JP4544379B2 - Glass hard disk abrasive - Google Patents

Description

第１表から平均二次粒子径が０．３μｍで酸化セリウムの含有率が９９．５％の実施例１及び２の方が平均二次粒子径が１．４μｍで酸化セリウムの含有率が５７％の比較例１より平均表面粗さが小さく、しかも平均表面粗さに対する研磨速度の比率が高くなり研磨特性が優れていることがわかる。
【００６７】
また実施例３及び４は、２０〜３０ｎｍの小粒子が多数混在するために研磨速度が少し低下している。しかし、平均表面粗さは良好で、光ディスクや磁気ガラスハードディスク用の精密研磨剤として有用である。
【００６８】
セリウム塩とアルカリ性物質を反応させて得られる水酸化セリウムに、酸素又は酸素含有ガスを吹き込む第１製法及び第２製法で得られる酸化第二セリウム粒子は、比表面積が大きく、単位重量当たりの水酸基が多いので、ケミカル・メカニカルな研磨に適する。酸化セリウム粉末を水に分散した研磨材が研磨面を引っ掻く作用に対して、本願の第１製法及び第２製法で得られた研磨材は、ケミカル・メカニカルな作用により凹凸の少ない良好な研磨面が得られ精密な研磨を必要とする用途に特に適する。また、この方法で得られた酸化第二セリウム研磨材は、ガラスに対して良好な研磨作用を示し、ガラス製ハードディスクの研磨に適する。
【００６９】
【発明の効果】
本発明の０．１〜０．５μｍの平均二次粒子径を有する酸化第二セリウム粒子が水に分散した安定なスラリーからなる光ディスクや磁気ディスク用ガラス基板の研磨剤、更には研磨剤中の全希土類元素に占めるセリウムの割合が酸化物の重量換算で９５％以上である上記の研磨剤は、平均表面粗さが小さく、しかも平均表面粗さに対する研磨速度の比率が高くなり研磨特性が優れている。
【００７０】
本発明の研磨剤は、酸化セリウム粒子の平均二次粒子径を小さくすることにより平均表面粗さを小さくし高品質の研磨面を得ることができる。更に、ガラス製ハードディスクの研磨に直接関与している研磨剤中の全希土類元素に占めるセリウムの割合が酸化物の重量換算で９５％以上にすることにより研磨速度が向上し、平均表面粗さに対する研磨速度の比率が高くなったため、研磨工程の生産性の向上及び低コスト化が可能である。
【００７１】
特に本発明の研磨剤は光ディスクや磁気ディスク用ガラス基板を研磨した場合、高品質の研磨面が得られることから仕上げ研磨剤として有用である。この光ディスクや磁気ディスク用ガラス基板とは、結晶化ガラス製ハードディスク、アルミノ珪酸塩強化ガラス又はソーダライム強化ガラス製ガラスハードディスクのことである。
【００７２】
また本発明の研磨液に硝酸アルミニウム、硝酸鉄、塩基性スルファミン酸アルミニウム等の研磨促進剤を添加した研磨用組成物は、工業製品として供給され得るアルミニウムディスクの上に設けられたＮｉ−Ｐ等のメッキ層の表面、酸化アルミニウム層の表面あるいはアルミニウム、その合金、アルマイトの表面を研磨するのに有用である。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a polishing composition suitable for surface polishing of a glass substrate for optical disks and magnetic disks.
[0002]
[Prior art]
The abrasive for the glass substrate for optical disks and magnetic disks is obtained by dispersing abrasive grains containing cerium oxide obtained by firing dry pulverization after firing bastonite ore or rare earth chloride in water. Although these abrasive grains are relatively inexpensive, the content of cerium oxide is 50 to 90% at most, and since natural mineral is used as a raw material, it is difficult to control the purity any more. Moreover, the average secondary particle diameter of the powder is 1 to 3 μm, and it is difficult to reduce the average secondary particle diameter to 1 μm or less when finely divided by a breakdown method such as dry pulverization.
[0003]
SiO of semiconductor devices₂For polishing an oxide film, a polishing agent made of cerium oxide having an average particle size of 1 μm or less and a purity of cerium oxide of 99.5% or more in JP-A-5-326469, Japanese Patent No. 2864451 has an average particle size of 0.1 μm. It is described below that a high-quality oxide film can be obtained by polishing with a cerium oxide abrasive having a purity of 99.5% or more.
[0004]
However, for polishing optical disk and glass substrate for magnetic disk, Japanese Patent Application Laid-Open No. 11-60282 discloses a method for polishing glass substrate for magnetic disk in which the content of cerium oxide in the polishing liquid is 0.5-8 wt%. Has been. International Publication No. WO 98/21289 discloses an abrasive composition for a magnetic recording medium substrate, which contains an abrasive, a polishing aid, and water, and has an average primary particle size of 0.002 to 3 μm. A method of using is described.
[0005]
[Problems to be solved by the invention]
In recent years, the performance of glass substrates for optical disks and magnetic disks has tended to increase in density and speed. Therefore, a high-quality polished surface with low surface roughness and average waviness is required. However, a cerium oxide abrasive with a cerium oxide purity of 50 to 90% and an average secondary particle size of 1 to 3 μm, which is fired from bust nesite or rare earth chloride and dry-ground, has a good polished surface. It's getting harder to get.
[0006]
In order to solve these problems, the average secondary particle diameter of the cerium oxide particles is set to 1 μm or less, while the cerium oxide content is set to 95% in order to compensate for the decrease in the polishing rate by reducing the average secondary particle diameter of the cerium oxide. With the above, a high-quality polished surface can be obtained, and a polishing agent for a high-speed polishing optical disk or magnetic disk glass substrate has been found and the present invention has been achieved.
[0007]
[Means for Solving the Problems]
As a first aspect, the present invention is a stable slurry in which ceric oxide particles having an average secondary particle diameter of 0.1 to 0.5 μm are dispersed in water as an abrasive, and CeO₂A glass hard disk abrasive characterized by containing 0.2 to 30% by weight as a concentration.
[0008]
Further, as a second aspect, the glass hard disk abrasive according to the first aspect is characterized in that the ratio of cerium in all rare earth elements in the abrasive is 95% or more in terms of the weight of the oxide. .
[0009]
DETAILED DESCRIPTION OF THE INVENTION
The cerium oxide particles are crystalline cerium oxide particles having an average secondary particle diameter of 0.1 to 0.5 μm, preferably 0.2 to 0.3 μm.
[0010]
The average secondary particle size means that a sol in which particles are dispersed in a state of a single particle or a state close to this is called a primary sol, and particles in this primary sol are called primary particles. A secondary sol is a collection of several primary particles in the primary sol, and this aggregate is called a secondary particle. Here, in the cumulative particle size distribution of these secondary particles, the particle size corresponding to 50%, that is, the median size is referred to as the average secondary particle size. The measurement can be performed using a commercially available centrifugal particle size distribution measuring device, for example, a product name CAPA-700 manufactured by Horiba, Ltd.
[0011]
The ratio of cerium to the total rare earth elements in the abrasive in the abrasive is 95% or more in terms of the weight of the oxide. This can be represented by the ratio of (cerium oxide) / (cerium oxide + other rare earth oxide) in the ceric oxide particles.
[0012]
As the cerium oxide particles, cerium oxide particles produced by a known method can be used.
[0013]
Particularly preferred ceric oxide particles are, as the first method, a cerium (III) salt and an alkaline substance in an aqueous medium under an inert gas atmosphere, and 3 to 30 (OH) / (Ce³⁺) After reacting at a molar ratio to form a suspension of cerium (III) hydroxide, oxygen or a gas containing oxygen is immediately blown into the suspension at a temperature of 10 to 95 ° C. under atmospheric pressure. The use is made of crystalline ceric oxide particles having an average secondary particle diameter of 0.1 to 0.5 μm (micrometer).
[0014]
In the first method of the above-mentioned cerium oxide particles, as a first step, cerium (III) salt and an alkaline substance in an aqueous medium under an inert gas atmosphere are mixed with 3 to 30 (OH) / (Ce.³⁺) The reaction is carried out at a molar ratio to produce a suspension of cerium (III) hydroxide, that is, cerium hydroxide.
[0015]
The reaction under an inert gas atmosphere is a reaction of a cerium (III) salt and an alkaline substance in an aqueous medium using, for example, a reaction vessel equipped with a gas-replaceable stirrer and a thermometer. As the aqueous medium, water is usually used, but a small amount of a water-soluble organic solvent can also be contained. In the gas replacement, the tubular gas inlet is submerged in an aqueous medium, an inert gas is blown into the aqueous medium, and the gas is discharged from the discharge port attached to the upper part of the aqueous medium of the reaction vessel. Fill with inert gas. It is preferable to start the reaction after the replacement of the inert gas is completed. This reaction vessel can be made of a material such as stainless steel or glass lining. At this time, it is desirable that the inside of the reaction vessel be under atmospheric pressure. Therefore, it is preferable that the inflow amount and the outflow amount of gas are substantially the same. The gas inflow and outflow are preferably 0.01 to 20 liters / minute with respect to 1 liter of the reaction tank volume.
[0016]
Examples of the inert gas include nitrogen gas and argon gas, and nitrogen gas is particularly preferable.
[0017]
In the first production method, examples of the cerium (III) salt include cerous nitrate, cerous chloride, cerous sulfate, cerous carbonate, cerium ammonium nitrate (III) and the like. Said cerium (III) salt can be used individually or as a mixture.
[0018]
In the first production method, examples of the alkaline substance include alkali metal hydroxides such as sodium hydroxide and potassium hydroxide, or organic bases such as ammonia, amine, and quaternary ammonium hydroxide. Particularly, ammonia, sodium hydroxide, Potassium hydroxide is preferred, and these can be used alone or as a mixture.
[0019]
Although the above cerium (III) salt and alkaline substance can be added to an aqueous medium and reacted in a reaction vessel, a cerium (III) salt aqueous solution and an alkaline substance aqueous solution are prepared, and both the aqueous solutions are mixed. You can also react. The cerium (III) salt is preferably used in an aqueous medium at a concentration of 1 to 50% by weight.
[0020]
In the first production method, the ratio of the cerium (III) salt to the alkaline substance is (OH) / (Ce³⁺) 3-30 by molar ratio, preferably 6-12. (OH) / (Ce³⁺) When the molar ratio is less than 3, the cerium (III) salt is not completely neutralized with cerium hydroxide (III), and partly remains in the suspension as a cerium (III) salt. This cerium (III) salt has a much slower rate of oxidation to cerium (IV) than cerium (III) hydroxide, so if cerium (III) hydroxide and cerium (III) salt coexist, Since the nucleation rate and crystal growth rate of nitric oxide cannot be controlled, the particle size distribution becomes wide and the particle size is not uniform. In addition, (OH) / (Ce³⁺) When the molar ratio is larger than 30, the crystallinity of the obtained crystalline cerium oxide particles is lowered, and when used as an abrasive, the polishing rate is lowered, which is not preferable. Moreover, the particle size distribution of the obtained particles becomes wide, and the particle size is not uniform.
[0021]
In the said 1st manufacturing method, the reaction time in the said 1st process changes with the magnitude | sizes of preparation amount, and is about 1 minute-24 hours.
[0022]
In the first step, when cerium (III) salt and an alkaline substance are reacted in an oxygen-containing gas such as air instead of an inert gas, the generated cerium (III) hydroxide comes into contact with oxygen. Since the cerium (IV) salt and cerium oxide are successively changed, a large number of cerium oxide nuclei are generated in the aqueous medium, and the particle size distribution of the obtained cerium oxide particles becomes wider. The diameter is not uniform.
[0023]
As a second step, an average secondary particle diameter of 0.1 to 0.5 μm is obtained by blowing oxygen or a gas containing oxygen at a temperature of 10 to 95 ° C. under atmospheric pressure into the suspension produced in the first step. The crystalline cerium oxide particles having the following are produced. In this step, cerium (III) hydroxide in the suspension obtained in the first step is produced in the presence of oxygen or oxygen-containing gas to produce highly crystalline ceric oxide particles. Examples of oxygen or oxygen-containing gas include gaseous oxygen, air, or a mixed gas of oxygen and an inert gas. Examples of the inert gas include nitrogen and argon. When a mixed gas is used, the oxygen content in the mixed gas is preferably 1% by volume or more. In the second step, it is particularly preferable to use air because of its ease of production.
[0024]
The second step is performed in the same reaction vessel following the first step. Following the introduction of the inert gas in the first step, the inert gas is immediately replaced with oxygen or a gas containing oxygen. Gas is introduced. That is, it is carried out by blowing oxygen or oxygen-containing gas into the suspension obtained in the first step from a thin tubular gas inlet submerged in the suspension.
[0025]
Since the second step is performed under atmospheric pressure, almost the same amount of gas introduced into the suspension is discharged from a discharge port attached to the top of the suspension in the reaction vessel.
[0026]
In the second step, the total amount of oxygen or oxygen-containing gas blown into the suspension is an amount capable of changing cerium (III) hydroxide to ceric oxide, and (O₂) / (Ce³⁺It is preferable that the molar ratio is 1 or more. When the above molar ratio is less than 1, cerium (III) hydroxide remains in the suspension, and this comes into contact with oxygen in the air during the cleaning after the end of the second step, thereby generating fine particles. The resulting cerium oxide particles have a wide particle size distribution and the particle size is not uniform.
[0027]
In the second step, the inflow amount and outflow amount of gas per unit time are preferably 0.01 to 50 liters / minute with respect to 1 liter of the reaction tank volume.
[0028]
When the blowing of the inert gas in the first step and the blowing of oxygen or oxygen-containing gas in the second step are not continuous in time, the surface of the suspension obtained in the first step is Since it will be in contact with air and a layer containing cerium oxide particles having various particle sizes on the surface layer is generated, the particle size of the cerium oxide particles obtained in the second step performed thereafter is uniform. Don't be.
[0029]
This second step is preferably performed while stirring the suspension with a stirrer such as a disper so that oxygen or a gas containing oxygen is uniformly present in the suspension. When the suspension itself is stirred by blowing gas, stirring with a stirrer is not always necessary.
[0030]
Oxidation of cerium (III) hydroxide in the first production method to produce crystalline cerium oxide particles means that nucleation and crystal growth of crystalline cerium oxide particles are performed, The nucleation rate and crystal growth rate can be controlled by the concentration of cerium salt, the concentration of alkaline substance, the reaction temperature, the concentration of the oxidizing aqueous solution, the supply amount, and the like. In the above method, the concentration of the cerium salt, the concentration of the alkaline substance, the reaction temperature, the concentration of the oxidizing aqueous solution and the supply amount during nucleation and crystal growth can be freely changed. By adjusting these factors, the particle diameter can be arbitrarily controlled within the range of the average secondary particle diameter of 0.1 to 0.5 μm.
[0031]
The cerium oxide particles obtained in the first production method of the above particles are taken out from the reaction apparatus as a slurry and washed by an ultrafiltration method or a filter press washing method, whereby the particles obtained by removing impurities are aqueous. It can be dispersed in a medium to make a polishing liquid.
[0032]
A preferred production method of the cerium oxide particles used in the present invention is a second production method in which cerium (III) salt and an alkaline substance are contained in an aqueous medium during the opening to the atmosphere of 3 to 30 (OH) / (Ce).³⁺) After producing a suspension of cerium hydroxide by reacting at a molar ratio, the suspension is immediately produced by blowing oxygen or a gas containing oxygen at a temperature of 10 to 95 ° C. under atmospheric pressure. The use of crystalline ceric oxide particles having an average secondary particle size of 0.1 to 0.5 μm (micrometers).
[0033]
That is, in the second production method of ceric oxide particles, as a first step, cerium (III) salt and an alkaline substance in 3 to 30 (OH) / (Ce) in an aqueous medium with the atmosphere open.³⁺) Reaction at a molar ratio to produce a suspension of cerium hydroxide. As the second step, the suspension produced in the first step contains oxygen or oxygen at a temperature of 10 to 95 ° C. under atmospheric pressure. Crystalline ceric oxide particles having an average secondary particle diameter of 0.1 to 0.5 μm are produced by blowing gas.
[0034]
In the second production method, other conditions and raw materials are the same as those in the first production method.
[0035]
In the second production method, when cerium (III) salt and alkaline substance are neutralized in the atmosphere without using an inert gas, the produced cerium (III) hydroxide comes into contact with oxygen and gradually becomes cerium (IV). Due to the change to salt or cerium oxide, cerium oxide nuclei are generated in the aqueous medium. After raising the temperature to a predetermined temperature in the next step, when the cerium (III) salt and an alkaline substance are reacted in a gas containing oxygen such as air, the produced cerium (III) hydroxide comes into contact with oxygen, Since the cerium (IV) salt and cerium oxide are successively changed, the particle size distribution of the cerium oxide particles becomes wider and the particle size becomes non-uniform compared to the first production method. However, a high-quality polished surface is obtained as a glass hard disk abrasive, and ceric oxide obtained by this second production method is also useful.
[0036]
The cerium oxide particles obtained by the above-mentioned method for producing particles were dried at 110 ° C., and the diffraction pattern was measured with an X-ray diffractometer. The diffraction angles 2θ = 28.6 °, 47.5 °, and 56.4 were measured. Cubic cerium oxide particles having a high crystallinity and a cubic system described in ASTM Card No. 34-394. Moreover, the specific surface area value by the gas adsorption method (BET method) of the cerium oxide particles is 2 to 200 m.²/ G.
[0037]
The ceric oxide particles obtained by this method can be heat-treated in an aqueous medium at a temperature of 50 to 250 ° C. in the presence of an ammonium salt to obtain an abrasive.
[0038]
As the aqueous medium of the present invention, water is usually used, but a small amount of a water-soluble organic medium can be contained.
[0039]
As the ammonium salt used in the present invention, an ammonium salt whose anion component is a non-oxidizing component can be used. The ammonium salt having a non-oxidizing anionic component is most preferably ammonium carbonate or ammonium hydrogen carbonate, and these can be used alone or as a mixture.
[0040]
The ammonium salt having a non-oxidizing anionic component is mixed with [NH in an aqueous medium._Four ⁺] / [CeO₂The molar ratio is preferably from 0.1 to 30, and the concentration of the ammonium salt in the aqueous medium is preferably from 1 to 30% by weight.
[0041]
When the anion component is heated in an aqueous medium using an ammonium salt of a non-oxidizing component, it is heated at a temperature of 50 to 250 ° C., preferably 50 to 180 ° C. Dicerium particles are obtained. The heating time can be 10 minutes to 48 hours. When the heat treatment temperature is 100 ° C. or lower, the reaction is performed using an open reaction vessel, but when the temperature exceeds 100 ° C., the reaction is performed using an autoclave device or a supercritical processing device. The heat-treated ceric oxide particles can be taken out from the treatment tank as a slurry and washed by an ultrafiltration method or a filter press method to remove impurities.
[0042]
The ceric oxide particles surface-modified by heat treatment in the presence of an ammonium salt having a non-oxidizing anionic component can be easily dispersed in an aqueous medium to form a polishing liquid. The aqueous medium is preferably water.
[0043]
A sol containing ceric oxide particles that have been surface-modified by heat treatment in an aqueous medium in the presence of an ammonium salt having a non-oxidizing anionic component is subjected to quaternization after removing impurities by washing. Ammonium ion (NR_Four ⁺Where R is an organic group. ), (NR_Four ⁺) / (CeO₂) In a range of 0.001-1 in terms of the molar ratio, it is preferable because the stability of the polishing liquid is improved. Quaternary ammonium ions are provided by adding quaternary ammonium silicates, quaternary ammonium halides, quaternary ammonium hydroxides, or mixtures thereof, especially quaternary ammonium silicates, hydroxide quaternary hydroxides. Addition of quaternary ammonium is preferred. Examples of R include a methyl group, an ethyl group, a propyl group, a hydroxyethyl group, and a benzyl group. Examples of the quaternary ammonium compound include tetramethylammonium silicate, tetraethylammonium silicate, tetraethanolammonium silicate, monoethyltriethanolammonium silicate, trimethylbenzylammonium silicate, tetramethylammonium hydroxide, and tetraethylammonium hydroxide.
[0044]
A small amount of acid or base can also be contained. The pH of the polishing liquid is preferably 2-12. The polishing liquid (sol) contains a water-soluble acid [H⁺] / [CeO₂An acidic polishing liquid (sol) can be obtained by adding it in a molar ratio of 0.001-1. This acidic sol has a pH of 2-6. Examples of the water-soluble acid include inorganic acids such as hydrogen chloride and nitric acid, organic acids such as formic acid, acetic acid, succinic acid, tartaric acid, citric acid and lactic acid, acidic salts thereof, and mixtures thereof. In addition, water-soluble base [OH^-] / [CeO₂] Alkaline sol can be obtained by adding it in the range of 0.001-1 by molar ratio. This alkaline polishing liquid (sol) has a pH of 8-12. In addition to the quaternary ammonium silicate and quaternary ammonium hydroxide described above, the water-soluble base includes monoethanolamine, diethanolamine, triethanolamine, aminoethylethanolamine, N, N-dimethylethanolamine, N -Amines such as methylethanolamine, monopropanolamine and morpholine, and ammonia.
[0045]
The polishing liquid is stable at room temperature for a long period of one year or longer.
[0046]
The cerium oxide particles have a mechanical polishing action as well as a chemical polishing action, and are oxidized by heat treatment in an aqueous medium in the presence of an ammonium salt having a non-oxidizing anionic component. Many hydroxyl groups (≡Ce-OH) are generated on the surface of the secondary cerium particles, and these (≡Ce-OH) groups have a chemical action on the hydroxyl groups (≡Si-OH) on the surface of the silicon oxide film to improve the polishing rate. It is thought that. It is considered that the ammonium salt having a non-oxidizing anionic component exerts a reducing action on the surface of the ceric oxide particles.
[0047]
Once an abrasive with a reduced polishing rate (i.e., with reduced polishing capability) leads to reduced productivity in the polishing process, such an abrasive would dispose of the abrasive itself. However, in the present invention, the used cerium oxide particles having a reduced polishing ability are heat-treated in an aqueous medium at a temperature of 50 to 250 ° C. in the presence of an ammonium salt having a non-oxidizing anion component. Then, the polishing ability can be recovered again, and an abrasive with improved polishing rate can be obtained.
[0048]
When the average secondary particle diameter of the ceric oxide particles is larger than 0.5 μm, the surface roughness of the abrasive for the optical disk or the magnetic disk glass substrate of the present invention prepared by these methods is not preferable. Moreover, when the average particle diameter of ceric oxide is smaller than 0.1 μm, the polishing rate is undesirably low.
[0049]
When the proportion of cerium in the total rare earth elements in the polishing agent is less than 95% in terms of the weight of the oxide, the polishing rate becomes slow and the productivity becomes poor.
[0050]
CeO₂The concentration is preferably 0.2 to 30% by weight, and if it is lower than 0.2% by weight, the polishing rate becomes slow and the productivity becomes worse. If it exceeds 30% by weight, the viscosity of the slurry becomes high and the polishing resistance becomes very large.
[0051]
【Example】
Example 1
NH in a 100 liter stainless steel reactor_Three/ Ce³⁺= 2Nkg of 20% aqueous ammonia solution corresponding to 6 (molar ratio), 1Nm from a glass nozzle while keeping the liquid temperature at 30 ° C^Three/ Hour nitrogen gas was blown to convert cerium nitrate into CeO in all rare earth oxides.₂76.2 kg (CeO) aqueous solution of cerium (III) nitrate having a purity of 99.0%₂A cerium (III) hydroxide suspension was obtained by gradually adding 8.0 kg as a conversion amount). Subsequently, the suspension was heated to 80 ° C. over 1 hour, and then blown from a glass nozzle was blown from nitrogen gas to 2 Nm.^ThreeSwitched to air / hour, the oxidation reaction was started to convert cerium (III) to cerium (IV). The oxidation reaction was completed in 5 hours. The reaction-completed liquid was returned to room temperature, and a reaction liquid having light yellow fine particles having a pH of 8.7 and an electric conductivity of 83 mS / cm was obtained.
[0052]
The reaction solution was washed with a rotary filter press (manufactured by Kotobuki Giken), conductivity 20 μS / cm, CeO₂A slurry having a concentration of 22% by weight was obtained. After this slurry was dispersed in pure water, the pH was adjusted to 5 with 10% nitric acid, and CeO₂A slurry having a concentration of 5% by weight was prepared.
[0053]
Moreover, when the average secondary particle diameter of the obtained particles was measured with a centrifugal particle size distribution measuring device (CAPA-700 from Horiba, Ltd.), the average secondary particle diameter was 0.30 μm. The yield of the particles was almost 100%. When the particles were dried and analyzed for impurities, the proportion of cerium in the total rare earth elements in the abrasive was 99.5% in terms of the weight of the oxide, and when powder X-ray diffraction was measured, the diffraction angle 2θ = 28.6 °, 47.5 ° and 56.4 ° with main peaks, which coincided with the characteristic peak of cubic cerium oxide described in ASTM card 34-394. Moreover, the specific surface area value by the gas adsorption method (BET method) is 25.8 m.²/ G.
[0054]
Example 2
A cerium oxide slurry washed with a rotary filter press (manufactured by Kotobuki Giken) and an aqueous ammonium carbonate solution were added to a 100 liter stainless steel reaction vessel, and the concentration of ammonium carbonate was 10% by weight, CeO.₂The concentration was 15% by weight and the slurry amount was 100 kg. The slurry was heated to 95 ° C. and heat-treated at this temperature for 8 hours. After cooling, the slurry was washed with a rotary filter press (manufactured by Kotobuki Giken Co., Ltd.), conductivity 25 μS / cm, CeO₂A slurry having a concentration of 23% by weight was obtained. After this slurry was dispersed in pure water, the pH was adjusted to 5 with 10% nitric acid, and CeO₂A slurry having a concentration of 5% by weight was prepared.
[0055]
Moreover, when the average secondary particle diameter of the obtained particle | grains was measured with the centrifugal particle size distribution measuring apparatus (Horiba, Ltd. CAPA-700), it was a particle | grain with an average secondary particle diameter of 0.28 micrometer. When the particles were dried and analyzed for impurities, the proportion of cerium in the total rare earth elements in the abrasive was 99.6% in terms of the weight of the oxide, and the powder X-ray diffraction was measured. It has main peaks at 2θ = 28.6 °, 47.5 ° and 56.4 °, and coincides with the characteristic peak of cubic cerium oxide described in ASTM card 34-394. Moreover, the specific surface area value by the gas adsorption method (BET method) is 25.5 m.²/ G.
[0056]
Example 3
NH in a 1 liter glass reactor_Three/ Ce³⁺= 20 (molar ratio) of 20% aqueous ammonia solution 238g was charged, and the liquid temperature was kept at 30 ° C, CeO₂/ Rare earth oxide = 762 g of cerium (III) nitrate aqueous solution having a purity of 99.0% (CeO₂A cerium (III) hydroxide suspension was obtained by gradually adding a conversion amount of 80 g). Subsequently, the suspension was heated to 80 ° C. over 1 hour, and then 2 L / min of air was blown from a glass nozzle to start an oxidation reaction in which cerium (III) was converted to cerium (IV). The oxidation reaction was completed in 5 hours. The reaction-completed liquid was returned to room temperature, and a reaction liquid having light yellow fine particles with a pH of 5.5 and an electric conductivity of 127 mS / cm was obtained.
[0057]
After the reaction solution was washed with water by Nutsche, the wet cake was redispersed with pure water, and the conductivity was 94 μS / cm, CeO.₂A slurry having a concentration of 25.5 wt% was obtained. The slurry was adjusted to pH 5 with 10% nitric acid, and CeO.₂A slurry having a concentration of 5% by weight was prepared.
[0058]
When the obtained particles were observed with a transmission electron microscope, many small particles of 20 to 30 nm were observed in addition to particles of 80 to 100 nm, and the particle size distribution was non-uniform. Further, when the average secondary particle size was measured with a centrifugal particle size distribution analyzer (CAPA-700 from Horiba, Ltd.), the average secondary particle size was 0.45 μm. The yield of the particles was almost 100%. When the particles were dried and analyzed for impurities, they contained 99.5% cerium oxide, and the powder X-ray diffraction was measured to find the characteristic peak of cubic ceric oxide described in ASTM card 34-394. Matched. Moreover, the specific surface area value by the gas adsorption method (BET method) is 25.0 m.²/ G.
[0059]
Example 4
NH in a 1 liter glass reactor_Three/ Ce³⁺= 20 (molar ratio) of 20% ammonia aqueous solution 238g was charged, while maintaining the liquid temperature at 50 ° C CeO₂/ Rare earth oxide = 762 g of cerium (III) nitrate aqueous solution having a purity of 99.0% (CeO₂A cerium (III) hydroxide suspension was obtained by gradually adding a conversion amount of 80 g). Subsequently, the suspension was heated to 80 ° C. over 30 minutes, and 2 L / min of air was blown from a glass nozzle to start an oxidation reaction in which cerium (III) was converted to cerium (IV). The oxidation reaction was completed in 5 hours. The reaction-completed liquid was returned to room temperature, and a reaction liquid having light yellow fine particles with pH = 6.1 and electric conductivity of 127 mS / cm was obtained.
[0060]
After the reaction solution was washed with water by Nutsche, the wet cake was redispersed with pure water, and the conductivity was 42 μS / cm, CeO.₂A slurry having a concentration of 23.4 wt% was obtained. The slurry was adjusted to pH 5 with 10% nitric acid, and CeO.₂A slurry having a concentration of 5% by weight was prepared.
[0061]
Observation of the obtained particles with a transmission electron microscope revealed many small particle sizes of 20 to 30 nm in addition to particles of 80 to 100 nm, and the particle size distribution was uneven. Moreover, when the average secondary particle diameter was measured with a centrifugal particle size distribution analyzer (CAPA-700 from Horiba, Ltd.), the average secondary particle diameter was 0.47 μm. The yield of the particles was almost 100%. When the particles were dried and analyzed for impurities, they contained 99.5% cerium oxide, and when powder X-ray diffraction was measured, the characteristic peak of cubic cerium oxide described in ASTM Card 34-394 Matched. Moreover, the specific surface area value by a gas adsorption method (BET method) is 26.1 m.²/ G.
[0062]
Comparative Example 1
Commercially available cerium oxide powder (average secondary particle size 1.4 μm, cerium oxide content 57%, specific surface area by gas adsorption method (BET method) is 3.0 m.²/ G) is dispersed in pure water and CeO₂A slurry having a concentration of 5% by weight was prepared.
[Polishing test]
Glass hard disk is made of SiO₂77.9% by weight, Al₂O_ThreeA 3.5-inch aluminosilicate tempered glass substrate consisting of 17.3% by weight and 4.8% by weight ZnO was used. This substrate was first polished, and the average surface roughness was 7.3 angstroms.
[0063]
An artificial leather type polyurethane polishing cloth (POLITEX DG (trademark), 38 mmφ, made by Speed Fam) is pasted on the lap master LM-15 polishing machine (manufactured by lap master), and it is made to face the polishing surface of the substrate to 11 KPa. Polishing was performed with a load of.
[0064]
The rotation speed of the surface plate is 45 rotations per minute, and the supply amount of the abrasive slurry is 10 ml / min. After polishing, the work piece was taken out, washed with pure water, dried, and the polishing rate was determined from the weight loss. The average surface roughness (Ra) of the polished surface was measured with New View 100 (manufactured by Zygo).
[0065]
Table 1 shows the polishing rate, the average surface roughness (Ra), and the ratio of the polishing rate to the average surface roughness.
[0066]
[Table 1]

From Table 1, Examples 1 and 2 having an average secondary particle size of 0.3 μm and a cerium oxide content of 99.5% have an average secondary particle size of 1.4 μm and a cerium oxide content of 57. % Of the average surface roughness is smaller than that of Comparative Example 1, and the ratio of the polishing rate to the average surface roughness is high, indicating that the polishing characteristics are excellent.
[0067]
In Examples 3 and 4, since a large number of small particles of 20 to 30 nm are mixed, the polishing rate is slightly reduced. However, the average surface roughness is good, and it is useful as a precision abrasive for optical disks and magnetic glass hard disks.
[0068]
The cerium oxide particles obtained by the first production method and the second production method in which oxygen or an oxygen-containing gas is blown into cerium hydroxide obtained by reacting a cerium salt with an alkaline substance have a large specific surface area, and hydroxyl groups per unit weight. Suitable for chemical / mechanical polishing. The abrasive obtained by dispersing the cerium oxide powder in water scratches the polished surface, whereas the abrasive obtained by the first and second production methods of the present application is a good polished surface with few irregularities due to the chemical mechanical action. Is particularly suitable for applications that require precise polishing. Moreover, the cerium oxide abrasive obtained by this method exhibits a good polishing action on glass and is suitable for polishing glass hard disks.
[0069]
【The invention's effect】
An abrasive for an optical disk or glass substrate for a magnetic disk comprising a stable slurry in which ceric oxide particles having an average secondary particle diameter of 0.1 to 0.5 μm of the present invention are dispersed in water, and further in the abrasive The above-mentioned abrasive, in which the ratio of cerium in the total rare earth elements is 95% or more in terms of the weight of the oxide, has a small average surface roughness and a high ratio of the polishing rate to the average surface roughness and excellent polishing characteristics. ing.
[0070]
The abrasive | polishing agent of this invention can make an average surface roughness small by making the average secondary particle diameter of a cerium oxide particle small, and can obtain a quality polishing surface. Furthermore, the polishing rate is improved by setting the ratio of cerium in the total rare earth elements in the abrasive directly involved in polishing of the glass hard disk to 95% or more in terms of the weight of the oxide, and the average surface roughness is reduced. Since the ratio of the polishing rate is increased, the productivity of the polishing process can be improved and the cost can be reduced.
[0071]
In particular, the abrasive of the present invention is useful as a final abrasive because a high-quality polished surface can be obtained when a glass substrate for optical disks or magnetic disks is polished. This glass substrate for optical disks and magnetic disks is a glass hard disk made of crystallized glass, aluminosilicate tempered glass or soda lime tempered glass.
[0072]
The polishing composition obtained by adding a polishing accelerator such as aluminum nitrate, iron nitrate, basic aluminum sulfamate to the polishing liquid of the present invention is Ni-P or the like provided on an aluminum disk that can be supplied as an industrial product. It is useful for polishing the surface of the plating layer, the surface of the aluminum oxide layer, or the surface of aluminum, its alloy, or alumite.

Claims (1)

Oxygen or an oxygen-containing gas was blown into cerium hydroxide obtained by reacting a cerium salt with an alkaline substance in an aqueous medium, and the resulting slurry was washed to an electric conductivity of 20 μS / cm to 94 μS / cm, and then adjusted to pH. A stable slurry containing ceric oxide particles having an average secondary particle size of 0.1 to 0.5 μm, and containing 0.2 to 30% by weight as a CeO ₂ concentration, and the total rare earth in the abrasive A polishing agent for glass hard disk , characterized in that the proportion of cerium in the element is 95% or more in terms of weight of oxide .