KR20070098125A - Method for equipment for chemical vapor deposition - Google Patents

Abstract

A chemical vapor depositing method is provided to increase or maximize production yield by preventing an error of an initial depositing process for a thin film. A chemical vapor depositing method includes a step of supplying a predetermined quantity of first source gas to the inside of a chamber by a source gas supply unit; a step of bypassing second source gas through a dump line connected with a ventilation unit pumping and ventilating the air of the chamber by the source gas supply unit(s200); a step of supplying the first and second source gas to the chamber and stabilizing a vacuum degree inside the chamber at a regular degree by pumping the air of the inside for the chamber(s300); and a step of forming a predetermined thin film on a wafer positioned inside the chamber, by inducing a plasma reaction giving high-frequency power to the first and second source gas supplied to the chamber(s400).

Description

Chemical vapor deposition method {Method for Equipment for chemical vapor deposition}

1 is a view schematically showing the structure of a conventional chemical vapor deposition apparatus.

Figure 2 is a flow chart shown for explaining the chemical vapor deposition method according to the prior art.

Figure 3 schematically shows the structure of the chemical vapor deposition apparatus of the present invention.

Figure 4 is a flow chart showing for explaining the chemical vapor deposition method according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100: source gas supply unit 200: process chamber

300: exhaust unit 400: purge gas supply unit

500: dump line

The present invention relates to a semiconductor manufacturing method, and more particularly to a chemical vapor deposition method for forming a thin film, such as a silicon oxide film on a wafer.

Recently, in the semiconductor manufacturing industry, the minimum line width applied to the semiconductor integrated circuit process has been steadily decreasing to increase the operation speed of the semiconductor chip and increase the information storage capability per unit area. In addition, the size of semiconductor devices such as transistors integrated on semiconductor wafers has been reduced to sub-half microns or less.

Such a semiconductor device may be manufactured through a deposition process, a photo process, an etching process, and a diffusion process, and at least one semiconductor device may be formed when these processes are repeated several times several times. In particular, the deposition process is an essential process requiring improvement in the reproducibility and reliability of semiconductor device fabrication, such as a sol-gel method, a sputtering method, an electroplating method, and an evaporation method. , A process of forming the processed film on the wafer by a chemical vapor deposition method, a molecular beam epitaxy method, an atomic layer deposition method, or the like.

Among them, the chemical vapor deposition method is most commonly used because of the excellent deposition characteristics and the uniformity of the processed film formed on the wafer than other deposition methods. Such chemical vapor deposition methods may be divided into low pressure chemical vapor deposition (LPCVD), atmospheric pressure chemical vapor deposition (APCVD), low temperature chemical vapor deposition (LTCVD), plasma enhanced chemical vapor deposition (PECVD), and the like.

For example, the PECVD is a process of forming a dielectric film by depositing water formed on a wafer by chemical reaction in a gas through an electrical discharge. In the conventional PECVD process, a plurality of wafers are introduced into a plasma chemical vapor deposition apparatus, and a specific film is formed on the plurality of wafers by collectively performing a PECVD process. However, recently, semiconductor devices have been highly integrated and wafers As the large diameter is hardened, a single wafer is introduced into the plasma chemical vapor deposition apparatus, and then a PECVD process is performed. After the PECVD process is performed on the single wafer, the residual gas and A washing and purging process is performed to remove the reaction product.

A chemical vapor deposition apparatus for depositing an interlayer insulating film such as a silicon oxide film by such a chemical vapor deposition method is disclosed in US Pat. No. 6,009,827.

Hereinafter, a chemical vapor deposition apparatus and a chemical vapor deposition method using the same will be described with reference to the accompanying drawings.

1 is a view showing the configuration of a conventional chemical vapor deposition apparatus in detail.

As shown in FIG. 1, the chemical vapor deposition apparatus according to the related art is supplied through a source gas supply unit 10 that largely generates a source gas, and a supply line 12 connected to the source gas supply unit 10. The process chamber 20 provides a predetermined sealed space so that a predetermined thin film is formed on the wafer 22 using the source gas, and an exhaust line 32 communicating with the process chamber 20. An exhaust unit 30 for pumping air in the process chamber 20, branched from the supply line 12, and connected to the exhaust line 32, and in the source gas supply unit 10, the process chamber 20. ) And a dump line 50 formed to bypass the source gas in the exhaust part 30.

Here, the source gas supply unit 10 is chemically reacted in the process chamber 20 to generate a plurality of source gases for forming the thin film and supply them to the process chamber 20 at a predetermined flow rate. For example, oxygen gas and TEOS gas may be used as the source gas. Supply connected to each of the oxygen gas tank 15a and the TEOS gas tank 15b so that the oxygen gas and the TEOS gas supplied from the source gas supply unit 10 are mixed at a predetermined flow rate and supplied to the process chamber 20. In line 12 there is formed a Liquid Flow Controller (LCC) 14 that regulates the flow rates of the oxygen gas and the TEOS gas. In addition, the source gas supply unit 10 may further include a purge gas supply unit 40 supplying a purge gas into the process chamber 20.

In addition, the process chamber 20 is formed below the process chamber 20 to support and fix the wafer 22 on which the thin film is to be formed, and the process facing the chuck 24. A shower head 25 formed above the chamber 20 to inject oxygen gas and TEOS gas onto the wafer 22, and formed above the shower head 25 or below the chuck 24. And at least one plasma electrode 26 for inducing a plasma reaction in a high temperature ion state to form the silicon oxide film having high uniformity by mixing the oxygen gas and the TEOS gas. The plasma electrode 26 receives RF power from the outside to induce a plasma reaction.

In addition, the exhaust unit 30 is connected to the exhaust line 32 in communication with the process chamber 20, a vacuum pump 34 for pumping air in the process chamber 20, and the exhaust line ( It is formed in the middle of 32 and comprises a pressure control valve 36 for regulating the amount of air pumped to the vacuum pump 34 to maintain the vacuum pressure inside the process chamber 20. Although not shown, the exhaust part 30 further includes a scrubber for purifying the exhaust gas of the source gas from the air exhausted through the vacuum pump 34 and discharging it to the atmosphere.

Finally, the dump line 50 does not supply at least one source gas supplied from the source gas supply unit 10 to the process chamber 20 before the thin film process in the process chamber 20 starts. It is formed to be discharged directly to the exhaust unit 30. In addition, a dump valve 52 is formed at an inlet of the dump line 50 so that the source gas is bypassed through the dump line 50.

The conventional chemical vapor deposition method using the chemical vapor deposition apparatus configured as described above is as follows.

FIG. 2 is a flowchart illustrating a chemical vapor deposition method according to the related art. In the conventional chemical vapor deposition method, when the wafer 22 is loaded into the process chamber 20, the inside of the process chamber 20 may be used. Pump the air (S10). Here, the pumping in the process chamber 20 is pumped to a higher vacuum than in a deposition process using a subsequent chemical vapor deposition method. That is, when the wafer 22 is loaded, the air inside the process chamber 20 is pumped to a high vacuum state to remove the air containing the external contaminants from the inside of the process chamber 20.

Next, while supplying an oxygen gas of a predetermined flow rate into the process chamber 20, the TEOS gas is bypassed through the dump line 50 (S20). Here, the oxygen gas is a first source gas, and when the oxygen gas is supplied into the process chamber 20, the process chamber 20 has a low vacuum state in which a subsequent deposition process may be performed in a high vacuum state. Is set. In addition, the TEOS gas is a second source gas, which is excellent in reactivity with the oxygen gas and is bypassed through the dump line 50 through the dump line 50 before deposition.

Subsequently, a TEOS gas is supplied together with the oxygen gas at a predetermined flow rate into the process chamber 20 and a plasma reaction is induced to form a thin film such as a silicon oxide film on the wafer 22 (S30). Here, the oxygen gas and the TEOS gas is mixed in the LFC and flows on the top of the wafer 22. At this time, the oxygen gas and the TEOS gas may be bonded by a high temperature plasma reaction because the coupling reaction does not occur uniformly at room temperature, thereby forming a silicon oxide film.

However, if the plasma reaction is induced as soon as the oxygen gas and the TEOS gas are supplied into the process chamber 20, the vacuum on the wafer 22 is not stabilized on the wafer 22. A thin film is formed, which may cause a failure of the initial deposition process of the thin film.

In addition, when the plasma reaction is induced while the oxygen gas and the TEOS gas flowing on the wafer 22 are not sufficiently uniformly mixed, a spark discharge is generated to deposit a thin film deposited on the wafer 22. In addition to being irregularly formed, the oxygen gas and the unreacted TEOS gas may be condensed on the surface of the wafer 22 to cause deposition failure. Subsequently, when a thin film having a predetermined thickness is deposited on the wafer 22, the oxygen gas and the TEOS gas may be uniformly mixed by the plasma reaction to deposit a thin film having an excellent surface state. In this case, when the thin film initially deposited on the wafer 22 is defective, the state of the thin film initially deposited on the wafer 22 is important because the thin film deposited thereafter is also formed while maintaining the initial defective state. .

Next, when the silicon oxide film is formed to a predetermined thickness, the supply of the oxygen gas and the TEOS gas supplied into the process chamber 20 is stopped, and the RF power supplied to the plasma electrode 26 is cut off to cause the plasma reaction. In operation S40, the oxygen gas and the TEOS gas in the process chamber 20 are removed by pumping the air in the process chamber 20.

In addition, a purge gas is supplied to completely remove the oxygen gas and the TEOS gas remaining in the process chamber 20, and the air in the process chamber 20 is continuously pumped (S50).

Finally, the supply of the purge gas is stopped, and the purge gas in the process chamber 20 is pumped (S70). Of course, such supply and pumping of the purge gas may be continuously performed periodically a plurality of times.

As described above, the conventional chemical vapor deposition method has the following problems.

First, in the conventional chemical vapor deposition method, as soon as TEOS gas bypassed through the dump line 50 is mixed with oxygen gas and supplied to the process chamber 20, a plasma reaction is induced to form a thin film on the wafer 22. As a result, the thin film is formed in a state in which the vacuum degree of the process chamber 20 is not stabilized, which may cause a defect in the initial deposition process of the thin film.

Second, in the conventional chemical vapor deposition method, when the oxygen gas and the TEOS gas are induced into the process chamber 20 and the plasma reaction is induced, the oxygen gas and the TEOS gas flowing on the wafer 22 are sufficiently supplied. Since the plasma reaction is induced in a state where it is not uniformly mixed, a flame discharge is generated so that a thin film deposited on the wafer 22 is irregularly formed, and the TEOS gas which is not reacted with the oxygen gas forms the wafer 22. Due to condensation on the surface of the initial deposition failure occurs there was a problem that the production yield falls.

An object of the present invention for solving the above problems according to the prior art, the thin film is formed in a state in which the vacuum degree of the process chamber 20 is stabilized, to prevent the failure of the initial deposition process of the thin film production yield It is to provide a chemical vapor deposition method that can be increased or maximized.

In addition, another object of the present invention, the plasma reaction is induced in a state that the oxygen gas and TEOS gas flowing on the wafer 22 is sufficiently uniformly mixed, and the spark discharge on the wafer 22 It is possible to prevent an irregular formation of the deposited thin film and to prevent an initial deposition failure caused by condensation of the oxygen gas and the unreacted TEOS gas on the surface of the wafer 22, thereby increasing or maximizing production yield. To provide a chemical vapor deposition method.

Chemical vapor deposition method according to an aspect of the present invention for achieving the above object, the step of supplying a first source gas of a predetermined flow rate into the chamber from the source gas supply; Bypassing a second source gas through a dump line connected to an exhaust part for pumping and exhausting air in the chamber from the source gas supply part; Pumping air inside the chamber while supplying the first source gas and the second source gas to the chamber to stabilize the inside of the chamber to have a predetermined degree of vacuum; And applying a high frequency power to the first source gas and the second source gas supplied to the chamber to induce a plasma reaction to form a predetermined thin film on a wafer located inside the chamber. .

Hereinafter, the chemical vapor deposition method according to an embodiment of the present invention with reference to the drawings. The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited by the embodiments described below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shape of the elements in the drawings are exaggerated to emphasize a clearer description.

3 is a view schematically showing a chemical vapor deposition apparatus of the present invention.

As shown in FIG. 3, the chemical vapor deposition apparatus according to the present invention may be supplied through a source gas supply unit 100 generating a source gas and a supply line 102 connected to the source gas supply unit 100. A process chamber 200 that induces a plasma reaction using a source gas and provides a predetermined sealed space to form a thin film on the wafer 202, and an exhaust line 302 communicating with the process chamber 200. The exhaust unit 300, which pumps air in the process chamber 200, and the supply line 102 and the exhaust line 302 are connected to each other to form a thin film on the wafer 202. Bypass at least one source gas supplied to the process chamber 200 from the source gas supply unit 100 to the exhaust unit 300 without being supplied to the process chamber 200 before the Including a dump line 500 It is configured.

Here, the source gas supply unit 100 is chemically reacted in the process chamber 200 to generate a plurality of source gases in which the thin film is to be formed and supplied to the process chamber 200 at a predetermined flow rate. For example, the source gas may be an oxygen gas (eg, a first source gas) and a TEOS gas (eg, a second source gas). Therefore, the source gas supply unit 100 is supplied from the oxygen gas tank 105a and the TEOS gas tank 105b and the oxygen gas tank 105a and the TEOS gas tank 105b to generate and supply the source gas. Oxygen gas and TEOS flow-fed through the first and second flow control valves 106a and 106b and the first and second flow control valves 106a and 106b to control a supply flow rate of oxygen gas and TEOS gas. And first and second flow shutoff valves 108a and 108b which are opened and closed to selectively supply gas through the supply line 102 according to a predetermined condition. In addition, the supply line 102 connected to the oxygen gas tank 105a and the TEOS gas tank 105b may be configured to adjust a mixing ratio of the oxygen gas and the TEOS gas via an inlet of the dump line 500. It is coupled in an LFC (Liquid Flow Controller) 104. The LFC 104 not only mixes the different source gases supplied from the source gas supply unit 100 in a mixing ratio at a predetermined ratio, but also supplies them to the process chamber 200, and thin films on the wafer 202. The TEOS gas may be blocked by the TEOS gas that is not required in the process chamber 200 before the TEOS gas is bypassed through the dump line 500. In this case, the dump valve 502 formed adjacent to the inlet of the dump line 500 supplies the TEOS gas to the process chamber 200 through the supply line 102 or through the dump line 500. It is controlled to bypass the TEOS gas and is exclusively opened and closed with the LFC 104. The dump line 500 is an end of the supply line 102 to which the source gas is supplied from the source gas supply unit 100 to the process chamber 200, and from the process chamber 200 to the exhaust unit 300. It is connected to the exhaust line 302 at the end of the exhaust line 302 from which the exhaust gas is discharged, i.e., the front end of the low vacuum pump 304b to be described below.

In addition, the source gas supply unit 100 may include a purge gas supply unit 400 supplying a purge gas into the process chamber 200 through the supply line 102, and a supply line 102 supplying the source gas. It further comprises a cleaning gas supply unit (not shown) for supplying a cleaning gas into the process chamber 200 through the. Here, the purge gas supply unit 400 also has a purge gas tank 105c for generating and supplying purge gas, and a third flow rate control valve for controlling the flow rate of the purge gas flowing and supplied from the purge gas tank 105c ( 106c and a third flow shut-off valve 108c which is opened and closed to selectively supply the purge gas flowing through the third flow control valve 106c through the supply line 102 according to a predetermined condition. Including

The process chamber 200 is formed in the upper portion of the process chamber 200, the shower head 205 for uniformly injecting the source gas, such as oxygen gas and TEOS gas supplied from the source gas supply unit 100, and the A chuck 204 formed under the process chamber 200 corresponding to the shower head 205 to support and fix the wafer 202, and a lower portion of the chuck 204 or the shower head 205. Including at least one plasma electrode 206 formed on top to induce a plasma reaction in a high temperature state by RF power applied from the outside to mix the oxygen gas and TEOS gas to form a highly uniform silicon oxide film Is done. Although not shown, the apparatus further includes a heater for heating the wafer 202 fixed to the chuck 204 to a predetermined temperature, and a pressure gauge for measuring the vacuum pressure inside the process chamber 200. Here, the plasma electrode 206 is formed inside the chuck 204 on which the upper electrode 206a is disposed on the shower head 205 and the wafer 202 is supported to face the upper electrode 206a. The lower electrode 206b may be formed, and RF power may be applied to at least one of the upper electrode 206a and the lower electrode 206b to induce a plasma reaction in the process chamber 200. For example, the pressure gauge includes a 1 Torr baratron sensor (not shown) for measuring low pressure and a 100 Torr baratron sensor (not shown) for measuring the pressure inside the process chamber 200 in two steps. ) Is mainly used. In this case, the pressure gauge is installed directly in the process chamber 200 or installed in the exhaust line 302 to measure the pressure in the process chamber 200 by pumping the vacuum pump 304. In this case, the process chamber 200 is configured as part of a cluster-type process equipment, and the wafer 202 requiring the thin film forming process is loaded or unloaded into the process chamber 200. It has a relatively high pressure compared to a transfer chamber (not shown) in communication with the process chamber 200. In addition, the plasma electrode 206 is composed of an upper electrode and a lower electrode to output at least one of high frequency or low frequency to induce a plasma reaction, and the oxygen gas and TEOS supplied between the shower head and the chuck 204. The gases can be mixed to form a uniform silicon oxide film. In this case, the oxygen gas and the TEOS gas is a plasma reaction is induced, the oxygen gas and the TEOS gas is uniformly injected from the front surface of the wafer 202 is injected from the center of the wafer 202 is the wafer 202 It flows to the edge of and is exhausted to the exhaust part 300 through the exhaust line 302. For example, there is a distance of about 1.5 cm between the shower head 205 and the wafer 202.

In addition, the exhaust part 300 is connected to the exhaust line 302 in communication with the process chamber 200, a vacuum pump 304 for pumping air in the process chamber 200, and the vacuum pump ( A pressure regulating valve 306 is formed at the front end of the exhaust line 302 to regulate the amount of air pumped to the vacuum pump 304 to maintain the vacuum pressure inside the process chamber 200. It is made to include. Here, the vacuum pump 304 for gradually pumping the air in the process chamber 200 is a turbo pump or a diffusion pump from the rear end of the exhaust line 302 in which the pressure regulating valve 306 is formed. A high vacuum pump 304a such as a diffusion pump and a low vacuum pump 304b such as a dry pump are each configured in series. For example, an exhaust line 302 connected to the process chamber 200 is connected to the high vacuum pump 304a, branched off from an exhaust line 302 between the high vacuum pump 304a and the process chamber 200. A roughing valve 308a is formed at the exhaust line 302 connected to the exhaust line 302 at the rear end of the high vacuum pump 304a and the roughing at the exhaust line 302 connected to the low vacuum pump 304b. A foreline valve 308 is formed between the front end connected to the exhaust line 302 where the valve 308a is formed and the high vacuum pump 304a. At this time, the roughing valve 308a and the four-line valve 308 are exclusively opened and closed to each other. For example, the exhaust pipe 302 to which the high vacuum pump 304a and the low vacuum pump 304b are connected in series in the process chamber 200 is called a for-line, and the process chamber 200 When the exhaust pipe 302 connected to the low vacuum pump 304b by bypassing the high vacuum pump 304a is referred to as a roughing line, the low vacuum pumps the air in the process chamber 200 through the roughing line. And high vacuum is pumped through the foreline. Although not shown, the exhaust part 300 further includes a scrubber for purifying the air exhausted through the low vacuum pump 304b or the source gas to discharge the air into the atmosphere.

In addition, the dump line 500 branched at the end of the source gas supply unit 100 is connected to the rear end of the roughing valve 308a and the four-line valve 308 and the front end of the low vacuum pump 304b. The source gas is bypassed from the source gas supply part 100 to the exhaust part 300 before the plasma reaction is induced in the process chamber 200.

The chemical vapor deposition method according to the embodiment of the present invention using the chemical vapor deposition apparatus configured as described above is as follows.

4 is a flowchart illustrating a chemical vapor deposition method according to an embodiment of the present invention.

As shown in FIG. 4, in the chemical vapor deposition method, the air is pumped into the process chamber 200 by using the low vacuum pump 304b and the high vacuum pump 304a of the exhaust unit 300. (S100). Although not shown, when the wafer 202 is loaded from the transfer chamber into the process chamber 200, the door formed between the process chamber 200 and the transfer chamber is closed to form a space independent of each chamber. . Here, the process chamber 200 may have a predetermined vacuum state by pumping the vacuum pump 304 connected to the process chamber 200 and the exhaust line 302. In this case, the vacuum state inside the process chamber 200 may be achieved by pumping the low vacuum pump 304b and the high vacuum pump 304a. For example, when the roughing valve 308a is opened, the air in the process chamber 200 is pumped to a low vacuum state of about 10-3 Torr using the low vacuum pump 304b. Then, the roughing valve 308a is closed and the process chamber 200 is opened through the pores using the high vacuum pump 304a and the low vacuum pump 304b in the state where the foreline valve 308 is opened. ) Pump internal air to high vacuum of about 10 ^-6 Torr.

Thereafter, the oxygen gas is flowed into the process chamber 200 at a predetermined flow rate, and the TEOS gas is bypassed to the exhaust part 300 through the dump line 500 (S200). Here, the process chamber 200 is again in a low vacuum state by the oxygen gas supplied into the process chamber 200. For example, the oxygen gas supplied into the process chamber 200 is supplied for about 20 seconds with a flow rate of about 8000 SCCM. At this time, the flow rate of the oxygen gas is controlled by the first flow control valve, it is supplied to the process chamber 200 in a state in which the first valve 104 is open. In addition, the roughing valve 308a of the exhaust line 302 is closed so that the process chamber 200 has a vacuum pressure of about 2.5 Torr while the oxygen gas flows in the process chamber 200. The low vacuum pump 304b and the high vacuum pump 304a pump air in the process chamber 200 while the valve 308 is open. Of course, the oxygen gas may be supplied while the low vacuum pump 304b pumps the air in the process chamber 200 while the roughing valve 308a is closed and the foreline valve 308 is open. have. At this time, the vacuum pressure inside the process chamber 200 is controlled by the opening and closing operation to the pressure control valve 306.

In addition, since the TEOS gas must be supplied to the process chamber 200 in a stable state when a silicon oxide film is to be formed in a subsequent reaction of the oxygen gas and the TEOS gas in the process chamber 200, the process chamber ( The TEOS gas at a flow rate to be supplied therein is bypassed to the dump line 500. That is, the TEOS gas should be heated to about 75 ° C. to flow into the process chamber 200, but the dump line 500 is very sensitive to initial deposition of a thin film formed on the wafer 202. Is bypassed). For example, when the oxygen gas flows into the process chamber 200 with a flow rate of about 8000 SCCM, the TEOS gas has a flow rate of about 350 SCCM and is bypassed through the dump line 500 for about 15 seconds. The TEOS gas is heated to bypass at a temperature of about 75 ° C., and the oxygen gas may also be heated to a temperature similar to that of the TEOS gas and supplied to the process chamber 200. At this time, the inside of the process chamber 200 is pumped by the vacuum pump 304 to have a vacuum pressure of about 2.5 Torr. In addition, the wafer 202 fixed on the chuck 204 in the process chamber 200 may be heated to a predetermined temperature by the heater.

Then, the degree of vacuum inside the process chamber 200 is stabilized while supplying the TEOS gas and the oxygen gas into the process chamber 200. Here, the process chamber 200 has a uniform mixing ratio of the TEOS gas and the oxygen gas in the internal space in which the wafer 202 is seated in the shower head to which the TEOS gas and the oxygen gas are supplied for a predetermined stabilization time. Can be mixed.

For example, the oxygen gas has a flow rate of about 8000SCCM, the TEOS gas has a flow rate of about 350SCCM, and the TEOS gas and the oxygen gas are supplied for a stabilization time of about 2 seconds to 5 seconds. At this time, the temperature inside the process chamber 200 is set to have about 70 ℃ to about 80 ℃. The wafer 202 is heated by the heater to have a temperature equal to or similar to the temperature required for the subsequent process chamber 200. The interior of the process chamber 200 is pumped by the vacuum pump 304 to have a vacuum pressure of about 2.5 Torr, the pressure of the vacuum pump is controlled by the pressure control valve 306.

Accordingly, in the chemical vapor deposition method according to the present invention, the source gas supply unit 100 supplies oxygen gas and TEOS gas to the process chamber 200 for a predetermined stabilization time to stabilize the vacuum degree of the process chamber 200. In order to form the thin film, and to prevent the failure of the initial deposition process of the thin film can increase or maximize the production yield.

Then, when the TEOS gas and the oxygen gas are supplied to the process chamber 200 during the stabilization time, high frequency power is applied to the plasma electrode 206 and the plasma reaction is induced to be fixed on the chuck 204. A silicon oxide film is formed on the wafer 202 (S400). Here, the plasma electrode 206 may excite the TEOS gas and the oxygen gas filled in the process chamber 200 into the plasma ion state having positive charges by separating electrons at a high temperature using the high frequency power. Can be. The TEOS gas and the oxygen gas supplied during the stabilization time inside the process chamber 200 before the plasma reaction is induced may be sufficiently mixed to fill the inside of the process chamber 200 with a predetermined mixing ratio. . In this case, the TEOS gas and the oxygen gas may be chemically combined on the wafer 202 when the plasma reaction is started to form a thin film such as a silicon oxide film on the wafer 202. Therefore, since the TEOS gas and the oxygen gas are mixed to have a constant mixing ratio to induce a plasma reaction, a thin film having excellent surface properties may be deposited during initial deposition of the thin film formed on the wafer 202. In addition, the TEOS gas and the oxygen gas may be uniformly mixed by the high frequency power to have a constant mixing ratio and flow to the surface of the wafer 202. In this case, when the TEOS gas and the oxygen gas are not mixed in a uniform mixing ratio, spark discharge may occur as in the prior art, which may cause an initial deposition process defect of the thin film formed on the wafer 202, but According to the present invention, since the TEOS gas and the oxygen gas are mixed to have a uniform mixing ratio within the process chamber 200 during the stabilization time, it is possible to prevent the spark discharge by the subsequent plasma reaction. In addition, the chemical vapor deposition method of the present invention prevents the thin film deposited on the wafer 202 by the spark discharge irregularly formed, the TEOS gas unreacted with the oxygen gas is It can prevent the initial deposition failure caused by condensation on the surface.

For example, the plasma electrode 206 is about 300 W while the TEOS gas and the oxygen gas are uniformly mixed with a mixing ratio of about 1:22 and supplied to the process chamber 200 for about 10 seconds to about 30 seconds. To about 600W high frequency power may be applied to induce a plasma reaction. The temperature inside the process chamber 200 is about 400 ° C., and the wafer 202 is also heated by the heater so as to have the same or similar temperature as that of the process chamber 200. Similarly, the interior of the process chamber 200 is pumped by the vacuum pump 304 to have a constant vacuum pressure of about 2.5 Torr.

Therefore, in the chemical vapor deposition method according to the present invention, after supplying oxygen gas and TEOS gas to the process chamber 200 from the source gas supply unit 100 for a predetermined stabilization time, a plasma reaction is induced on the wafer 202. The plasma reaction is induced in a state where the flowing oxygen gas and the TEOS gas are sufficiently uniformly mixed, and the thin film deposited on the wafer 202 is prevented from being irregularly formed by the spark discharge, and the oxygen gas and Since the unreacted TEOS gas can prevent an initial deposition failure caused by condensation on the surface of the wafer 202, it is possible to increase or maximize production yield.

Thereafter, when the thin film is formed to have a predetermined thickness on the wafer 202, the supply of the TEOS gas and the oxygen gas supplied into the process chamber 200 is stopped, and the plasma reaction is stopped sequentially. (S500). In addition, the TEOS gas and the oxygen gas remaining in the process chamber 200 are pumped and exhausted (S500). For example, air such as the oxygen gas and the TEOS gas inside the chamber is pumped for about 10 seconds. At this time, the chamber is pumped to have a vacuum degree of about 0 Torr or less.

Next, a purge gas is supplied into the process chamber 200 (S600). Here, the purge gas is supplied into the process chamber 200 through a supply line 102 connected between the source gas supply unit and the process chamber 200, and the purge gas remains in the process chamber 200. It is possible to dilute the TEOS gas and the oxygen gas. For example, nitrogen gas is mainly used for the purge gas, and the polymer component and the silicon oxide film formed on the inner wall of the process chamber 200 are supplied for about 20 seconds at a small flow rate such that the purge gas does not fall by the flow of the purge gas. At this time, the purge gas supplied into the chamber may be flowed over a plurality of intervals about 10 seconds, the chamber is pumped to have a degree of vacuum of about 2.5 Torr.

Then, the air containing the purge gas in the process chamber 200 is pumped to create a predetermined vacuum state (S700). At this time, the supply and pumping of the purge gas may be continuously performed plural times.

Although not shown, a door between the process chamber 200 and the transfer chamber is opened, and a robot installed in the transfer chamber opens the wafer 202 located on the chuck 204 inside the process chamber 200. Unloading into the transfer chamber completes chemical vapor deposition.

The foregoing has outlined rather broadly the features and technical advantages of the present invention to better understand the claims of the invention which will be described later. Additional features and advantages that make up the claims of the present invention will be described below. It should be appreciated by those skilled in the art that the conception and specific embodiment of the invention disclosed can be used immediately as a basis for designing or modifying other structures for carrying out similar purposes to the invention.

In addition, the inventive concepts and embodiments disclosed herein may be used by those skilled in the art as a basis for modifying or designing other structures for carrying out the same purposes of the present invention. In addition, such modifications or altered equivalent structures by those skilled in the art may be variously changed, substituted, and changed without departing from the spirit or scope of the invention described in the claims.

As described above, according to the present invention, the source gas supply unit supplies oxygen gas and TEOS gas to the process chamber for a predetermined stabilization time so that the thin film is formed while the vacuum degree of the process chamber is stabilized. Since it is possible to prevent the failure of the initial deposition process of the has the effect of increasing or maximizing the production yield.

In addition, after the oxygen gas and the TEOS gas is supplied to the process chamber from the source gas supply for a predetermined stabilization time, the plasma reaction is induced in a state where the oxygen gas and the TEOS gas flowing on the wafer are sufficiently uniformly mixed. To prevent the thin film deposited on the wafer by the flame discharge from being irregularly formed, and to prevent the initial deposition failure caused by condensation of the oxygen gas and the unreacted TEOS gas on the surface of the wafer. As a result, production yield can be increased or maximized.

Claims (7)

Supplying a first source gas at a predetermined flow rate into the chamber from a source gas supply unit; Bypassing a second source gas through a dump line connected to an exhaust part for pumping and exhausting air in the chamber from the source gas supply part; Pumping air inside the chamber while supplying the first source gas and the second source gas to the chamber to stabilize the inside of the chamber to have a predetermined degree of vacuum; And And applying a high frequency power to the first source gas and the second source gas supplied to the chamber to induce a plasma reaction to form a predetermined thin film on a wafer located inside the chamber. Vapor deposition method. The method of claim 1, The chemical vapor deposition method of claim 1, wherein the first source gas and the second source gas are supplied to the chamber to stabilize the degree of vacuum in the chamber. The method of claim 1, Wherein the first source gas is an oxygen gas and the second gas is a TEOS gas. The method of claim 3, wherein And wherein the TEOS gas bypasses the dump line for about 15 seconds. The method of claim 3, wherein And pumping air in the chamber to have a vacuum degree of 2.5 Torr while the first oxygen gas and the first TEOS gas are supplied to the chamber. The method of claim 3, wherein The oxygen gas has a flow rate of 8000 SCCM, the TEOS gas is supplied to the chamber to have a flow rate of 350 SCCM chemical vapor deposition method. The method of claim 3, wherein The plasma reaction method is formed by applying a RF power of about 300W to about 600W.

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