WO2003016590A2 - Device for supplying gas mixtures to a cvd reactor - Google Patents

Abstract

The invention relates to a device comprising a supply line branch (Z1) for a gas mixture consisting of an atomized medium (M1) and a carrier gas (T) to a CVD reactor (R). The supply line branch (Z1) comprises a supply line for the liquid medium (M1), a supply line for the carrier gas (T) and a processing unit which is fed by the supply lines and is used to convert the liquid medium (M1) into a gaseous state using an injector valve (EV1) and to mix the medium (M1) with the carrier gas (T). The supply lines are respectively provided with a through flow control unit (DS11, DS12)

Description

description

Device for supplying gas mixtures to a CVD reactor

The invention relates to a device by means of which gas mixtures with CVD media contained therein can be fed to a CVD reactor.

In the manufacture of semiconductor components, thin layers are produced on substrates using CVD (Chemical Vapor Deposition) systems. This is done in a CVD reactor by controlled separation of CVD media from the gas phase.

The CVD media are usually initially in liquid form and must therefore be converted to the gas phase before the gas phase separation. Two common methods are available for converting liquid CVD media into the gas phase. In a first method, a carrier gas is pumped through a container which is filled with the liquid CVD medium. During this process, part of the CVD medium passes into the gas phase through evaporation and mixes with the carrier gas atmosphere. A second method is based on the atomization of the liquid CVD medium. For this purpose, the liquid CVD medium is injected into a by means of an injection valve

Sprayed small chamber enriched carrier gas, so that a gaseous state of the CVD medium and mixing with the carrier gas are also achieved. Chemically inert gases such as e.g. Helium. This eliminates undesired reactions of the carrier gas with the CVD medium.

PCT patent application WO 00/15881 describes a CVD system which is based on the principle of evaporation of liquid CVD media. For this purpose, there is a liquid CVD medium in a container. The container has a feed line for a carrier gas which is inserted into the container with a adjustable flow is initiated. When the carrier gas flows through the container filled with the liquid CVD medium, the CVD medium is converted into the gas phase by evaporation and, together with the carrier gas, is fed via feed lines into a CVD reactor in which a controlled separation of the CVD medium from the Gas phase takes place on a substrate surface.

A disadvantage of previous CVD systems is that the gaseous CVD media partially already condense in the feed lines to the CVD reactor and possibly on the injection valves. Deposits in the feed lines caused thereby cause reduced and undefined cross-sectional areas of the feed lines, which makes a controlled supply of the gas mixtures to the CVD reactor considerably more difficult. Ultimately, the supply lines can even be completely closed. Deposits on the injection valves lead to malfunction or failure of the injection valves due to the high reactivity of the CVD media. Due to such degradations, the injection valves have to be replaced frequently. Otherwise, if the injection valves remained in the CVD system for too long, there was a risk that the function of the injector valves, which were impaired in their function, would get liquid CVD media into the CVD reactor and heavily contaminate it.

The object of the invention is therefore to provide a device for a CVD system and to specify a corresponding method by means of which reduced deposits of CVD media are brought about in the feed lines to the CVD reactor and, if appropriate, on the injection valves. It is in particular a further object of the invention that undesired mixing of the CVD media can be prevented.

The problem underlying the invention is characterized by the features of claims 1, 10, 18 and 22 solves. Advantageous further developments and refinements are specified in the subclaims.

A device according to the invention for supplying gases to a CVD reactor has at least one feed branch through which a gas mixture is fed to the CVD reactor. The gas mixture is generated by atomizing a liquid CVD medium in a carrier gas. The at least one feed branch comprises a first feed line for the liquid CVD medium, a second feed line for the carrier gas and a treatment unit. The processing unit is used to transfer the liquid CVD medium into the gas phase by means of an injection valve and to mix the CVD medium with the carrier gas. For this purpose, the processing unit is supplied on the input side with the liquid CVD medium through the first feed line and with the carrier gas through the second feed line. An essential idea of the invention is that the first feed line has a first flow control unit and the second feed line has a second flow control unit.

In the present patent application, a flow can be understood as an amount or a volume that flows through a surface perpendicular to the flow per unit of time. As a rule, the flow of the liquid CVD medium is given in the unit mg / min and the flow of the carrier gas in the unit sccm (sccm: standard cm ³ / min).

A major advantage of the device according to the invention lies in the controllability of the flow of the liquid CVD

Medium through the first feed line and the flow of the carrier gas through the second feed line. The processing unit can be supplied with the CVD medium and the carrier gas with individually set flows. The flow control of the liquid CVD medium can also indirectly control the rate at which the liquid CVD medium is atomized in the processing unit. In dependence of The chemical compositions and the physical properties of the CVD medium and the carrier gas allow their mixture concentrations to be optimized by the device according to the invention such that on the one hand the CVD medium completely changes into the gas phase and on the other hand condensations of the CVD medium in the feed lines to the CVD Reactor and at the injector are minimized. This measure extends the service life of the supply lines and the injection valve considerably.

If the device according to the invention has a plurality of feed branches and thus a plurality of processing units, the inflows to each processing unit can be set independently of the inflows to the other processing units. Furthermore, the presence of several supply branches for one CVD medium each ensures that different CVD media do not mix undesirably.

The flow of the CVD medium and the flow of the carrier gas can advantageously be controlled independently of one another. Independent controls of this type make it possible, for example, to set the desired operating conditions of an associated CVD system either via the first flow control unit or via the second flow control unit. The reason for this is that in the device according to the invention which works on the atomization principle, both a change in the flow of the liquid CVD medium and a change in the flow of the carrier gas change the concentration ratio which exists in the treatment unit between the CVD medium and the carrier gas , directly influenced.

So that the inflows of the CVD medium and the carrier gas to the processing unit can be kept at predetermined values, it is particularly advantageous to include a flow control arrangement in the device according to the invention integrate. The flow control arrangement includes, for example, measuring devices for measuring the flows through the first and the second feed line, the two flow control units described above and a control unit which regulates the flows through the two feed lines to predetermined and adjustable values. It can also be provided that the regulation takes place only in one of the two feed lines.

Furthermore, it is advantageous to connect a liquid sensor downstream of the processing unit. The liquid sensor can be used to determine whether the atomization of the CVD medium in the processing unit is optimal. For example, it can also be provided that the flow control arrangement is fed with the measured values supplied by the liquid sensor. In this case, the liquid sensor would take over the function of the above-mentioned measuring device in the flow control.

According to advantageous refinements of the invention, shut-off valves are arranged on the inflow and outflow sides of the first flow control unit. Likewise, further shut-off valves can advantageously be provided on the upstream and downstream sides of the second flow control unit. On the one hand, these measures are particularly advantageous when replacing a flow control unit. Due to the shut-off valves, the two flow control units can be decoupled from the supply lines and removed from the supply lines without the vacuum in the supply lines being impaired thereby. On the other hand, these measures are advantageous if a certain CVD medium is not required during the operation of the associated CVD system. In this case, the inflow of the relevant CVD medium and the carrier gas to the associated feed branch can be closed, thereby reducing signs of wear that are caused by the presence of the CVD medium in the feed lines. A particularly preferred embodiment of the invention is characterized in that in the case of a plurality of feed branches, these are combined on the output side to form a common feed line which feeds the CVD reactor through a gas inlet. This reduces the number of gas inlets on the CVD reactor, which means that the likelihood of a leak in the vacuum seal of the CVD reactor is also reduced.

A method according to the invention relates to the supply of at least one gas mixture to a CVD reactor. The at least one gas mixture is generated by atomizing a liquid CVD medium in a carrier gas. For this purpose, the initially liquid CVD medium is converted into the gas phase in a treatment unit by an injection valve and mixed there with the carrier gas. An essential idea of the invention is that the inflows of the liquid CVD medium and the carrier gas to the processing unit are controlled.

The advantage of the method according to the invention is that by controlling the inflows of the CVD medium and the carrier gas to the processing unit, an optimal mixing of the two gases in the processing unit is made possible. As a result, the efforts of the gaseous CVD medium for condensation are kept as low as possible, so that deposits of the CVD medium in the supply lines and on the injection valve and thereby impaired operation of the associated CVD system are minimized.

Another aspect of the invention relates to a device for supplying gases to a CVD reactor, which has supply lines for CVD media and / or gases to the CVD reactor and a cleaning arrangement for pumping liquid residues out of the supply lines. The cleaning arrangement can be coupled to the feed lines via valves. During the cleaning process, gases that remove the liquid residues hold, not pumped through the CVD reactor. Furthermore, the cleaning arrangement and the CVD reactor have a common pump.

This device allows both those liquid residues that are left in the feed lines for the liquid CVD media after the operation of the CVD system to be pumped out, as well as those liquid residues that result from condensation of the gaseous CVD media in the feed lines for the gas mixtures to the CVD reactor. Such cleaning measures reduce deposits of CVD media in the feed lines to the CVD reactor. An advantage of the present device is that the gases produced during the pumping out are not pumped through the CVD reactor. This prevents the gaseous residues of the CVD media from contaminating the CVD reactor. Another advantage lies in the joint use of a pump both for cleaning the supply lines and for creating a vacuum in the CVD reactor. This reduces the number of pumps required to a minimum.

The device according to the invention advantageously has a bypass line which connects the feed lines to the pump. The bypass line enables the gases to be pumped out without them crossing the CVD reactor. The

Bypass line therefore represents a simple way of realizing the cleaning arrangement.

A further advantageous embodiment of the invention provides that the bypass line has a check valve and / or a shut-off valve and / or a filter. The check valve prevents air from entering the CVD system through the bypass line in the event of a sudden vacuum leak on the pump. The shut-off valve is open while the supply lines are being cleaned and closed during normal operation of the CVD system. The filter prevents residues of CVD media in liquid form from getting into the pump and damaging it.

In order to be able to decouple the CVD reactor from the pump before cleaning the supply lines, a further shut-off valve can advantageously be arranged between the CVD reactor and the pump. This prevents the penetration of CVD media into the CVD reactor and the resulting contamination of the CVD reactor during the cleaning operation.

In a method according to the invention for cleaning supply lines for CVD media and / or gases to a CVD reactor, liquid residues are pumped out of the supply lines. For this purpose a pump is used, which is also used as a vacuum pump of the CVD reactor. Furthermore, gases which contain the liquid residues are not pumped through the CVD reactor during the cleaning of the feed lines.

The process according to the invention has the advantage that when cleaning the feed lines, the gases which carry the remaining residues of the CVD media out of the feed lines are not pumped through the CVD reactor. This prevents the CVD reactor from being contaminated by these gases. Another advantage is the use of the pump for vacuum generation in the CVD reactor as well as for cleaning the supply lines. This saves additional pumps that are only used for cleaning the supply lines.

The invention is described below in an exemplary manner

Reference to the drawing explained in more detail. The single figure shows a schematic arrangement of an exemplary embodiment of the device according to the invention for supplying gases to a CVD reactor.

The figure shows a CVD reactor R, which is fed through a gas inlet with CVD media M1, M2 and M3. The CVD Media are in the liquid state beforehand and must therefore first be converted into the gas phase. This is done in supply branches ZI, Z2 and Z3. Since the feed branches ZI, Z2 and Z3 correspond in their structure and function, only the feed branch ZI is described below. The structure and function of the feed branches Z2 and Z3 result from this in an analogous manner.

The CVD medium M1 is supplied to the feed branch ZI in the liquid state. After passing through a 3-way valve 3WV11, a shut-off valve AV11 and a 3-way valve 3WV12, the liquid CVD medium Ml flows through a flow control unit DSU and reaches an injection valve EVl via a shut-off valve AV14. The feed branch ZI also has a feed line for a carrier gas T. The carrier gas T first passes through a filter F2 and is then fed to the feed branches ZI, Z2 and Z3. In the feed branch ZI, the carrier gas T successively passes through a shut-off valve AV12, a flow control unit DS12 and a shut-off valve AV13. The liquid CVD medium Ml is then injected into the carrier gas T within a small chamber through the injection valve EV1, as a result of which the CVD medium Ml changes into the gas phase and mixes with the carrier gas T. A liquid sensor FS1 downstream of the injection valve EV1 serves to determine the liquid content of the gas mixture consisting of the CVD medium M1 and the carrier gas T. After flowing through a shut-off valve AV15, the gas mixtures generated in the feed branches ZI, Z2 and Z3 are combined to form a common feed line and fed into the CVD reactor R via a shut-off valve AV2 and a filter F3.

It is also possible to have a regulatory arrangement. to implement in the present arrangement. For example, the flow control units DSU and DS12 can include a control loop. The flows are measured by the flow control units DSU and DS12 and then for example, controlled by means of controllable valves within the flow control units DSU and DS12 to predetermined values. Furthermore, it is also conceivable that the flows through the flow control units DSU and DS12 are not measured for the control arrangement, but that the liquid sensor FS1 serves as a measuring device of the control arrangement. If the gas mixture produced is too high, the flow of the carrier gas T can be increased, for example, or the flow of the medium Ml can be reduced.

The shut-off valves AV12 and AV13 are required when replacing the flow control unit DS12. The flow control unit DS12 can be decoupled from the supply lines and replaced by the shut-off valves AV12 and AV13.

The same applies to the shut-off valves AV11 and AV14 and the flow control unit DSU. With the help of the shut-off valve AVI5, the feed branch ZI can be decoupled from the CVD reactor R. Furthermore, all feed branches ZI, Z2 and Z3 can be decoupled from the CVD reactor R by the shut-off valve AV2. The filter F3 prevents contaminants from entering the CVD reactor R.

A bypass line BL is provided for cleaning the lines of the present arrangement. The bypass line BL is connected at one end to the line branches ZI, Z2 and Z3 via the 3-way valves 3WV11, 3WV21 and 3WV31. At its other end, the bypass line BL is connected to a pump P via a check valve RV5, a shutoff valve AV3 and a filter F4. If the respective valves have the corresponding positions, residues of all types, in particular liquid residues of the CVD media M1, M2 and M3, can be pumped through the bypass line BL from the feed branches ZI, Z2 and Z3. The vacuum in the CVD reactor R and the feed branches ZI, Z2 and Z3 is also generated by the pump P. During the cleaning of the feed branches ZI, Z2 and Z3, the CVD reactor R is separated from the pump P and the bypass line BL by a shutoff valve AV4. In normal operation, the shutoff valve AV4 is open and the shutoff valve AV3 is closed, so that the bypass line BL is decoupled from the pump P.

In addition, the feed branches ZI, Z2 and Z3 can be flushed with nitrogen N for cleaning purposes. For this purpose, the nitrogen N is flushed through a check valve RV1 and the 3-way valve 3WV12 through the feed branch ZI. The same applies to the feed branches Z2 and Z3.

Furthermore, the nitrogen N can also be used to purge the CVD reactor R. For this purpose, the common feed of the feed branches ZI, Z2 and Z3 can be fed with nitrogen N. The nitrogen N is fed to the common feed line to the CVD reactor R via a filter F1, a shut-off valve AVI, a needle valve NV and a check valve RV4. This nitrogen supply can also be used to purge the feed branches ZI, Z2 and Z3 via their outputs.

Claims

claims

1. Device for supplying gases to a CVD reactor (R), with at least one feed branch (ZI, Z2, Z3) for a gas mixture, which by atomizing a CVD medium (Ml, M2, M3) in a carrier gas (T ) is generated, the at least one supply branch (ZI, Z2, Z3) a first supply line for the liquid CVD medium (M1, M2, M3), a second supply line for the carrier gas (T) and one of the first and the second Supply line fed treatment unit, which converts the liquid CVD medium (Ml, M2, M3) into the gaseous state by means of an injection valve (EVl, EV2, EV3) and mixes with the carrier gas (T), the first supply line having a first flow control unit ( DSU, DS21, DS31) and the second feed line have a second flow control unit (DS12, DS22, DS32).

2. Device according to claim 1, characterized in that - the two flow control units (DSU, DS21, DS31, DS12, DS22, DS32) an independent control of the flow of the CVD medium (Ml, M2, M3) and the flow of the carrier gas (T ) enable.

3. Device according to claim 1 or 2, g e k e n n z e i c h n e t d u r c h

- A flow control arrangement which enables the carrier gas and / or the CVD medium flow to be controlled using the first and / or the second flow control unit (DSU, DS21, DS31, DS12, DS22, DS32).

4. The device as claimed in one or more of the preceding claims, wherein the device is used,

- that the processing unit is followed by a liquid sensor (FS1, FS2, F3) with whose measured values if necessary, in particular the flow control arrangement is fed.

5. Device according to one or more of the preceding claims, g e k e n n z e i c h n e t d u r c h

- A first shut-off valve (AV11, AV21, AV31), which is arranged in the first feed line upstream of the first flow control unit (DSU, DS21, DS31), and / or a second shut-off valve (AV12, AV22, AV32), which is in the second feed line is arranged upstream of the second flow control unit (DS12, DS22, DS32).

6. Device according to one or more of the preceding claims, g e k e n n z e i c h n e t d u r c h

- A third shut-off valve (AV14, AV24, AV34), which is arranged in the first feed line downstream of the first flow control unit (DSU, DS21, DS31), and / or a fourth shut-off valve (AV13, AV23, AV33), which in the second feed line is arranged downstream of the second flow control unit (DS12, DS22, DS32).

7. Device according to one or more of the preceding claims, g e k e n n z e i c h n e t d u r c h

- A fifth shut-off valve (AV15, AV25, AV35), which is arranged downstream of the treatment unit.

8. The device according to one or more of the preceding claims, characterized du rch - a plurality of feed branches (ZI, Z2, Z3) which open on the output side into a common feed line which is connected to a gas inlet of the CVD reactor (R) ,

9. The device according to claim 8, d a d u r c h g e k e n n z e i c h n e t,

- That the common supply line has a sixth shut-off valve (AV2).

10. Method for supplying at least one gas mixture, which is generated by atomizing a CVD medium (M1, M2, M3) in a carrier gas (T), to a CVD reactor (R), the initially liquid CVD medium ( Ml, M2, M3) is converted into the gaseous state in a processing unit by means of an injection valve (EVl, EV2, EV3) and mixed with the carrier gas (T), and the inflow of the liquid CVD medium (Ml, M2, M3 ) and the inflow of the carrier gas (T) to the processing unit can be controlled.

11. The method according to claim 10, d a d u r c h g e k e n n z e i c h n e t,

- That the inflow of the liquid CVD medium (Ml, M2, M3) and the inflow of the carrier gas (T) to the processing unit are controlled independently.

12. The method of claim 10 or 11, d a d u r c h g e k e n e z e i c h n e t, - that the inflow of the liquid CVD medium (Ml, M2, M3) and / or the inflow of the carrier gas (T) to the processing unit are regulated.

13. The method according to claim one or more of claims 10 to 12, d a d u r c h g e k e n n z e i c h n e t,

- That the liquid portion of the at least one gas mixture is examined, and possibly in particular the regulation of the inflow of the liquid CVD medium (Ml, M2, M3) and / or the regulation of the inflow of the carrier gas

(T) depending on the test result.

14. The method according to one or more of claims 10 to

13, d a d u r c h g e k e n n z e i c h n e t,

- That the inflow of the CVD medium (M1, M2, M3) to the treatment unit is controlled by a first shut-off valve (AV14, AV24, AV34) and / or the inflow of the carrier gas (T) to the treatment unit by a second shut-off valve (AV13, AV23, AV33) is controlled.

15. The method according to one or more of claims 10 to 14, d a d u r c h g e k e n n z e i c h n e t,

- That the outflow of the at least one gas mixture from the processing unit through a third shut-off valve

(AV15, AV25, AV35) is controlled.

16. The method according to one or more of claims 10 to 15, g e k e n n z e i c h n e t d u r c h

- A plurality of gas mixtures, which is fed to the CVD reactor (R) via a common feed line.

17. The method according to claim 16, d a d u r c h g e k e n n z e i c h n e t,

- That the inflow of the gas mixtures to the CVD reactor (R) is controlled by a fourth shut-off valve (AV2).

18. Device for supplying gases to a CVD reactor (R), with

- Supply lines for CVD media (M1, M2, M3) and / or gases to the CVD reactor (R), and

a cleaning arrangement for pumping liquid residues out of the feed lines, the cleaning arrangement being able to be coupled to the feed lines via valves (3WV11, 3WV21, 3WV31), - The cleaning arrangement and the CVD reactor (R) have a common pump (P), and

- The cleaning arrangement is designed in such a way that gases which are pumped out during the cleaning and contain the liquid residues are pumped past the CVD reactor (R).

19. The apparatus of claim 18, g e k e n n z e i c h n e t d u r c h - a bypass line (BL) which connects the feed lines to the pump (P).

20. The apparatus of claim 19, d a d u r c h g e k e n n z e i c h n e t - that the bypass line (BL) has a check valve (RV5) and / or a first shut-off valve (AV3) and / or a filter (F4).

21. The device according to one or more of claims 18 to 20, g e k e n n z e i c h n e t du r c h

- A second shut-off valve (AV4), which is arranged between the CVD reactor (R) and the pump (P).

22. Processes for cleaning supply lines for CVD media

(Ml, M2, M3) and / or gases to a CVD reactor (R), in which liquid residues are pumped out of the feed lines, whereby

- A pump (P) common to the CVD reactor (R) is used for cleaning the supply lines, and

- Gases containing the liquid residues are pumped past the CVD reactor (R) during the cleaning of the supply lines.

23. The method according to claim 22, characterized in - That the supply lines are connected to the pump (P) by a bypass line (BL).

24. The method according to claim 23, d a d u r c h g e k e n n z e i c h n e t,

- That the bypass line (BL) has a check valve (RV5) and / or a first shut-off valve (AV3) and / or a filter (F4).

25. The method according to one or more of claims 22 to 24, that a c r g e k e n n z e i c hn e t,

- That the CVD reactor (R) is decoupled from the pump (P) by a second shut-off valve (AV4) before cleaning the supply lines.