KR101543272B1 - Depositing Apparatus including Vaporizer - Google Patents

Abstract

The present invention relates to a vapor deposition apparatus having a vaporizer in which a vaporization efficiency of a source material in a liquid state is increased by supplying a reactive gas or a solvent to a vaporizer, The vaporizer being vaporized; And a process chamber that receives the mixed gas from the vaporizer and deposits a thin film on the substrate by a complete reaction between the source material and the reactive gas.

Vaporizer, source material, reaction gas, solvent

Description

[0001] Depositing Apparatus including Vaporizer [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vapor deposition apparatus having a vaporizer, and more particularly, to a vapor deposition apparatus having a vaporizer in which a vaporization efficiency of a source material in a liquid state is increased by supplying a reactive gas or a solvent to a vaporizer.

Generally, a method of forming a material into a thin film is classified into a sputtering method using physical impact and a deposition method of supplying a raw material gas in a gaseous phase. A vapor deposition method is preferred, which is superior in uniformity of composition and thickness, and step coverage as a semiconductor device is highly integrated. In the vapor deposition method, a desired thin film is deposited on a substrate by supplying a source gas necessary for forming a thin film to a reaction chamber on which the substrate is placed. However, in the case where the source material used for forming the thin film exists in a liquid state instead of a gaseous state, the liquid source material is vaporized and then transported to the surface of the substrate inside the reaction chamber. Therefore, the source material is supplied in a liquid state to the vicinity of the source material inlet of the reaction chamber, and the source material in a liquid state is vaporized through the vaporizer to supply the source gas to the source gas.

However, in the conventional vaporizer, the liquid source material is not completely vaporized, and the source material in the liquid state and the gaseous state flows into the reaction chamber, and the thin film deposition process proceeds. The uniformity of the deposited thin film may be lowered or particles may be generated in the deposited thin film due to the source material in the liquid state flowing into the reaction chamber.

Hereinafter, a vapor deposition apparatus using a conventional vaporizer will be described with reference to FIG. 1 is a schematic view of a vapor deposition apparatus using a vaporizer according to the prior art.

In the prior art, a deposition apparatus in which a vaporizer is installed includes a process chamber 10 for carrying out a process of depositing a thin film on a substrate (not shown), and a process chamber 10 for supplying a source material 12 in a liquid state to the process chamber 10 A vaporizer 16 for converting the source material 12 into a gaseous state and supplying the source material 12 to the inside of the process chamber 10 and a reaction for supplying a reaction gas to the process chamber 10 A gas supply unit 52 and a carrier gas supply unit 42 for transferring the source material 12 in a liquid state to the vaporizer 16.

The process chamber 10 is a closed space capable of maintaining a vacuum state so that the thin film deposition process can be performed. Although not shown in the figure, the substrate space includes a substrate stand on which the substrate is placed, and a dispensing device for distributing the source gas and the reactive gas have. The source supply unit 14 includes a storage tank 18 in which the source material 12 in a liquid state is stored, a source material source (not shown) that supplies the source material 12 to the storage tank 18, A first carrier gas supply source (not shown) for supplying a first carrier gas such as Ar so that the source material 12 can be supplied to the vaporizer 16 within the carrier 18, And a first flow controller (MFC) 50 for controlling the flow rate of the fluid.

A carrier gas supply 42 connected to the vaporizer 16 is connected to a second carrier gas source such as Ar for supplying the source material converted to the gaseous state from the vaporizer 16 to the process chamber 10 along the supply line A second flow controller (MFC) 20 for controlling the flow rate of the second carrier gas, and a first heater 22 for heating the second carrier gas. The process chamber 10 is supplied with the unstable second carrier gas through the pumping line 26 to the trap device 24 without supplying the process gas to the process chamber 10. A vacuum pump (not shown) is connected to the trap device 24.

A reaction gas supply unit 52 for supplying a reaction gas to the process chamber 10 includes a reaction gas supply source (not shown), a third flow controller (MFC) 54 for controlling the flow rate of the reaction gas, And a second heater 56 for heating the gas. Between the vaporizer (16) and the pumping line (26) and between the vaporizer (16) and the heater (22)

1, argon (Ar) is used as a source including ruthenium (Ru) and first and second carrier gases as a source material in a liquid state, and oxygen (O2) or A ruthenium oxide film (RuO ₂ ) is deposited on the substrate using ozone (O 3). A liquid source including ruthenium is vaporized in the vaporizer 16 at a temperature of 100 to 190 占 폚 to be supplied to the process chamber 10 but the vaporization efficiency is low so that the thin film deposited on the substrate has a haze or brittle Blister) occurs.

In order to solve the problems of the prior art as described above, the present invention provides a method for vaporizing a source material and a reactive gas in an incomplete reaction state in a vaporizer, And to provide a vapor deposition apparatus having a vaporizer for vapor deposition.

Another object of the present invention is to provide a vapor deposition apparatus having a vaporizer in which a source material and a solvent are supplied to a vaporizer to increase the vaporization efficiency of the source material.

According to an aspect of the present invention, there is provided a vapor deposition apparatus having a vaporizer, including: a vaporizer that is supplied with a source material in a liquid state and a reaction gas and is vaporized into a mixed gas in an incomplete reaction state; And a process chamber that receives the mixed gas from the vaporizer and deposits a thin film on the substrate by a complete reaction between the source material and the reactive gas.

In the vapor deposition apparatus having the above-described vaporizer, the source material is an organic source including ruthenium, the reactive gas is oxygen or ozone, and the thin film is ruthenium or ruthenium oxide.

In the vapor deposition apparatus having such a vaporizer, the organic source is characterized by being Ru [(C ₂ H ₅ ) C ₅ H ₄ ] ₂ or Ru [(C ₇ H ₁₁ ) (C ₇ H ₉ )] .

In the deposition apparatus having a carburetor as described above, the source material in the liquid state comprises a zirconium (Zr) or titanium (Ti), and the reaction gas is oxygen or nitrogen, the thin film is zirconium oxide (ZrO _2), or And is a titanium nitride film (TiN).

In the vapor deposition apparatus having the above-described vaporizer, the temperature inside the vaporizer is about 100 to 200 ° C, and the temperature of the process chamber is about 250 to 500 ° C.

In the vapor deposition apparatus having the above-described vaporizer, a carrier gas is used to transport the mixed gas from the vaporizer to the process chamber.

According to an aspect of the present invention, there is provided a vapor deposition apparatus having a vaporizer, including: a vaporizer supplied with a liquid source material and a solvent to vaporize the source material into a source gas; A reaction gas supply unit for supplying a reaction gas; And a process chamber that receives the source gas and the reaction gas from the reaction gas supply unit from the vaporizer and deposits a thin film on the substrate by reaction between the source gas and the reaction gas.

In the vapor deposition apparatus having the above-described vaporizer, the source material is an organic source including ruthenium, the reactive gas is oxygen or ozone, the thin film is a ruthenium oxide film, and the solvent is an alcohol-based material such as THF (TetraHydroFuran) .

In the deposition apparatus having a carburetor as described above, the source material in the liquid state comprises a zirconium (Zr) or titanium (Ti), and the reaction gas is oxygen or nitrogen, the thin film is zirconium oxide (ZrO _2), or And is a titanium nitride film (TiN).

The substrate processing apparatus having the vaporizer according to the embodiment of the present invention has the following effects.

The present invention vaporizes an incomplete reaction state of a source material and a reactive gas in a vaporizer, and deposits a defect-free thin film on the substrate by a complete reaction of the source material and the reactive gas in the process chamber. Also, the source material and the solvent are supplied to the vaporizer to increase the vaporization efficiency of the source material.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

2 is a schematic view of a vapor deposition apparatus using a vaporizer according to the first embodiment of the present invention. In the first embodiment of the present invention, argon is used as an organic material including ruthenium as a source material and carrier gas in a liquid state, and oxygen or ozone is used as a reaction gas reacting with ruthenium. Then, a method of vaporizing a source material and a reaction gas into an incomplete reaction state in a vaporizer, and depositing a high-quality ruthenium oxide film on a substrate by a complete reaction in a process chamber will be described.

In the first embodiment of the present invention, the vapor deposition apparatus in which the vaporizer is installed includes a process chamber 110 in which a source material is supplied and a thin film is deposited on a substrate (not shown), a source material 112 in a liquid state A vaporizer 116 for vaporizing the reactant gas into an incomplete reaction state and supplying the source gas 112 to the inside of the process chamber 110; And a carrier gas supply unit 142 for transferring the reactant gas to the vaporizer 116. The reactant gas supply unit 152 supplies the reactant gas to the vaporizer 116,

The process chamber 110 is a closed space in which a vacuum state can be maintained so that a thin film deposition process can be performed. Although not shown in the figure, a substrate stand for placing a substrate on the inner space and a distributor for distributing the source gas and the reactive gas are provided have. The source supply unit 114 includes a storage tank 118 in which the source material 112 in a liquid state is stored, a source material source (not shown) for supplying the source material 112 to the storage tank 118, A first carrier gas supply source (not shown) for supplying a first carrier gas such as Ar so that the source material 112 can be supplied to the vaporizer 116 in the inside of the vapor source 118, And a first flow controller (MFC) 150 for controlling the flow rate of the fluid.

A carrier gas supply 142 connected to the vaporizer 116 is connected to a second carrier gas source such as Ar for supplying the source material converted to the gaseous state from the vaporizer 116 to the process chamber 110 along the supply line A second flow controller (MFC) 120 for controlling the flow rate of the second carrier gas, and a first heater 122 for heating the second carrier gas. The second carrier gas, whose supply flow rate is unstable, is supplied to the trap device 124 through the pumping line 126 without supplying the process chamber 110 with the second carrier gas. A vacuum pump (not shown) is connected to the trap device 124. And the pumping line 126 and the connection pipe of the vaporizer 116 and the process chamber 110 use 1/4 inch pipe having twice the diameter as compared with the pipe used for the other part. The other part of the pipe has a diameter of 1/8 inch.

The reaction gas supply unit 152 for supplying the reaction gas to the vaporizer 116 includes a reaction gas supply source (not shown), a third flow controller (MFC) 154 for controlling the flow rate of the reaction gas, And a second heater 156 for heating the second heater 156. The vaporizer 116 is provided with an inlet at the upper portion and a discharge portion at the lower portion to easily remove the carrier gas or the source material remaining in the vaporizer 116 by the pumping line 126. A valve as required is mounted and used between the vaporizer 116 and the pumping line 126 and between the vaporizer 116 and the first and second heaters 122 and 156. [

In the vapor deposition apparatus as shown in Fig. 2, as a source material in a liquid state Ru [(C2H5) C5H4] or _{Ru [(C 7 H 11)} (C 7 H 9)] and the like ruthenium organic source and the first and second carrier A ruthenium oxide film (RuO ₂ ) is deposited on a substrate by using argon (Ar) as a gas and oxygen (O 2) or ozone (O 3) as a reaction gas. NH ₃ is used to deposit a thin film of ruthenium on a substrate in a process chamber 110 using a plasma.

When the ruthenium organic source and oxygen or ozone as a reaction gas are supplied to the vaporizer 116, the pressure and the temperature of the vaporizer 116 are low, and ruthenium and oxygen or ozone are not completely reacted, and unreacted mixed gas ) State. A mixed gas of ruthenium and oxygen or ozone is supplied from the vaporizer 116 to the interior of the process chamber 110 having sufficient temperature and pressure conditions for the reaction so that ruthenium reacts with oxygen or ozone to form a high quality A ruthenium oxide film is deposited. The flow rate of the ruthenium organic source flowing into the vaporizer 116 is about 100 to 1000 sccm, and the carrier gas is used at 200 to 500 sccm. The ratio of the reaction gas supplied to the vaporizer 116 and the first and second carrier gases is 1 to 100%.

A zirconium oxide film (ZrO ₂ ), a titanium nitride film (TiN), or the like can be formed as a thin film by using zirconium (Zr) or titanium (Ti) as a source material in a liquid state and oxygen or nitrogen as a reaction gas. The process chamber 110 is higher than the internal temperature of the vaporizer 116. The temperature inside the vaporizer 116 is about 100 to 200 占 폚, and preferably vaporizes the liquid source at 170 占 폚. The reaction temperature of the source material and the reaction gas in the process chamber 110 is about 250 to 500 ° C. However, the reaction temperature may be set differently depending on whether or not a thin film such as a silicon oxide film is formed on the substrate. Ruthenium reacts with a reaction formula such as' Ru [(C ₂ H ₅ ) C ₅ H ₄ ] ₂ + O ₂ => Ru + CO ₂ + H ₂ O + C ₂ H ₅ + by-

3 is a schematic view of a vapor deposition apparatus using a vaporizer according to a second embodiment of the present invention. In the second embodiment of the present invention, argon is used as an organic material containing ruthenium and a carrier gas as a source material in a liquid state, and oxygen or ozone is used as a reaction gas reacting with ruthenium. Then, a method of depositing a ruthenium oxide film on a substrate by supplying a solvent capable of diluting the ruthenium organic source together with the ruthenium organic source to the vaporizer to increase the vaporization efficiency will be described.

In the second embodiment of the present invention, the deposition apparatus in which the vaporizer is installed includes a process chamber 210 to which a source material is supplied and a thin film is deposited on a substrate (not shown), a source material 212 in a liquid state A vaporizer 216 for vaporizing the source material 212 and a slurry and supplying the source material 212 to the inside of the process chamber 210, A solvent supply section 260 for supplying a solvent for diluting the source material 212, a reaction gas supply section 252 for supplying a reaction gas to the process chamber 210, And a carrier gas supply unit 242 for transferring the carrier gas 212 to the vaporizer 216.

The process chamber 210 is a closed space capable of maintaining a vacuum state so that the thin film deposition process can be performed. Although not shown in the figure, the substrate space includes a substrate stand on which the substrate is placed, and a dispensing device for distributing the source gas and the reactive gas have. The source supply unit 214 includes a storage tank 218 in which the source material 212 in a liquid state is stored, a source material source (not shown) that supplies the source material 212 to the storage tank 218, A first carrier gas supply source (not shown) for supplying a first carrier gas such as Ar so that the source material 212 can be supplied to the vaporizer 216 in the interior of the liquid source material 212 And a first flow controller (MFC) 250 for controlling the flow rate of the fluid.

A carrier gas supply 242 connected to the vaporizer 216 is connected to a second carrier gas source such as Ar for supplying the source material converted to the gaseous state from the vaporizer 216 to the process chamber 210 along the supply line A second flow controller (MFC) 220 for controlling the flow rate of the second carrier gas, and a first heater 222 for heating the second carrier gas. The second carrier gas, whose supply flow rate is unstable, is supplied to the trap device 224 through the pumping line 226 without supplying the process chamber 210 with the second carrier gas. A vacuum pump (not shown) is connected to the trap device 224.

The reaction gas supply unit 252 for supplying the reaction gas to the process chamber 210 includes a reaction gas supply source (not shown), a third flow controller (MFC) 254 for controlling the flow rate of the reaction gas, And a second heater (256) for heating the gas. A solvent supply unit 260 for supplying a solvent for diluting the liquid source material to the vaporizer 216 includes a solvent supply source (not shown) and a fourth flow controller (MFC) 262 for controlling the flow rate of the solvent And a third heater 264 for heating the solvent. The carburetor 216 is provided with an inlet portion at the upper portion and a discharge portion at the lower portion to easily remove the carrier gas or the source material remaining therein from the pump line 226. Between the vaporizer 216 and the pumping line 226 and between the vaporizer 216 and the first and third heaters 222 and 264 and between the process chamber 210 and the second heater 256, .

In the deposition apparatus as shown in FIG. 3, a ruthenium organic source such as Ru [(C ₂ H ₅ ) C ₅ H ₄ ] or Ru [(C ₇ H ₁₁ ) (C ₇ H ₉ )] containing ruthenium (Ru) , Argon (Ar) is used as the first and second carrier gas, and oxygen (O 2) or ozone (O 3) is used as the reaction gas. In addition, an alcohol-based material such as THF is used as a solvent for diluting the ruthenium organic source in the vaporizer 216. The ruthenium organic source is diluted by the solvent inside the vaporizer 216 and the distance between the particles of the ruthenium organic source is increased to increase the vaporization efficiency. The amount of the solvent used in the vaporizer 216 is about 50 to 200% of the ruthenium organic source. The vaporization efficiency of the ruthenium organic source is increased by the solvent supplied to the vaporizer 216 so that the ruthenium organic source supplied from the vaporizer 216 and the oxygen or ozone supplied from the reaction gas supply unit 252 in the process chamber 210 And a high-quality ruthenium oxide film can be deposited on the substrate by a complete reaction. In the second embodiment, zirconium oxide (ZrO ₂ ) or zirconium oxide (ZrO ₂ ) is formed as a thin film by using zirconium (Zr) or titanium (Ti) as a source material in a liquid state and oxygen or nitrogen as a reaction gas A titanium nitride film (TiN) or the like can be formed.

1 is a schematic view of a vapor deposition apparatus using a vaporizer according to the prior art;

2 is a schematic view of a vapor deposition apparatus using a vaporizer according to a first embodiment of the present invention;

3 is a schematic view of a vapor deposition apparatus using a vaporizer according to a second embodiment of the present invention

Claims (10)

A process chamber; A vaporizer whose one end is connected to the process chamber; A source supply unit connected to the other end of the vaporizer to supply a liquid source material to the vaporizer; And a reaction gas supply unit connected to the other end of the vaporizer to supply the reaction gas to the vaporizer, Wherein the source material is heated to a first temperature and is vaporized in the vaporizer while the source material and the reaction gas are heated to the first temperature to incomplete reaction in the vaporizer to generate a mixed gas, Wherein the mixed gas is supplied to the process chamber and is completely reacted at a second temperature higher than the first temperature to form a thin film on the substrate in the process chamber. delete The method according to claim 1, Wherein the source material is an organic source including ruthenium, the reaction gas is oxygen or ozone, and the thin film is a ruthenium or ruthenium oxide film. The method of claim 3, Wherein the organic source is Ru [(C ₂ H ₅ ) C ₅ H ₄ ] ₂ or Ru [(C ₇ H ₁₁ ) (C ₇ H ₉ )]. The method according to claim 1, Wherein the liquid source material comprises zirconium (Zr) or titanium (Ti), the reaction gas is oxygen or nitrogen, and the thin film is a zirconium oxide (ZrO ₂ ) or titanium nitride (TiN) Lt; / RTI > The method according to claim 1, Wherein the first temperature is between 100 and 200 ° C, and the second temperature is between 250 and 500 ° C. The method according to claim 1, And a carrier gas supply unit for supplying a carrier gas for conveying the mixed gas to the process chamber in the vaporizer. delete Supplying a source gas and a reactant gas in a liquid state to a vaporizer having a first temperature; The source material in the liquid state is heated and vaporized at the first temperature and the source material and the reactive gas are heated at the first temperature to be vaporized to an incomplete reaction state to produce a mixed gas; Supplying the mixed gas in a process chamber having a second temperature higher than the first temperature to deposit a thin film on a substrate positioned in the process chamber To form a thin film. delete

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