic group through an oxygen atom. Examples of this type of preferred compound include metal alkoxides, metal β-diketonato complexes, mixtures of metal alkoxides and β-diketonato complexes, and the like. Examples of β-diketonato complexes include metal complexes having β-diketones such as acetylacetone, hexafluoroacetylacetone, dpm, pentafluoropropanoylpivaloylmethane, etc. as ligands. Among these, a complex with dpm is preferable. As the metal alkoxide, those having 1 to 6 carbon atoms of the alkoxy group are preferable, and those having a branched alkoxy group (isopropoxide, tert-butoxide, etc.) are particularly preferable. Particularly preferred organometallic compounds are metal dipivaloylmethanato complexes, metal isopropoxides, metal tert-butoxide, mixtures of metal isopropoxide and dipivaloylmethanato complexes, metal tert-butoxide and dipivaloylmethanato It is a mixture of complexes. For alkaline earth metals, alkali metals, and Pb, β-diketonato complexes (for example, dipivaloylmethanato complexes) are preferred. For transition metals such as Ti, Zr, V, and Nb, β-diketonato complexes are generally used. And a metal alkoxide can be used, and a mixture of a metal alkoxide and a β-diketonato complex can also be used.
[0017]
As a raw material for forming a BST thin film, dipivaloylmethanato complexes of Ba and Sr, isopropoxide, tert-butoxide, dipivaloylmethanato complex, a mixture of isopropoxide and dipivaloylmethanato complex, and tert It is preferred to use a Ti compound selected from a mixture of butoxide and dipivaloylmethanato complex .
[0018]
Examples of the organic solvent include one or more selected from the group consisting of THF, methyltetrahydrofuran, n-octane, isooctane, hexane, cyclohexane, pyridine, lutidine, butyl acetate, and amyl acetate. Preferably it is THF.
[0019]
The solution raw material for forming a dielectric thin film of the present invention is characterized by containing 10 to 200 ppm of water as an additive in a raw material liquid obtained by mixing one or more organic metal compound raw materials and an organic solvent. .
[0020]
For example, a raw material liquid obtained by mixing [Ba (dpm) ₂ ] as an organometallic compound and THF as an organic solvent and dissolving the organometallic compound in the organic solvent has a metal element Ba in [Ba (dpm) ₂ ]. Since the α orbit is electronically empty, the metal Ba and the ligand dpm cause bond cleavage in the organometallic compound molecule (intramolecular cleavage), and the metal Ba is intercalated between the molecules. Polymerization occurs between the ligands dpm and the quantity is increased. Since the oligomers that have increased in quantity are thermally unstable, when vaporized in the vaporization chamber of the CVD apparatus, they are heated and separated into indeterminate small molecules and organic compounds. Molecules that are partially oligomers are supplied at the same time. Therefore, the dielectric thin film formed on the substrate does not have film formation reproducibility on the step-coated surface in sub-micron units, and surface roughness occurs, resulting in a morphological abnormality.
[0021]
By including 10 to 200 ppm of water as an additive in this raw material liquid, water has a coordination property to the metal Ba, thereby bringing about a trap effect on the empty α orbit of the metal element and forming an intermolecular polymer. Therefore, stable vaporization at the time of thin film formation is maintained, film reproducibility of the formed dielectric thin film is improved, and the morphology of the thin film surface is stabilized. Although the organometallic compound containing Ba has been described as an example, the same coordination stabilization effect can be obtained with an organometallic compound containing Sr (for example, [Sr (dpm) ₂ ]).
[0022]
In the case of an organometallic compound containing Ti (for example, [Ti (Oi-Pr) ₂ (dpm) ₂ ]), polymerization into an oxonium complex is caused by water, and the transition or arrangement of the Ti compound into a hydroxyl complex is caused. As a result, the Ti complex after polymerization is more stable, has better steric hindrance and adhesion to the substrate, and the initial growth of TiO ₂ is conformal and easy. Occur. Furthermore, the effect on the metal Ti is considered to have a synergistic effect with the effect of stabilizing the coordination of the metal Sr and the metal Ba.
[0023]
As a method for preparing the solution raw material of the present invention, two or more kinds of organometallic compounds containing each metal element constituting the dielectric thin film are dissolved together or separately in an organic solvent, and water is further added as an additive. A solution raw material used for forming a dielectric thin film by MOCVD is prepared by containing 10 to 200 ppm. Using this solution raw material, a dielectric thin film is formed on a substrate or other substrate by MOCVD. In this embodiment, the MOCVD method uses a solution vaporization CVD method in which each solution is supplied to a heated vaporization chamber, where each solution raw material is instantaneously vaporized and sent to a film formation chamber.
[0024]
As shown in FIG. 2, the MOCVD apparatus includes a chamber 10 and a steam generator 11. A heater 12 is provided inside the chamber 10, and a substrate 13 is held on the heater 12. The inside of the chamber 10 is evacuated by a pipe 17 having a pressure gauge 14 and a needle valve 16. The steam generator 11 includes a raw material container 18, and the raw material container 18 dissolves an organometallic compound in an organic solvent and further stores a solution raw material containing an additive. A carrier gas introduction pipe 21 is connected to the raw material container 18 through a gas flow rate control device 19, and a supply pipe 22 is connected to the raw material container 18. The supply pipe 22 is provided with a needle valve 23 and a solution flow rate adjusting device 24, and the supply pipe 22 is connected to the vaporization chamber 26. A carrier gas introduction pipe 29 is connected to the vaporizing chamber 26 via a needle valve 31 and a gas flow rate adjusting device 28. The vaporizing chamber 26 is further connected to the chamber 10 by a pipe 27.
In this apparatus, a carrier gas composed of an inert gas such as N ₂ , He, Ar is introduced into the raw material container 18 from the carrier gas introduction pipe 21, and the solution raw material stored in the raw material container 18 is vaporized by the supply pipe 22. It is conveyed to the chamber 26. The organometallic compound vaporized in the vaporizing chamber 26 and converted into vapor is further supplied into the chamber 10 through the pipe 27 by the carrier gas introduced into the vaporizing chamber 26 from the carrier gas introduction pipe 28. In the chamber 10, the vapor of the raw organometallic compound is thermally decomposed, and the metal oxide generated thereby is deposited on the heated substrate 13 to form a dielectric thin film.
[0025]
In the solution raw material of the present invention, the vaporization property of each raw material compound in a solution state is stable, and the metal atomic ratio of the formed thin film is almost the same as the metal atomic ratio in the solution. A complex oxide dielectric thin film can be formed, and the quality of the film is stabilized.
[0026]
The dielectric thin film formed by the MOCVD method using the solution raw material of the present invention is useful as a capacitor for DRAM. Although the MOCVD method is generally excellent in step coverage, the use of the solution raw material of the present invention improves the film reproducibility and stabilizes the surface morphology as compared with a thin film formed using a conventional solution raw material.
In addition, since the solution raw material of the present invention can stably supply the vapor of each raw material compound to the film formation chamber as described above, it has excellent film composition controllability, and has a desired composition and dielectric characteristics. The body thin film can be stably formed on the substrate. The dielectric thin film formed using the solution raw material of the present invention can also be used as a dielectric filter for a piezoelectric resonator, an infrared sensor, or the like.
[0027]
【Example】
Next, examples of the present invention will be described together with comparative examples.
<Example 1>
First, bis (dipivaloylmethanato) barium complex [Ba (dpm) ₂ ] as the organic barium compound, bis (dipivaloylmethanato) strontium complex [Sr (dpm) ₂ ] as the organic strontium compound, and organic titanium compound Bisisopropoxybisdibivaloylmethanate titanium complex [Ti (Oi-Pr) ₂ (dpm) ₂ ] was prepared. Moreover, THF was prepared as an organic solvent and water was used as an additive.
Next, each organic metal compound raw material and THF are mixed to prepare a raw material liquid in which each organic metal compound raw material is dissolved in THF. Further, 100 ppm of water is added to this raw material liquid to thereby prepare a BST dielectric thin film solution raw material. Was prepared.
[0028]
<Example 2>
A solution raw material for a BST dielectric thin film was prepared in the same manner as in Example 1 except that the amount of water added was 200 ppm.
[0029]
<Comparative Example 1>
A solution raw material for a BST dielectric thin film was prepared in the same manner as in Example 1 except that the additive was not added.
<Comparative example 2>
A solution raw material for a BST dielectric thin film was prepared in the same manner as in Example 1 except that the amount of water added was 5 ppm.
<Comparative Example 3>
A solution raw material for a BST dielectric thin film was prepared in the same manner as in Example 1 except that the amount of water added was 210 ppm.
[0030]
<Comparison evaluation>
The BST dielectric thin film solution raw materials prepared in Examples 1 and 2 and Comparative Examples 1 to 3 were each divided into two and introduced into an MOCVD apparatus as shown in FIG. Each type was formed. Deposition reproducibility of two types of BST dielectric thin films formed of the same material on the substrate surface using an atomic force microscope (AFM) or a scanning tunneling microscope (hereinafter referred to as STM). The film quality of the formed thin film was measured. Moreover, the surface of the formed dielectric thin film was observed, and the surface morphology was investigated.
Table 1 shows the long-term storage stability of the solution raw materials for the BST dielectric thin film of Examples 1-2 and Comparative Examples 1-3, the film formation reproducibility of the formed dielectric thin film, and the surface morphology, respectively.
[0031]
[Table 1]

[0032]
As is clear from Table 1, the film formation reproducibility is poor and the surface morphology is not stable in Comparative Example 1 using a solution raw material containing no additive. Further, in Comparative Examples 2 and 3 in which the amount of water as an additive is outside the scope of the present invention, as shown in FIGS. 3 to 5, the film quality varies, and a film is formed only at the bottom of the trench. The thin film other than the trench grew abnormally, and the surface morphology was not stable. In contrast, in Examples 1 and 2, as shown in FIG. 1, the dielectric thin film formed using the solution raw material of the present invention has good film reproducibility and stable surface morphology. I understand.
[0033]
【The invention's effect】
Above As mentioned, the dielectric thin film-forming raw material solution of the present invention, the organic metal compound materials, dielectrics water containing 10~200ppm as an additive to the raw material solution formed by combining an organic solvent consisting of tetrahydrofuran A solution raw material for forming a thin film, wherein the organometallic compound is composed of a bis (dipivaloylmethanato) barium complex, a bis (dipivaloylmethanato) strontium complex and a bisisopropoxybisdibivaloylmethanato titanium complex Since this water suppresses the intramolecular and intermolecular interaction of the organometallic compound, the film reproducibility of the dielectric thin film formed using this solution raw material is improved and the surface morphology is stabilized.
[Brief description of the drawings]
FIG. 1 is a view showing a surface morphology around a trench of a dielectric thin film formed on a substrate using the dielectric material for forming a dielectric thin film of the present invention.
FIG. 2 is a schematic view of an MOCVD apparatus.
FIG. 3 is a view showing a surface morphology around a trench of a dielectric thin film formed on a substrate using a conventional solution raw material for forming a dielectric thin film.
FIG. 4 is a view showing a surface morphology around a trench of a dielectric thin film formed on a substrate using another conventional raw material for forming a dielectric thin film.
FIG. 5 is a view showing a surface morphology around a trench of a dielectric thin film formed on a substrate using still another conventional dielectric thin film forming solution raw material.
[Explanation of symbols]
13 Substrate 15 Dielectric thin film

Claims (5)

And organic metal compound precursor, a dielectric thin film-forming raw material solution containing 10~200ppm water as an additive to the raw material solution formed by combining an organic solvent consisting of tetrahydrofuran,
For forming a dielectric thin film characterized in that the organometallic compound is composed of a bis (dipivaloylmethanato) barium complex, a bis (dipivaloylmethanato) strontium complex, and a bisisopropoxybisdibivaloylmethanato titanium complex Solution raw material. How to form the substrate of the composite oxide on (13) the dielectric thin film (15) by metal organic chemical vapor deposition using a raw material solution according to claim 1 Symbol placement. The method according to claim 2 , wherein the formation of the dielectric thin film by the metal organic chemical vapor deposition method is performed by supplying the solution raw material in a liquid state to the vaporization chamber. The method according to claim 3 , wherein a separate solution raw material is supplied to the vaporization chamber for each metal. It claims 2 to dielectric thin film made of barium strontium titanate formed on the substrate by 4 method according to any one.

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