JP4329289B2 - SBT ferroelectric thin film, composition for forming the same, and method for forming the same - Google Patents

Description

【００４８】
【表２】

【００４９】
【表３】

【００５０】
【表４】

【００５１】
【表５】

【００５２】
【表６】

【００５３】
【表７】

【００５４】
【表８】

【００５５】
【表９】

【００５６】
表１〜９の通り、Ｂ組成無しのＮｏ．１（比較例）に対し、Ｂ組成を添加したＮｏ．２〜２４１（実施例）のものはいずれも結晶化温度が低い。また、Ｎｏ．２〜２４１の通り、Ｂ／Ａを大きくすることにより、結晶化温度がより低くなる。そして、Ｂ／Ａを０．２以上とし、特に０．３とすることにより、結晶化温度は十分に低くなる。結晶化温度が５５０℃となるようにＢ成分を添加したサンプルは、いずれも５５０℃焼成物の残留分極Ｐｒが十分に大きい値となっている。
【００５７】
実験Ｎｏ．２４２〜３１３
１）ＳＢＴＮ溶液の合成
有機溶剤としてジエチレングリコールを使用し、これに２−エチルへキサン酸Ｓｒ、２−エチルへキサン酸Ｂｉ、Ｔａエトキシド及び／或いはＮｂエトキシドを溶解し、溶媒沸点下で還流させながら生成してくる低沸点副生成有機物を蒸留留去しつつ１０時間反応させＳＢＴＮの複合金属有機化合物を合成した。この後、アセチルアセトンを金属合計量に対して１倍モル加え、溶媒沸点下で１時間還流反応を行い、粘度調整のためイソプロパノールで溶液を希釈し安定な表１０，１１のＳＢＴＮ組成のＳＢＴＮ薄膜形成剤を得た。
２）Ｂｉ−Ｓｉ溶液の合成
有機溶剤として十分に脱水したｎ−ブタノールを使用し、これに２−エチルへキサン酸ＢｉとＳｉエトキシドをモル比でＢｉ：Ｓｉ＝２：１となるように加えて溶解し、溶媒沸点下で２時間還流させＢｉ−Ｓｉの複合金属有機化合物を合成した。この後、アセチルアセトンを金属合計量に対して１倍モル加え、溶媒沸点下で１時間還流反応を行い、安定なＢｉ−Ｓｉ薄膜形成剤を得た。
３）Ｌａ−Ｓｉ溶液の合成
有機溶剤として十分に脱水したｎ−ブタノールを使用し、これに酢酸ランタン１．５水和物を溶解させ、共沸蒸留により結晶水を除去した。得られた溶液にモル比でＬａ：Ｓｉ＝２：１となるようにＳｉエトキシドを加えて溶解し、溶媒沸点下で２時間還流させＬａ−Ｓｉの複合金属有機化合物を合成した。この後、アセチルアセトンを金属合計量に対して１倍モル加え、溶媒沸点下で１時間還流反応を行い、安定なＬａ−Ｓｉ薄膜形成剤を得た。
【００５８】
上記Ｂｉ−Ｓｉ溶液とＬａ−Ｓｉ溶液を表１０，１１記載のＢ組成となるよう混合し、更にこの溶液とＳＢＴＮ溶液を表１０，１１に示すＢ／Ａ組成比となるよう混合し、溶媒沸点下で１時間還流反応を行い、安定なＳＢＴＮ−Ｂｉ−Ｌａ−Ｓｉ薄膜形成剤を得た。これら溶液を使用し、複合金属酸化物薄膜の成膜を行った。最終的な結晶化温度は４００，４５０，５００，５５０，６００℃でそれぞれ行い、組成により結晶化が何℃で起こっているかをＸＲＤで確認した。その結果を表１０，１１に示す。
【００５９】
【表１０】

【００６０】
実験Ｎｏ．３１４〜３８５
１）ＳＢＴＮ溶液の合成
有機溶剤としてプロピレングリコールを使用し、これにＳｒメタル、Ｂｉエトキシド、Ｔａエトキシド及び／或いはＮｂエトキシドを溶解し、溶媒沸点下で還流させながら生成してくる低沸点副生成有機物を蒸留留去しつつ５時間反応させＳＢＴＮの複合金属有機化合物を合成した。この後、アセチルアセトンを金属合計量に対して１倍モル加え、溶媒沸点下で１時間還流反応を行い、粘度調整のためｎ−ブタノールで溶液を希釈し安定な表１２，１３のＳＢＴＮ組成のＳＢＴＮ薄膜形成剤を得た。
２）Ｂｉ−Ｓｉ溶液の合成
有機溶剤として十分に脱水したｎ−ブタノールを使用し、これにＢｉエトキシドとＳｉエトキシドをモル比でＢｉ：Ｓｉ＝２：１となるように加えて溶解し、溶媒沸点下で２時間還流させＢｉ−Ｓｉの複合金属有機化合物を合成した。この後、アセチルアセトンを金属合計量に対して１倍モル加え、溶媒沸点下で１時間還流反応を行い、安定なＢｉ−Ｓｉ薄膜形成剤を得た。
３）Ｌａ−Ｓｉ溶液の合成
有機溶剤として十分に脱水したｎ−ブタノールを使用し、これに酢酸ランタン１．５水和物を溶解させ、共沸蒸留により結晶水を除去した。得られた溶液にモル比でＬａ：Ｓｉ＝２：１となるようにＳｉエトキシドを加えて溶解し、溶媒沸点下で２時間還流させＬａ−Ｓｉの複合金属有機化合物を合成した。この後、アセチルアセトンを金属合計量に対して１倍モル加え、溶媒沸点下で１時間還流反応を行い、安定なＬａ−Ｓｉ薄膜形成剤を得た。
【００６１】
上記Ｂｉ−Ｓｉ溶液とＬａ−Ｓｉ溶液を表１２，１３記載のＢ組成となるよう混合し、更にこの溶液とＳＢＴＮ溶液を表１２，１３に示すＢ／Ａ組成比となるよう混合し、溶媒沸点下で１時間還流反応を行い、安定なＳＢＴＮ−Ｂｉ−Ｌａ−Ｓｉ薄膜形成剤を得た。これら溶液を使用し、複合金属酸化物薄膜の成膜を行った。最終的な結晶化温度は４００，４５０，５００，５５０，６００℃でそれぞれ行い、組成により結晶化が何℃で起こっているかをＸＲＤで確認した。その結果を表１２，１３に示す。
【００６２】
【表１１】

【００６３】
【表１２】

【００６４】
実験Ｎｏ．３８６〜４５７
１）ＳＢＴＮ溶液の合成
有機溶剤としてジエチレングリコールを使用し、これに２−エチルへキサン酸Ｓｒ、２−エチルへキサン酸Ｂｉ、Ｔａエトキシド及び／或いはＮｂエトキシドを溶解し、溶媒沸点下で還流させながら生成してくる低沸点副生成有機物を蒸留留去しつつ１０時間反応させＳＢＴＮの複合金属有機化合物を合成した。この後、アセチルアセトンを金属合計量に対して１倍モル加え、溶媒沸点下で１時間還流反応を行い、粘度調整のためｎ−ブタノールで溶液を希釈し安定な表１４，１５のＳＢＴＮ組成のＳＢＴＮ薄膜形成剤を得た。
２）Ｂｉ−Ｓｉ溶液の合成
有機溶剤として十分に脱水したｎ−ブタノールを使用し、これに２−エチルへキサン酸ＢｉとＳｉエトキシドをモル比でＢｉ：Ｓｉ＝２．１：１となるように加えて溶解し、溶媒沸点下で２時間還流させＢｉ−Ｓｉの複合金属有機化合物を合成した。この後、アセチルアセトンを金属合計量に対して１倍モル加え、溶媒沸点下で１時間還流反応を行い、安定なＢｉ−Ｓｉ薄膜形成剤を得た。
３）Ｌａ−Ｓｉ溶液の合成
有機溶剤として十分に脱水したｎ−ブタノールを使用し、これに酢酸ランタン１．５水和物を溶解させ、共沸蒸留により結晶水を除去した。得られた溶液にモル比でＬａ：Ｓｉ＝２：１となるようにＳｉエトキシドを加えて溶解し、溶媒沸点下で２時間還流させＬａ−Ｓｉの複合金属有機化合物を合成した。この後、アセチルアセトンを金属合計量に対して１倍モル加え、溶媒沸点下で１時間還流反応を行い、安定なＬａ−Ｓｉ薄膜形成剤を得た。
【００６５】
上記Ｂｉ−Ｓｉ溶液とＬａ−Ｓｉ溶液を表１４，１５記載のＢ組成となるよう混合し、更にこの溶液とＳＢＴＮ溶液を表１４，１５に示すＢ／Ａ組成比となるよう混合し、溶媒沸点下で１時間還流反応を行い、安定なＳＢＴＮ−Ｂｉ−Ｌａ−Ｓｉ薄膜形成剤を得た。これら溶液を使用し、複合金属酸化物薄膜の成膜を行った。最終的な結晶化温度は４００，４５０，５００，５５０，６００℃でそれぞれ行い、組成により結晶化が何℃で起こっているかをＸＲＤで確認した。その結果を表１４，１５に示す。
【００６６】
【表１３】

【００６７】
【表１４】

【００６８】
【表１５】

【００６９】
表１０〜１５の通り、実験Ｎｏ．２４２〜４５７のものは、結晶化温度が十分に低い。
【００７０】
【発明の効果】
以上の通り、本発明によると、ＳＢＴ強誘電体薄膜の結晶化温度を低下させることができる薄膜形成用組成物と、薄膜形成方法と、この方法により形成された強誘電体薄膜とが提供される。[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an SBT ferroelectric thin film expected to be applied to various devices due to electrical or optical properties, a composition for forming the same, and a forming method.
[0002]
[Prior art]
  Strontium bismuth tantalate (SBT in a narrow sense) and strontium bismuth tantalum niobate (SBTN in a narrow sense) are expected to be applied to devices such as various capacitors and nonvolatile memories due to their high dielectric constant and excellent ferroelectric properties. . In this specification, SBT and SBTN are collectively referred to as SBT. As a method for forming these metal oxide thin films, there are a sputtering method, an MOCVD method, and the like. As a method for forming a thin film relatively inexpensively and simply, there is a sol-gel method in which an organic metal solution is applied to a substrate.
[0003]
  In the sol-gel method, after a raw material solution containing a hydrolyzable compound of each component metal as a raw material, a partial hydrolyzate thereof and / or a partial polycondensate thereof is applied to a substrate and the coating film is dried, A method of forming a ferroelectric thin film by heating to about 400 ° C. in air to form a metal oxide film, and further firing the metal oxide at a crystallization temperature or higher to crystallize the film. is there.
[0004]
  As a method similar to the sol-gel method, there is an organometallic decomposition (MOD) method. In the MOD method, a raw material solution containing a thermally decomposable organometallic compound, for example, a metal β-diketone complex (for example, metal acetylacetonate) or a carboxylate (for example, acetate) is applied to a substrate. Heating in air or in an oxygen-containing atmosphere causes evaporation of the solvent in the coating film and thermal decomposition of the metal compound to form a metal oxide film, which is further baked at a temperature higher than the crystallization temperature to crystallize the film. Make it. Accordingly, the film forming operation is almost the same as that of the sol-gel method, except that the raw material compounds are different.
[0005]
  Thus, since the sol-gel method and the MOD method have the same film forming operation, a method using both of them is also possible. That is, the raw material solution may contain both a hydrolyzable metal compound and a thermally decomposable metal compound. In that case, hydrolysis and thermal decomposition of the raw material compound occur during heating of the coating film, and the metal An oxide is formed.
[0006]
  These sol-gel methods, MOD methods, and methods using these in combination are referred to as CSD methods (Chemical Solution Deposition).
[0007]
  In addition to the advantages of being inexpensive, simple and suitable for mass production, the CSD method has the excellent features that the film composition can be easily controlled and the film thickness is relatively uniform. Therefore, this is a film forming method advantageous for forming a ferroelectric thin film on a relatively flat substrate.
[0008]
  In the conventional CSD method, the raw material solution is applied to a substrate and dried, followed by calcination, and this coating, drying and calcination are repeated until a desired film thickness is obtained. Film formation is performed by baking and crystallizing at a temperature equal to or higher than the crystallization temperature.
[0009]
[Problems to be solved by the invention]
  Formation of a ferroelectric thin film by the CSD method requires firing for crystallization.
[0010]
  On the other hand, in the memory using such a ferroelectric thin film, with the miniaturization of the device chip, adverse effects on the transistor of the device and its peripheral circuit due to the heat treatment are becoming a problem. It is desired to reduce the crystallization temperature when forming a metal oxide thin film. Also, a reduction in crystallization temperature is expected to prevent oxidation of aluminum wiring on the substrate.
[0011]
  In applications other than ferroelectric memory, reducing the crystallization temperature during film formation enables film formation on glass substrates, etc., which were difficult to form at conventional crystallization temperatures. Reduction of the crystallization temperature is strongly desired since it is expected to expand the application range of piezoelectric materials, piezoelectric materials, current collectors, and the like.
[0012]
  The present invention provides a composition for forming a metal oxide thin film that can be crystallized even at a low temperature of 550 ° C. or less, a forming method thereof, and this low temperature crystallization method when forming an SBT ferroelectric thin film. An object of the present invention is to provide a ferroelectric thin film.
[0013]
[Means for Solving the Problems]
  The composition for forming an SBT ferroelectric thin film of the present invention (invention 1) is:By CSD method (Chemical Solution Deposition)In a composition for forming a ferroelectric thin film comprising an organometallic compound solution for forming an SBT ferroelectric thin film, a general formula: Sr_xBi_y(Ta_zNb_1-z)₂O₉(In the formula, 0.6 <x <1.1, 2.0 ≦ y <2.6, 0<composite metal compound A represented by z ≦ 1), Bi, Si, Pb, Ge, Sn, Al, Ga, In, Mg, Ca, Sr, Ba, V, Nb, Ta, Sc, Y, Ti, Zr 1 selected from Hf, Cr, Mn, Fe, Co, Ni, Zn, Cd, Li, Na, and KSeedComposed of elementsMoneyMixture of metal oxide BalloyA liquid composition for forming a metal oxide thin film comprising a thermally decomposable organometallic compound, a hydrolyzable organometallic compound, a partially hydrolyzed product and / or a heavy metal of each metal constituting the metal oxide. The condensate is organic in proportions that give the metal atomic ratio shown in the above formulasolventFrom the solution that is dissolved inThe crystallization temperature of the formed SBT ferroelectric thin film is 640 ° C. or lower.It is characterized by that.
[0014]
  The present inventors have conducted various studies to reduce the crystallization temperature of the SBT ferroelectric thin film. As a result, Bi, Si, Pb, Ge, Sn, Al, Ga, In, Mg, Ca, Sr, Ba, One or more elements of the group consisting of V, Nb, Ta, Sc, Y, Ti, Zr, Hf, Cr, Mn, Fe, Co, Ni, Zn, Cd, Li, Na, and K are added to SBT. It was found that the addition resulted in crystallization at a lower temperature than pure SBT and improved film morphology.
[0015]
  The composition of the present invention has been created based on such knowledge. The molar ratio B / A between B and A is preferably 0 <B / A <100. The effect of B as a dopant begins to appear in a state in which a small amount of B is mixed, but as the amount of B increases, an effect of improving the crystallization temperature and further the morphology appears. However, if B / A becomes too large, the characteristics of A itself are diluted and the residual polarizability Pr becomes weak. Therefore, the optimum amount of B / A varies depending on the application. As a general optimum range, 0 <B / A <20 is preferable, further 0.1 <B / A <20, further 0.2 <B / A <20, and most preferably 0.4 <B. / A <20.
[0016]
  The present invention (claims)4) SBT ferroelectric thin film forming compositionBy CSD method (Chemical Solution Deposition)In a composition for forming a ferroelectric thin film comprising an organometallic compound solution for forming an SBT ferroelectric thin film, a general formula: Sr_xBi_y(Ta_zNb_1-z)₂O₉(In the formula, 0.6 <x <1.1, 2.0 ≦ y <2.6, 0<a composite metal compound A represented by z ≦ 1) and (Bi_α, La_1-α)₂SiO₅ (Where 0 ≦ α ≦ 1)A mixed composition of composite metal oxide B represented by the formula (wherein the molar ratio B / A B / A is 0 <B / A <5), and a liquid composition for forming a thin film: A ratio such that the thermally decomposable organometallic compound, hydrolyzable organometallic compound, partially hydrolyzed product and / or polycondensate of each metal constituting the metal oxide give a metal atomic ratio represented by the above formula OrganicsolventIt consists of the solution melt | dissolved in.
[0017]
  The present invention (claims)5) SBT ferroelectric thin film forming compositionBy CSD method (Chemical Solution Deposition)In a composition for forming a ferroelectric thin film comprising an organometallic compound solution for forming an SBT ferroelectric thin film, a general formula: Sr_xBi_y(Ta_zNb_1-z)₂O₉(In the formula, 0.6 <x <1.1, 2.0 ≦ y <2.6, 0<a composite metal compound A represented by z ≦ 1) and (Bi_β, La_1-α)₂SiO₅ (Where 0 ≦ α ≦ 1, α <β <1.3α)A mixed composite metal oxide of composite metal oxide B represented by the formula (However, the molar ratio B / A between B and A is 0 <B / A <5)A liquid composition for forming a thin film of the metal oxide comprising a thermally decomposable organometallic compound, a hydrolyzable organometallic compound, a partially hydrolyzed product and / or a polycondensate of each metal constituting the metal oxide. , Organic at a ratio giving the metal atomic ratio shown in the above formulasolventIt consists of the solution melt | dissolved in.
[0018]
  The inventor conducted further studies on the composite oxide B, and found that (Bi_α, La_1-α)₂SiO₅Or (Bi_β, La_1-α)₂SiO₅Has been found to be very suitable. However, α <β <1.3α. When such a Bi-La-Si composite oxide is used as the composite oxide, the SBT ferroelectric thin film is crystallized at a lower temperature.
[0019]
  In the method for forming a ferroelectric thin film of the present invention, this ferroelectric thin film forming composition is applied to a heat resistant substrate and heated in air, in an oxidizing atmosphere or in a water-containing atmosphere once or in a desired manner. The process is repeated until a film having a thickness is obtained, and the film is fired at a temperature equal to or higher than the crystallization temperature at least during or after heating in the final step.
[0020]
  The ferroelectric thin film of the present invention is formed by this method.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, embodiments of the present invention will be described in detail.
[0022]
  In the organometallic compound raw material used in the present invention, the organic group is arranged in the order of Sr, Bi, Ta and Nb for the composite metal compound A.To goldBi, Si, Pb, Ge, Sn, Al, Ga, In, Mg, Ca, Sr, Ba, V, Nb, Ta, Sc, Y, Ti, Zr, Hf, Cr, Mn, Fe for the genus compound B , Co, Ni, Zn, Cd, Li, Na and K are preferably bonded to each metal via an oxygen or nitrogen atom, such as metal alkoxide, metal diol complex, metal triol complex, metal carboxylic acid. Examples thereof include one or more selected from the group consisting of a salt, a metal β-diketonate complex, a metal β-diketoester complex, a metal β-iminoketo complex, and a metal amino complex. Particularly suitable compounds are metal alkoxides, partial hydrolysates thereof and / or organic acid salts (eg acetates). Examples of the alkoxide include alkoxides such as methoxide, ethoxide, isopropoxide, butoxide, dimethoxydiisopropoxide. Although the metal alkoxide may be used as it is, a partially hydrolyzed product thereof may be used in order to promote decomposition.
[0023]
  In order to prepare the composition for forming an SBT ferroelectric thin film of the present invention, these raw material organometallic compounds are dissolved in an appropriate solvent at a ratio corresponding to the desired SBT ferroelectric thin film composition and are suitable for coating. Adjust to a different concentration.
[0024]
  The solvent of the composition for forming an SBT ferroelectric thin film used here is appropriately determined according to the raw material organometallic compound, but in general, carboxylic acid, alcohol, ester, ketones (for example, acetone, methyl ethyl ketone). , Ethers (eg, dimethyl ether, diethyl ether), cycloalkanes (eg, cyclohexane, cyclohexanol), aromatics (eg, benzene, toluene, xylene), other tetrahydrofuran, or a mixed solvent of two or more of these Can be used.
[0025]
  Complex oxide B is (Bi_α, La_1-α)₂SiO₅Or (Bi_β, La_1-α)₂SiO₅In this case, the solvent preferably contains a mixed solvent of monoalcohol and diol or consists of this mixed solvent. As the diol, triethylene glycol is particularly preferable, but propylene glycol is also preferable.
[0026]
  Specific examples of the carboxylic acid include n-butyric acid, α-methylbutyric acid, i-valeric acid, 2-ethylbutyric acid, 2,2-dimethylbutyric acid, 3,3-dimethylbutyric acid, 2,3-dimethylbutyric acid, 3-methylpentanoic acid, 4-methylpentanoic acid, 2-ethylpentanoic acid, 3-ethylpentanoic acid, 2,2-dimethylpentanoic acid, 3,3-dimethylpentanoic acid, 2,3-dimethylpentanoic acid, 2- It is preferable to use ethylhexanoic acid or 3-ethylhexanoic acid.
[0027]
  As the ester, ethyl acetate, propyl acetate, n-butyl acetate, sec-butyl acetate, tert-butyl acetate, isobutyl acetate, n-amyl acetate, sec-amyl acetate, tert-amyl acetate, isoamyl acetate are used. As the alcohol, 1-propanol, 2-propanol, 1-butanol, 2-butanol, iso-butyl alcohol, 1-pentanol, 2-pentanol, 2-methyl-2-pentanol, 2-methoxy It is preferred to use ethanol.
[0028]
  The total concentration of the organometallic compound in the organometallic compound solution of the SBT ferroelectric thin film forming composition is preferably about 0.1 to 20% by weight in terms of metal oxide.
[0029]
  In this organometallic compound solution, β-diketones (for example, acetylacetone, heptafluorobutanoylpivaloylmethane, dipivaloylmethane, trifluoroacetylacetone, benzoylacetone, etc.) are used as stabilizers as necessary. Β-ketone acids (for example, acetoacetic acid, propionylacetic acid, benzoylacetic acid, etc.), β-ketoesters, for example, lower alkyl esters of these ketone acids such as methyl, propyl, butyl, etc., oxyacids (for example, lactic acid, glycolic acid) , Α-oxybutyric acid, salicylic acid, etc.), lower alkyl esters of these oxyacids, oxyketones (eg, diacetone alcohol, acetoin, etc.), diols, triols, higher carboxylic acids, alkanolamines (eg, jetanolamine) , Triethanolamine Monoethanolamine), a multivalent amine and the like, may be added from 0.2 to 3 approximately at (stabilizer number of molecules) / (number of metal atoms).
[0030]
  In the present invention, particles are removed by filtering the organometallic compound solution thus prepared, and the number of particles having a particle size of 0.5 μm or more (particularly 0.3 μm or more, especially 0.2 μm or more). Is preferably 50 / mL or less per mL of solution.
[0031]
  When the number of particles having a particle size of 0.5 μm or more in the organometallic compound solution exceeds 50 particles / mL, long-term storage stability becomes poor. The smaller the number of particles having a particle size of 0.5 μm or more in this organometallic compound solution, the more preferable, and particularly preferably 30 particles / mL or less.
[0032]
  Although there is no restriction | limiting in particular as a method of processing the organometallic compound solution after preparation so that it may become such a particle count, Specifically, the following methods are mentioned.
  (1)  A filtration method in which a commercially available membrane filter having a pore size of 0.2 μm is used and pressure-fed with a syringe.
  (2)  A pressure filtration method combining a commercially available membrane filter with a pore size of 0.05 μm and a pressure tank.
  (3)  the above(2)Circulation filtration method combining a filter and a solution circulation tank.
[0033]
  In any method, the particle capture rate by the filter varies depending on the solution pressure. It is generally known that the lower the pressure, the higher the capture rate,(1),(2)In order to realize the condition of 50 particles or less, it is preferable to pass the filter very slowly at a low pressure.
[0034]
  In order to form an SBT ferroelectric thin film using the composition for forming an SBT ferroelectric thin film according to the method of the present invention, the composition for forming an SBT ferroelectric thin film of the present invention described above is spin coated, dip-coated. The coating is applied onto the substrate by a coating method such as a LSMCD (Liquid Source Misted Chemical Deposition) method, followed by drying (preliminary firing) and main firing.
[0035]
  As a specific example of the substrate to be used, single-crystal Si, polycrystal Si, Pt, Pt (uppermost layer) / Ti, Pt (uppermost layer) / Ta, Ru, RuO are formed on the surface layer of the substrate.₂, Ru (top layer) / RuO₂, RuO₂(Top layer) / Ru, Ir, IrO₂, Ir (top layer) / IrO₂, Pt (top layer) / Ir, Pt (top layer) / IrO₂, SrRuO₃Or (La_xSr_1-xCoO₃A substrate using a perovskite-type conductive oxide such as, but not limited to, is exemplified.
[0036]
  In addition, when a desired film thickness cannot be obtained by one application, the application and drying steps are repeated a plurality of times, and then the main baking is performed.
[0037]
  Here, the preliminary calcination is performed in order to remove the solvent and thermally decompose or hydrolyze the organometallic compound to convert it into a composite oxide, so that it is performed in air, in an oxidizing atmosphere, or in a steam-containing atmosphere. Even in heating in the air, the moisture required for hydrolysis is sufficiently secured by the humidity in the air. This heating may be performed in two stages: low temperature heating for removing the solvent and high temperature heating for decomposing the organometallic compound.
[0038]
  The main firing is a step for firing and crystallizing the thin film obtained by the pre-firing at a temperature equal to or higher than the crystallization temperature, whereby an SBT ferroelectric thin film is obtained. The firing atmosphere in this crystallization process is O₂, N₂, Ar, N₂O or H₂Or a mixed gas thereof is suitable.
[0039]
  Generally, pre-baking is performed at 150 to 350 ° C., and main baking is performed at 530 to 630 ° C. In the present invention, the thin film can be crystallized even if the main baking temperature is low.
[0040]
【Example】
  Hereinafter, the present invention will be described more specifically with reference to Examples and Comparative Examples.
[0041]
  In the following Examples and Comparative Examples, the following were used as the organometallic compound raw materials.
      Bi compound: Bi ethoxide
      La compound: Lanthanum 2-methoxyethoxide
      Ti compound: Ti tetraisopropoxide
      Si compound: Si tetraethoxide
      Ge compound: Ge tetraethoxide
      Sn compound: Sn tetra-n-butoxide
      Al compound: Al triisopropoxide
      Ga compound: Ga triethoxide
      In compound: In triisopropoxide
      Mg compound: Mg ethoxide
      Ca compound: Ca ethoxide
      Sr compound: Sr ethoxide
      Ba compound: Ba ethoxide
      V compound: vanadyl triisopropoxide
      Nb compound: Nb pentaethoxide
      Ta compound: Ta pentaethoxide
      Sc compound: scandium acetate
      Y compound: Y isopropoxide
      Ti compound: Ti tetraisopropoxide
      Zr compound: Zr tetranormal butoxide
      Hf compound: Hf ratraethoxide
      Cr compound: Cr triethoxide
      Mn compound: Mn methoxide
      Fe compound: Fe triisopropoxide
      Co compound: 2-ethylhexanoic acid Co
      Ni compound: 2-ethylhexanoic acid Ni
      Zn compound: 2-ethylhexanoic acid Zn
      Cd compound: 2-ethylhexanoic acid Cd
      Li compound: Li ethoxide
      Na compound: Na ethoxide
      K compound: K ethoxide
[0042]
  Experiment No. 1-241
  Using 2-methoxyethanol that has been sufficiently dehydrated as an organic solvent, each metal compound is dissolved therein, and acetylacetone is added to the metal alkoxide twice in order to stabilize the solution, followed by heating under reflux, A thin film forming solution having the composition shown in 9 and having a total organometallic compound concentration of about 10% by weight in terms of metal oxide was prepared.
[0043]
  Using each solution, a thin film was formed by the CSD method by the following method.
[0044]
  That is, each solution was applied onto a 6-inch silicon substrate by spin coating at 2000 rpm for 30 seconds.
[0045]
  Subsequently, using a hot plate, it preheated by heating at 200 degreeC for 10 minutes. This coating and pre-baking process was repeated twice, followed by baking with an RTA (rapid heat treatment apparatus) for 1 minute in an oxygen atmosphere at various temperatures to form a ferroelectric thin film having a thickness of 2000 mm, and a crystallization temperature. I investigated. Further, the morphology of the formed film was observed by SEM. The results are shown in Tables 1-9. In Tables 1 to 9, ◯ indicates that the morphology is good, Δ indicates that it is slightly better, and X indicates that it is not good.
[0046]
  In addition, these No. 1 to 241, a ferroelectric thin film was formed under the same conditions except that the final firing temperature was uniformly set to 550 ° C., and the residual polarization Pr at an applied voltage of 3 V of each ferroelectric thin film was examined. 9 shows.
[0047]
[Table 1]

[0048]
[Table 2]

[0049]
[Table 3]

[0050]
[Table 4]

[0051]
[Table 5]

[0052]
[Table 6]

[0053]
[Table 7]

[0054]
[Table 8]

[0055]
[Table 9]

[0056]
  As Tables 1 to 9, No. 1 (comparative example), No. 1 to which the B composition was added. Any of the materials of 2 to 241 (Examples) has a low crystallization temperature. No. As shown in 2 to 241, the crystallization temperature becomes lower by increasing B / A. And by making B / A 0.2 or more, especially 0.3, the crystallization temperature becomes sufficiently low. In all the samples to which the B component was added so that the crystallization temperature was 550 ° C., the residual polarization Pr of the 550 ° C. fired product had a sufficiently large value.
[0057]
  Experiment No. 242-313
1) Synthesis of SBTN solution
  Diethylene glycol is used as an organic solvent, and 2-ethylhexanoic acid Sr, 2-ethylhexanoic acid Bi, Ta ethoxide and / or Nb ethoxide are dissolved in this, and the low boiling point produced while refluxing at the boiling point of the solvent The reaction was carried out for 10 hours while distilling off the by-product organic material to synthesize a composite metal organic compound of SBTN. Thereafter, acetylacetone is added in a molar amount of 1 times the total amount of metal, and reflux reaction is performed for 1 hour at the boiling point of the solvent. An agent was obtained.
2) Synthesis of Bi-Si solution
  Use sufficiently dehydrated n-butanol as an organic solvent, and add 2-ethylhexanoic acid Bi and Si ethoxide in a molar ratio of Bi: Si = 2: 1 and dissolve it at a solvent boiling point. The mixture was refluxed for 2 hours to synthesize a Bi—Si composite metal organic compound. Thereafter, acetylacetone was added in an amount of 1-fold mol with respect to the total amount of metals, and a reflux reaction was carried out at the boiling point of the solvent for 1 hour to obtain a stable Bi-Si thin film forming agent.
3) Synthesis of La-Si solution
  Sufficiently dehydrated n-butanol was used as an organic solvent, and lanthanum acetate hemihydrate was dissolved in this, and water of crystallization was removed by azeotropic distillation. Si ethoxide was added to the resulting solution so that the molar ratio of La: Si = 2: 1 was dissolved, and the mixture was refluxed at the boiling point of the solvent for 2 hours to synthesize a La—Si complex metal organic compound. Thereafter, 1 mol of acetylacetone was added to the total amount of metals, and a reflux reaction was performed for 1 hour at the boiling point of the solvent to obtain a stable La-Si thin film forming agent.
[0058]
  The Bi-Si solution and the La-Si solution are mixed so as to have the B composition described in Tables 10 and 11, and this solution and the SBTN solution are further mixed so as to have the B / A composition ratio shown in Tables 10 and 11. A reflux reaction was performed at the boiling point for 1 hour to obtain a stable SBTN-Bi-La-Si thin film forming agent. Using these solutions, a composite metal oxide thin film was formed. Final crystallization temperatures were 400, 450, 500, 550, and 600 ° C., respectively, and it was confirmed by XRD how many degrees of crystallization occurred depending on the composition. The results are shown in Tables 10 and 11.
[0059]
[Table 10]

[0060]
  Experiment No. 314-385
1) Synthesis of SBTN solution
  Propylene glycol is used as the organic solvent, and Sr metal, Bi ethoxide, Ta ethoxide and / or Nb ethoxide is dissolved in this, while distilling off low-boiling by-product organic substances produced while refluxing at the boiling point of the solvent. The reaction was carried out for 5 hours to synthesize a SBTN complex metal organic compound. Thereafter, acetylacetone was added in an amount of 1 mol to the total amount of metal, refluxed for 1 hour at the boiling point of the solvent, and the solution was diluted with n-butanol to adjust the viscosity, and the stable SBTN compositions of SBTN in Tables 12 and 13 were obtained. A thin film forming agent was obtained.
2) Synthesis of Bi-Si solution
  A sufficiently dehydrated n-butanol is used as an organic solvent, and Bi ethoxide and Si ethoxide are added and dissolved in a molar ratio of Bi: Si = 2: 1. The mixture is refluxed for 2 hours at the boiling point of the solvent. A composite metal organic compound of -Si was synthesized. Thereafter, acetylacetone was added in an amount of 1-fold mol with respect to the total amount of metals, and a reflux reaction was carried out at the boiling point of the solvent for 1 hour to obtain a stable Bi-Si thin film forming agent.
3) Synthesis of La-Si solution
  Sufficiently dehydrated n-butanol was used as an organic solvent, and lanthanum acetate hemihydrate was dissolved in this, and water of crystallization was removed by azeotropic distillation. Si ethoxide was added to the resulting solution so that the molar ratio of La: Si = 2: 1 was dissolved, and the mixture was refluxed at the boiling point of the solvent for 2 hours to synthesize a La—Si complex metal organic compound. Thereafter, 1 mol of acetylacetone was added to the total amount of metals, and a reflux reaction was performed for 1 hour at the boiling point of the solvent to obtain a stable La-Si thin film forming agent.
[0061]
  The Bi-Si solution and the La-Si solution are mixed so as to have the B composition described in Tables 12 and 13, and this solution and the SBTN solution are further mixed so as to have the B / A composition ratio shown in Tables 12 and 13. A reflux reaction was performed at the boiling point for 1 hour to obtain a stable SBTN-Bi-La-Si thin film forming agent. Using these solutions, a composite metal oxide thin film was formed. Final crystallization temperatures were 400, 450, 500, 550, and 600 ° C., respectively, and it was confirmed by XRD how many degrees of crystallization occurred depending on the composition. The results are shown in Tables 12 and 13.
[0062]
[Table 11]

[0063]
[Table 12]

[0064]
  Experiment No. 386-457
1) Synthesis of SBTN solution
  Diethylene glycol is used as an organic solvent, and 2-ethylhexanoic acid Sr, 2-ethylhexanoic acid Bi, Ta ethoxide and / or Nb ethoxide are dissolved in this, and the low boiling point produced while refluxing at the boiling point of the solvent The reaction was carried out for 10 hours while distilling off the by-product organic material to synthesize a composite metal organic compound of SBTN. Thereafter, acetylacetone was added in a molar amount of 1 times the total amount of metal, refluxed for 1 hour at the boiling point of the solvent, and the solution was diluted with n-butanol to adjust the viscosity. A thin film forming agent was obtained.
2) Synthesis of Bi-Si solution
  A sufficiently dehydrated n-butanol is used as an organic solvent, and 2-ethylhexanoic acid Bi and Si ethoxide are added and dissolved in a molar ratio of Bi: Si = 2.1: 1, and the solvent boiling point is obtained. The mixture was refluxed for 2 hours to synthesize a Bi-Si composite metal organic compound. Thereafter, acetylacetone was added in an amount of 1-fold mol with respect to the total amount of metals, and a reflux reaction was carried out at the boiling point of the solvent for 1 hour to obtain a stable Bi-Si thin film forming agent.
3) Synthesis of La-Si solution
  Sufficiently dehydrated n-butanol was used as an organic solvent, and lanthanum acetate hemihydrate was dissolved in this, and water of crystallization was removed by azeotropic distillation. Si ethoxide was added to the resulting solution so that the molar ratio of La: Si = 2: 1 was dissolved, and the mixture was refluxed at the boiling point of the solvent for 2 hours to synthesize a La—Si complex metal organic compound. Thereafter, 1 mol of acetylacetone was added to the total amount of metals, and a reflux reaction was performed for 1 hour at the boiling point of the solvent to obtain a stable La-Si thin film forming agent.
[0065]
  The Bi-Si solution and La-Si solution are mixed so as to have the B composition described in Tables 14 and 15, and this solution and the SBTN solution are further mixed so as to have the B / A composition ratio shown in Tables 14 and 15. A reflux reaction was performed at the boiling point for 1 hour to obtain a stable SBTN-Bi-La-Si thin film forming agent. Using these solutions, a composite metal oxide thin film was formed. Final crystallization temperatures were 400, 450, 500, 550, and 600 ° C., respectively, and it was confirmed by XRD how many degrees of crystallization occurred depending on the composition. The results are shown in Tables 14 and 15.
[0066]
[Table 13]

[0067]
[Table 14]

[0068]
[Table 15]

[0069]
  As shown in Tables 10 to 15, Experiment No. Those of 242 to 457 have a sufficiently low crystallization temperature.
[0070]
【The invention's effect】
  As described above, according to the present invention, the crystallization temperature of the SBT ferroelectric thin film can be lowered.ThinThere are provided a film forming composition, a thin film forming method, and a ferroelectric thin film formed by this method.

Claims (12)

In a composition for forming a ferroelectric thin film comprising an organometallic compound solution for forming an SBT ferroelectric thin film by a CSD method (Chemical Solution Deposition) ,
General _formula: (wherein, 0.6 <x <1.1,2.0 ≦ y <2.6,0 <z ≦ 1) Sr x Bi y (Ta z Nb 1-z) 2 O 9 shown in Composite metal compound A and Bi, Si, Pb, Ge, Sn, Al, Ga, In, Mg, Ca, Sr, Ba, V, Nb, Ta, Sc, Y, Ti, Zr, Hf, Cr, Mn , Fe, Co, Ni, Zn , Cd, Li, 1 kind of consists element Rukin genus oxide liquid composition for forming a thin film of mixed alloy genus oxides of B chosen from among the Na and K Because
A ratio such that the thermally decomposable organometallic compound, hydrolyzable organometallic compound, partially hydrolyzed product and / or polycondensate of each metal constituting the metal oxide give a metal atomic ratio represented by the above formula in Ri Do from a solution dissolved in an organic solvent, SBT ferroelectric thin film-forming composition that the crystallization temperature of the SBT ferroelectric thin film to be formed, characterized in der Rukoto 640 ° C. or less. The composition for forming an SBT ferroelectric thin film according to claim 1, wherein the metal oxide B is a Si metal oxide. According to claim 1 or 2, the molar ratio B / A between B and A is 0 <B / A <SBT ferroelectric thin film-forming composition, which is a 20. In a composition for forming a ferroelectric thin film comprising an organometallic compound solution for forming an SBT ferroelectric thin film by a CSD method (Chemical Solution Deposition) ,
General _formula: (wherein, 0.6 <x <1.1,2.0 ≦ y <2.6,0 <z ≦ 1) Sr x Bi y (Ta z Nb 1-z) 2 O 9 shown in Mixed metal oxide A and mixed metal oxide B of (Bi _α , La _1-α ) ₂ SiO ₅ (where 0 ≦ α ≦ 1) (where B, A and Is a liquid composition for forming a thin film having a molar ratio B / A of 0 <B / A <5),
A ratio such that the thermally decomposable organometallic compound, hydrolyzable organometallic compound, partially hydrolyzed product and / or polycondensate of each metal constituting the metal oxide give a metal atomic ratio represented by the above formula A composition for forming an SBT ferroelectric thin film comprising a solution dissolved in an organic solvent . In a composition for forming a ferroelectric thin film comprising an organometallic compound solution for forming an SBT ferroelectric thin film by a CSD method (Chemical Solution Deposition) ,
General _formula: (wherein, 0.6 <x <1.1,2.0 ≦ y <2.6,0 <z ≦ 1) Sr x Bi y (Ta z Nb 1-z) 2 O 9 shown in Mixed composite metal oxide A and composite metal oxide B represented by (Bi _β , La _1-α ) ₂ SiO ₅ (where 0 ≦ α ≦ 1, α <β <1.3α) A liquid composition for forming a thin film having a molar ratio B / A between B and A of 0 <B / A < 5 ,
A ratio such that the thermally decomposable organometallic compound, hydrolyzable organometallic compound, partially hydrolyzed product and / or polycondensate of each metal constituting the metal oxide give a metal atomic ratio represented by the above formula A composition for forming an SBT ferroelectric thin film comprising a solution dissolved in an organic solvent . According to claim 4 or 5, wherein the SBT ferroelectric thin film-forming composition of the organic solvent is characterized by containing a mixed solvent of monoalcohols and diols. The composition for forming an SBT ferroelectric thin film according to claim 6 , wherein the diol is triethylene glycol. In any one of claims 1 to 7, wherein the organic metal compound, for SBT ferroelectric thin film formation which is a compound in which an organic group is bonded to a metal through its oxygen or nitrogen atom Composition. 9. The organometallic compound according to claim 8 , wherein the organometallic compound is a metal alkoxide, a metal diol complex, a metal triol complex, a metal carboxylate, a metal β-diketonate complex, a metal β-diketoester complex, a metal β-iminoketo complex, or a metal amino complex. A composition for forming an SBT ferroelectric thin film, which is one or more selected from the group consisting of: In any 1 item | term of Claim 1 thru | or 9 , it selected from the group which consists of (beta) -diketone, (beta) -ketone acid, (beta) -ketoester, oxyacid, diol, triol, higher carboxylic acid, alkanolamine, and a polyvalent amine. A composition for forming an SBT ferroelectric thin film, comprising one or more stabilizers in a proportion of 0.2 to 3 moles relative to 1 mole of the total amount of metals in the composition. . A process of applying the composition for forming a ferroelectric thin film according to any one of claims 1 to 10 to a heat resistant substrate and heating in air, in an oxidizing atmosphere or in a water-containing atmosphere once or in a desired manner A method of forming an SBT ferroelectric thin film, characterized in that it is repeated until a film having a thickness is obtained, and the film is fired at a temperature equal to or higher than the crystallization temperature at least after heating in the final step. An SBT ferroelectric thin film formed by the method of claim 11 .