Organic compounds -- part of the class 532-570 series – Organic compounds – Heavy metal containing
Reexamination Certificate
2002-06-21
2003-04-29
Nazario-Gonzalez, Porfirio (Department: 1621)
Organic compounds -- part of the class 532-570 series
Organic compounds
Heavy metal containing
C556S136000, C427S585000, C427S587000, C427S250000, C427S255310
Reexamination Certificate
active
06555701
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a CVD material for forming a ruthenium or ruthenium compound thin film.
2. Description of the Related Art
Recently, thin film electrodes made of ruthenium or ruthenium oxides are investigated for use in semiconductor devices such as Dynamic RAMs (DRAMs). These materials have lower resistivities which can provide excellent electric properties of the electrodes. They are investigated for use in the storage electrodes in capacitors for DRAMs. The materials are expected to significantly contribute to high density DRAMs. The ruthenium thin films draw attentions as one of major materials for the thin film electrodes.
The ruthenium or ruthenium thin films are often formed by the sputtering method as well as the chemical vapor deposition (hereinafter referred to as CVD) method. The CVD method can easily provide thin films of more uniformity and particularly higher step coverage than those by the sputtering method. Thus, the CVD method is expected to become a major process for manufacturing thin film electrodes which can provide recent circuits and electronic components of much higher density.
The CVD material for forming ruthenium and ruthenium compound thin films requires properties generally including a lower melting point and a higher vapor pressure. One of the recently proposed CVD methods is a solution CVD in which the material organic compound is not directly evaporated but is dissolved in a solvent such as an organic solvent which is then vaporized. The solution CVD is effective for a material organometallic compound of a higher melting point but the solution CVD requires a material to be soluble in the organic solvent.
Recent investigations on organic ruthenium compounds which have the above properties have proposed various organic ruthenium compounds. One of the compounds is described in Japanese Patent Application Laid-Open No. 2000-212744 which discloses &bgr;-diketonato-ruthenium expressed by the following formula.
where, R1 and R2 represent different alkyls having 1 to 4 carbon atoms.
The above organic ruthenium compound comprises a ruthenium metal coordinated with &bgr;-diketone. The compound has a lower melting point and exists in liquid states at room temperature and also has higher solubility and stability in organic solvents. Thus, the compound itself can be handled easily as CVD material and also serve as a suitable material for the solution CVD.
However the inventors found out that the above described ruthenium compound may produce ruthenium thin films by CVD process which can have relatively easy handling and high purity but poor morphology, particularly high surface roughness.
The surface roughness is very small on the order of nanometer which can, however, have a large impact on thin film electrodes. In addition, recent semiconductor devices have been required to have higher performances, and particularly research works on DRAMs aim to increase their capacitance from Mbit to Gbit size. For those purposes, the devices should essentially have very high densities so that thin film electrodes need to have morphology with very high precision.
The present invention is made under the above described background. It is an object of the present invention to provide a CVD material compound based on an organic ruthenium compound, which has a lower melting temperature, higher solubility in solvent and capability of forming a good morphology thin film, and a method for manufacturing the material compound.
SUMMARY OF THE INVENTION
To solve the above mentioned problems, the inventors have paid attention to tris (2,4-octa-dionato) ruthenium which is one of the &bgr;-diketonato ruthenium as expressed by the formula 2. Tris (2,4-octa-dionato) ruthenium is also found to show poor thin film morphology. The investigations of the morphology have shown that tris (2,4-octa-dionato) ruthenium has two geometrical isomers, cis and trans isomers as shown in FIG.
1
and the known manufacturing methods produce tris (2,4-octa-dionato) ruthenium which consists of the two geometrical isomers. It has also been shown that mixed isomers of tris (2,4-octa-dionato) ruthenium can not form thin films having good step coverage.
The different geometrical isomers have the same molecular formula and very different physical properties. As regards the properties of the CVD materials, the different geometrical isomers are considered to have different evaporation and decomposition rates. Thus mixed geometrical isomers of the compounds cannot form thin films at a constant deposition rate during the CVD process and may degradate the thin film morphology. It has not been disclosed how the thin film morphology is affected by the CVD process which uses mixed isomers of an organic metal compound. The inventors have recognized that the CVD material requires such properties that it has high purity and does not have mixed isomers but has one of the isolated isomers. The recognition has led the inventors to the present invention.
The present invention provides a CVD material compound based on an organic ruthenium compound, the organic ruthenium compound consisting only of one of cis and trans isomers of tris (2,4-octa-dionato) ruthenium (III) as expressed by the following formula.
According to the present invention, the geometrical isomers are isolated and only the cis or trans isomer can be the main ingredient so that the evaporation, decomposition, and deposition rates can be kept constant. According to the present invention, the preferable ruthenium compound is the trans geometrical isomer which can form thin films of smaller surface roughnesses and better morphology.
According to the present invention, mixed geometrical isomers tris (2,4-octa-dionato) ruthenium are separated into the cis and trans isomers each of which is used independently as a CVD material. The cis and trans isomers have different dipole moments. The trans isomer can have a smaller dipole moment in the complex molecular which may provide a lower adsorption on the adsorbent such as an alumina. Since the dipole moment results from the vector sum of the bond moments, the cis isomer can have a dipole moment larger than that of the trans isomer which may provide a higher adsorption on the adsorbent. According to the present invention, the above natures are used to isolate the geometrical isomers of tris (2,4-octa-dionato) ruthenium. Specifically, the alumina adsorbent adsorbs mixed geometrical isomers of tris (2,4-octa-dionato) ruthenium. Then a solvent is passed through the adsorbent to first elute the trans isomer which has a smaller dipole moment (or lower adsorbability). Then another solvent having a polarity higher than that of the first solvent is passed through the adsorbent to elute the cis isomer. Thus, both isomers are isolated to be used as CVD materials.
In other words, a method for producing a CVD material compound according to the present invention comprises the steps of preparing tris (2,4-octa-dionato) ruthenium (III), adsorbing the tris (2,4-octa-dionato) ruthenium (III) on an adsorbent including alumina, and contacting the adsorbent with a first solvent to elute the trans isomer and then contacting the adsorbent with a second solvent having a polarity higher than that of the first solvent to elute the cis isomer.
The first and second solvents should basically be selected to have different polarities. In general, nonpolar solvents include hexane, cyclohexane, benzene etc., and the polar solvents include alcohol, acetone, ethyl acetate etc. According to the present invention, the above compounds can be used either alone or in combination. For example, as the first solvent can be used one of the above nonpolar solvents alone, and as the second solvent can be used one of the above polar solvents alone. Alternatively, as the first and second solvents can be used in nonpolar and polar solvents different mixtures. The solvents are mixed to provide different polarities for each mixture. As a specific example, as the first and second solvents can be used
Okamoto Koji
Saito Masayuki
Suzuki Hiroaki
Taniuchi Jun-ichi
Nazario-Gonzalez Porfirio
Rothwell Figg Ernst & Manbeck
Tanaka Kikinzoku Kogyo K.K.
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