JP2004140320A - Chemical vapor deposition apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a chemical vapor deposition apparatus capable of forming a film while suppressing variations of the thickness of a thin film formed on a wafer surface. <P>SOLUTION: The chemical vapor deposition apparatus comprises an external container pipe 5 having one end closed (the upper part), an inner container pipe 4 serving as a reaction chamber 9 installed in the external container pipe 5, a support jig 2, called a boat, accommodated in the inner container pipe 4, and an electric furnace 7 accommodating the external container pipe 5 and including a heater 6 for heating a wafer 1 set on the support jig 2. A plurality of exhaust openings 3 are provided in the inner wall of the internal container pipe 4. Through the exhaust opening 3 radical gas is exhausted to form a thin film with reduced variations of its thickness on the wafer 1. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a chemical vapor deposition apparatus for forming a thin film on a surface of a substrate.
[0002]
[Prior art]
A semiconductor device is formed by stacking various thin films such as a polycrystalline silicon film, a metal film, and an insulating film on a semiconductor substrate, and a chemical vapor deposition method is often used as a film forming method.
FIGS. 10A and 10B are main part configuration diagrams of a conventional batch type chemical vapor deposition apparatus. FIG. 10A is an overall view, and FIG. 10B is a perspective view of a support jig (boat) on which a wafer is set. FIG.
The chemical vapor deposition apparatus (CVD apparatus: Chemical Vapor Deposition apparatus) includes an outer container tube 5 having one end (upper part) closed, and an inside which is installed in the outer container tube 5 and has a reaction chamber 9 inside. A container 6, a supporting jig 2 called a boat accommodated in the inner container 4, and a heater 6 accommodating the outer container 5 and heating the wafer 1 (substrate) set in the supporting jig 2. And the like. The support jig 2 includes a support 24, a plurality of columns 25 arranged so that the wafer 1 can be set on the support 24 from the direction of arrow H, and a support plate 26 that supports these columns 25 in the middle. It consists of.
[0003]
A large number of wafers 1 are arranged on the support jig 2 in a row at a narrow interval. The support jig 2 is inserted into the inner container tube 4, and the opening 8 (lower portion) of the outer container tube 5 is covered with a lid 8. Then, the inside of the outer container tube 5 is brought into a reduced pressure atmosphere, and a reactive gas and a carrier gas are introduced into the inner container tube 4 (reaction chamber 9) from the gas inlet 10 provided at the lower portion, and the upper portion is introduced into the upper portion. These flowing gas flows 12 are sucked and exhausted from a gas exhaust port 11 by a vacuum pump (not shown) through a gap sandwiched between a wall surface of the inner container tube 4 and a wall surface of the outer container tube 5.
In FIG. 10, since the gas flow 12 flows from below to above, the lower part becomes the source flow area 21, the upper part becomes the downstream area 23, and the middle part becomes the middle flow area 22.
[0004]
This film forming method is an excellent method capable of growing a thin film on the order of nanometers at a relatively low temperature with good controllability. For example, a polycrystalline silicon film (polysilicon film) applied as a material for a gate electrode of a MOS transistor is formed by using monosilane (SiH) in an atmosphere at a furnace temperature of 550 ° C. and a degree of vacuum of 100 Pa.₄) 1000 sccm gas and nitrogen (N₂) When the gas is injected together with 200 sccm, the gas is deposited on the wafer 1 at a film forming rate of about 30 ° / min.
Under the above-described film forming speed, a single-wafer type apparatus (not shown) that processes one sheet at a time has excellent uniformity of the film thickness on the wafer 1 but cannot increase the productivity. A batch-type apparatus capable of performing batch processing for simultaneously processing the wafers 1 at a time is used. In this batch processing, in order to arrange a large number of wafers 1 in a region with good temperature uniformity, the wafers 1 are sequentially arranged in parallel at as small an interval as possible, and a reactive gas and a carrier gas are caused to flow around the periphery thereof. Take.
[0005]
In such a configuration, a chemical vapor deposition apparatus in which the film thickness distribution is improved is disclosed in, for example, Patent Document 1. As shown in FIG. 11, an inner tube 15 having a large number of holes is provided inside the inner container tube 4 of the chemical vapor deposition apparatus shown in FIG. The gas flow is supplied between the plurality of openings of the inner end pipe 15 and diffused into the space between the wafers (Patent Document 1).
[0006]
[Patent Document 1]
JP-A-3-22522
[0007]
[Problems to be solved by the invention]
However, in these configurations, the reactive gas flows from the source flow area 21 to the downstream area 23 while being in contact with the high-temperature atmosphere. It mixes a little. This reactive species is a reactive species (radical reactive species) having a very high reactivity. Since the reactive species touches the wafer 1 and is deposited as a polysilicon thin film, the uniformity of the film thickness on the wafer 1 is not sufficient. Problems arise.
FIG. 12 is a model diagram showing a state inside the inner container tube of the chemical vapor deposition apparatus shown in FIG. The mechanism by which the film thickness becomes non-uniform will be described using this model diagram.
[0008]
In the case of polysilicon film formation, the reactive gas is 100% SiH₄Gas, carrier gas N₂Injected together with the gas from the lower part of the inner vessel tube 4 which is the reaction chamber 9. In the reaction chamber 9, a uniform temperature of 550 ° C. is maintained over the wafer installation area, and the uniform temperature area has a length of about 800 mm in a batch apparatus of 150 sheets. SiH injected from the lower part of the reaction chamber 9₄The gas 13 is subjected to heat radiation and collision of gas molecules in this long high temperature region, and a part of the gas 13 is SiH according to the following reaction formula.₂It changes to gas 14.
SiH₄→ SiH₂+ H₂
Where SiH₂The gas 14 is called a radical gas, is extremely reactive, and is decomposed and deposited as a silicon film only by hitting the surface of the wafer 1. That is, SiH₂Is a radical reactive species.
[0009]
That is, SiH₂SiH of gas 14₄As the relative concentration with respect to the gas 13 increases, the SiH₂The deposition of polysilicon from the gas 14 becomes active, and the film thickness at that portion increases, and as a result, the film thickness on the surface of the wafer 1 becomes uneven.
In fact, SiH₂SiH₄The relative concentration (concentration ratio) with respect to is 1 × 10^-7On the other hand, for the wafer in the midstream region 22, 3 × 10^-7About 7 × 10 for the wafer in the downstream region 23^-7Degree and increase. For this reason, the variation in the film thickness in the downstream region 23 is larger than that in the source region 21. That is, the non-uniformity of the film thickness in the wafer surface is caused by the SiH generated by the thermal energy.₂It depends on the amount of gas 14.
[0010]
FIG. 13 is a diagram showing the relationship between the wafer position and the film thickness. A total of 150 wafers 1 are set on the support jig 2, and the side into which the reactive gas flows is divided into the source flow area 21, the middle area into the middle flow area 22, and the side from which the reactive gas flows out into the downstream area 23. Then, 50 wafers are set in each area, and a polysilicon film is formed on the wafer 1. The narrow interval at this time is 8 mm. The thickness of the formed polysilicon film is measured in the X direction of FIG. 14 at 20 points on a straight line including the center of the wafer 1 (10 mm intervals between -40 mm and +40 mm, and 5 mm intervals outside thereof). I do. The measurement of the film thickness is performed on each of 50 wafers set in the three regions of the source flow region 21, the middle flow region 22, and the downstream region 23. Next, the average value of the film thickness at the same measurement point of the wafer 1 in each region (average value of 50 wafers) is obtained, and this average value is calculated as the average value of the film thickness at the center of the wafer 1 (average of 50 wafers). At each measurement point was shown as an average value of the normalized film thickness in each region (hereinafter, referred to as a normalized average film thickness value). In the figure, G is a head flow region, H is a middle flow region, and I is a normalized average film thickness value at each measurement point in an upstream region.
[0011]
As described above, in the downstream region 23, the ratio of the reactive species having high reactivity is higher, so that the variation in the normalized average film thickness value of the polysilicon film formed in the downstream region 23 is 1.5%. %, And the variation is as large as 0.8% even in the head flow region 21.
Such a thing can be said similarly in FIG.
The inconvenience in the case where the variation in the thickness of the thin film in the wafer surface becomes large as described above will be described using a polysilicon film as an example of the thin film.
FIG. 15 is a diagram for explaining inconvenience in the case of a trench groove. When a gate electrode such as a MOSFET of a trench gate is formed, a trench groove 53 covered with a gate insulating film 52 is formed by filling the polysilicon film 51 with a radical reactive species (SiH₂In the case of (ii), the trench groove 53 is closed at the upper portion, and a cavity 54 is formed inside the trench groove 53, which causes a problem that the gate resistance increases. Incidentally, 55 in the figure is a well region, and 56 is a source region.
[0012]
FIG. 16 is a diagram for explaining inconvenience in the case of a planar. If the thickness of the polysilicon film 61 serving as a gate electrode varies with a planar type vertical MOSFET (DMOS) or the like, a source region 63 is formed in the surface layer of the well region 62 using the polysilicon film 61 as a mask. In this case, at a thin portion (left side in the figure), there arises a problem that the ion implantation impurity 64 penetrates the polysilicon film 61 to dope the channel portion to change the threshold voltage.
As described above, if the thickness of the thin film such as the polysilicon film formed on the wafer 1 varies, the above-described inconvenience occurs in manufacturing the semiconductor device.
[0013]
An object of the present invention is to solve the above-mentioned problems and to provide a chemical vapor deposition apparatus capable of making the thickness of a thin film formed on a wafer surface uniform.
[0014]
[Means for Solving the Problems]
In order to achieve the above object, a heating furnace, an outer container tube housed in the heating furnace, one end of which is closed, an inner container tube housed in the outer container tube, and open at both ends, A support jig accommodated in the inner container tube and arranging a plurality of substrates in a row is provided, and a reactive gas flows between the wall surface of the inner container tube and the support jig where the substrate is arranged. In a chemical vapor deposition apparatus for forming a thin film on a substrate, an exhaust opening for exhausting a part of the reactive gas is provided on a wall surface of an inner container tube.
Alternatively, the inner container pipe may be formed in multiple layers, and may have an exhaust opening for exhausting a part of the reactive gas on at least a wall surface of the innermost inner container pipe.
[0015]
Further, it is assumed that the exhaust opening is formed symmetrically at the center of the inner container tube in the horizontal direction.
Further, it is assumed that the inner container pipe has a plurality of exhaust openings in which a wall surface is formed in a mesh shape.
Alternatively, the inner container tube is divided into a plurality of regions in the row direction of the substrate, and each inner container tube has an internal supply port and an internal exhaust port for the reactive gas.
The support jig is provided with a shielding plate, and the inside of the inner container tube is divided into a plurality of regions by the shielding plate.
[0016]
A reactive gas supply pipe for a reactive gas supplied to each of the plurality of regions of the inner container pipe is provided, and the distances of the reactive gas supply pipes from the outer container pipe to the inner container pipe are substantially equal. .
A reactive gas supply pipe for supplying the reactive gas to the inner container pipe, wherein the reactive gas supply pipe connects the outer container pipe from the outside of the heating furnace in a substantially horizontal direction to each region of the inner container pipe. Through the inner container tube.
Alternatively, a temperature adjusting means for adjusting the temperature of the reactive gas to about the same as the ambient temperature in the outer container tube is provided.
[0017]
Further, the inner diameter of the reactive gas supply pipe for supplying the reactive gas to the inner container pipe is set to 50 mm or less.
Here, the purpose of preliminarily raising the temperature of the reactive gas to about the same as the ambient temperature in the outer vessel tube is to divide the inner vessel pipe into a plurality of sections and shorten the reaction chamber. This is because, if supplied, the temperature distribution in the reaction chamber becomes large, and a distribution occurs in the growth rate of the thin film. In addition, the reason why the inner diameter of the reactive gas supply pipe is set to 50 mm or less is that when the reactive gas supply pipe is kept at a high temperature, radical reactive species are generated therein, and if it is left as it is, the variation in the thin film in the reaction chamber becomes large. turn into. Since the diffusion distance of the radical reactive species is 25 mm in the reaction temperature range, by setting the inner diameter of the reactive gas supply pipe to 50 mm or less, the reactive species generated in the reactive gas supply pipe can be reacted with the reactive gas. It can adhere to the inner wall of the supply pipe and be extinguished.
[0018]
As described above, in a batch type chemical vapor deposition apparatus, SiH generated by thermal energy in a space (a gas flow path) between a wall surface of an inner vessel tube serving as a reaction chamber of the apparatus and a substrate row.₂However, the uniformity of the thin film on the wafer 1 can be improved by reducing the probability of intrusion into the substrate surface.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 is a configuration diagram of a main part of a chemical vapor deposition apparatus according to a first embodiment of the present invention. In FIG. FIG. 2 is a perspective view of the inner container tube of FIG. This embodiment is an example in which the exhaust opening 3 is provided on the wall surface of the inner container tube 4 in which the inside becomes the reaction chamber 9, and is an example showing a case where a polysilicon film is deposited on the wafer 1.
The chemical vapor deposition apparatus includes an outer container tube 5 having one end (upper part) closed, an inner container tube 4 having an exhaust opening 3 serving as a reaction chamber 9 installed in the outer container tube 5, A support jig 2 (shown in FIG. 10B) called a boat accommodated in the container tube 4 and an external container tube 5 are accommodated, and the wafer 1 (substrate) set in the support jig 2 is heated. It comprises a heating furnace 7 having a heater 6 and the like. An exhaust opening 3 as shown in FIG. 2 is formed in the inner container tube 4, and a part of the reactive gas is exhausted from the exhaust opening 3. Since the above-mentioned radical reactive species increases toward the downstream region, it is necessary to exhaust a part of the reactive gas uniformly in the direction of the gas flow in order to form a film with less variation. . Therefore, the exhaust opening 3 is formed symmetrically with respect to the center of the inner container tube in the horizontal direction. Further, it is preferable to form a plurality of exhaust openings 3 having a predetermined interval in the horizontal direction. In this embodiment, eight exhaust openings are formed at equal intervals in the gas flow direction at intervals of 100 mm.
[0020]
The polysilicon film was formed under the same conditions as those shown in the prior art. A large number of wafers 1 are arranged in a row on the support jig 2, the support jig 2 is inserted into the inner container tube 4, the opening 8 (lower portion) of the outer container tube 5 is covered with a lid 8, and sealed. Then, the inside of the outer container tube 5 is set to a reduced pressure atmosphere, and the reactive gas SiH₄Gas and N as carrier gas₂The gas is introduced into the inner vessel tube 4 (reaction chamber 9) from the gas inlet 10 provided at the lower part, and the gas flow flowing from the upper part and the gas flow flowing from the exhaust opening 3 are converted into the inner vessel. The gas is sucked and exhausted from the gas exhaust port 11 by a vacuum pump (not shown) through a gap sandwiched between the wall surface of the pipe 4 and the wall surface of the outer container pipe 5. In the figure, since the gas flow flows from below to above, the lower part becomes the source flow area 21, the upper part becomes the downstream area 23, and the middle part becomes the middle flow area 22.
[0021]
FIG. 3 is a model diagram showing a state inside the inner vessel tube of the chemical vapor deposition apparatus shown in FIG. The gas flow 12 flows from the source flow side to the downstream side. The exhaust opening 3 is formed symmetrically with respect to the center of the inner container tube 5 in the horizontal direction. By providing the exhaust opening 3 in the inner container tube 5, SiH₄Part of the gas is exhausted, and at the same time, the radical reaction species generated by thermal energy in the space between the wall surface of the inner container tube and the substrate row (which becomes a gas flow path) is also exhausted. The probability of species invading the substrate gap can be reduced, and the₂By suppressing the increase in the concentration of the gas 14, the gas 13 can make the thickness of the polysilicon film in the wafer 1 uniform.
[0022]
Here, a polysilicon film is used as the thin film. However, in the case of a nitride film or an oxide film, as in the present invention, the probability of radical reactive species entering between opposing surfaces of adjacent substrates is reduced. Therefore, it is presumed that forming the exhaust opening 3 in the inner container tube 5 is effective.
FIG. 4 is a film thickness distribution when a polysilicon film is formed on a wafer using the chemical vapor deposition apparatus of FIG.
A total of 150 wafers 1 are set on the support jig 2, and the side into which the reactive gas flows is divided into the source flow area 21, the middle area into the middle flow area 22, and the side from which the reactive gas flows out into the downstream area 23. Then, 50 wafers 1 are set in each area, and a polysilicon film is formed on the wafer 1 as a thin film. As shown in FIG. 14, the thickness of the formed polysilicon film is measured at 20 points on a straight line including the center of the wafer 1 (at intervals of 10 mm between -40 mm and +40 mm, and at intervals of 5 mm outside thereof). .
[0023]
The measurement of the film thickness is performed on each of 50 wafers set in the three regions of the source flow region 21, the middle flow region 22, and the downstream region 23. Next, the average value of the film thickness at the same measurement point in each area is obtained, and the average value is divided by the average value of the film thickness at the center of the wafer 1 to obtain a standard value in each area at each measurement point. The average value of normalized film thickness (normalized average film thickness value) was shown. In the figure, A is a source flow region, B is a middle flow region, and C is a normalized average film thickness value at each measurement point in a downstream region.
Since radical reactive species are exhausted from the exhaust opening 3, the variation in the normalized average film thickness of the polysilicon film formed in the downstream region C is as small as 0.7%. Further, although not shown, the variation of the maximum value of the normalized film thickness (normalized maximum film thickness value) in the downstream region C is also about 1.4 times the variation of the normalized average film thickness value, and is 1%. And small variations.
[0024]
By providing the exhaust opening 3 in this manner, the thickness of the thin film can be suppressed to an in-plane variation of 1% or less, and the uniformity of device characteristics can be greatly extended.
FIG. 5 is a configuration diagram of a main part of a chemical vapor deposition apparatus according to a second embodiment of the present invention.
The difference from the first embodiment is that the inner container tube 4 is formed in two layers.
As in the first embodiment, an exhaust opening 3 is provided in the inner internal vessel tube, and radical reactive species are exhausted from the exhaust opening 3.
Since the number of radical reactive species generated in the apparatus increases toward the downstream region, it is desired to increase the exhaust capacity as the region reaches the downstream region. By forming the inner container pipe as a double pipe, forming an exhaust opening inside, and providing an exhaust port at the upper portion of the inner container pipe, it is possible to increase the exhaust capacity from the downstream region. In this embodiment, since the upper exhaust port is opposed to the outer container tube, it is possible to increase the exhaust ability of more radical reactive species. Here, the case where the inner container pipe is double is shown, but it is needless to say that the inner container pipe may be triple or more.
[0025]
FIG. 6 is an enlarged view of a main part of an inner container tube of a chemical vapor deposition apparatus according to a third embodiment of the present invention. The exhaust opening 3 is formed in a mesh shape. Even if the film is formed in a mesh shape as described above, a film with improved uniformity can be formed.
FIGS. 7A and 7B are schematic diagrams of a main part of a chemical vapor deposition apparatus according to a fourth embodiment of the present invention. FIG. 7A is an overall view, FIG. 7B is a perspective view of a support jig on which a wafer is set, The same parts as those in FIG. 10 are denoted by the same reference numerals.
This embodiment is an example in which the inner container tube 4 is divided into a plurality of regions 43, 44 and 45, and is an example showing a case where a polysilicon film is deposited on the wafer 1.
[0026]
The chemical vapor deposition apparatus includes an outer container tube 5 having one end (upper portion) closed, an inner container tube 4 serving as a reaction chamber 9 installed in the outer container tube 5, and a shielding plate 27. A heating jig 7 having a supporting jig 2 for separating the inner container tube 4 into three regions by a plate 27 and a heater 6 for housing the outer container tube 5 and heating the wafer 1 (substrate) set in the supporting jig 2. And a reactive gas supply pipe 16 having an inner diameter of 45 mm for supplying a reactive gas to each region of the inner container tube 4.
The internal container pipe 4 has an internal supply port 41 as a flow port for a reactive gas and an internal exhaust port 42 as a discharge port for exhaust gas in each region. The internal supply port 41 is connected to the reactive gas supply pipe 16, and the reactive gas supply pipe 16 is made of quartz and inserted into the through holes formed in the heating furnace 7, the external vessel pipe 5 and the internal vessel pipe 4, and The tube 5 and the inner container tube 4 are each fused.
[0027]
The support jig 2 includes a support 24, a support 25, and a shielding plate 27, and arranges the wafer 1 in a region divided by the shielding plate 27. The inner container tube 4 is divided into a plurality of parts by a shielding plate 27 provided on the support jig 2. Further, a thin film can be formed while rotating the support jig 2.
The respective regions 43, 44 and 45 of the inner container tube 4 are connected by a gap between the shielding plate 27 and the inner container tube 4 and are not completely separated from each other. It is possible to suppress the reactive gas from being exhausted from the internal exhaust port 42 and from being introduced into the adjacent region through the gap between the shielding plate 27 and the internal container pipe 4.
[0028]
The means for previously raising the temperature of the reactive gas to about the same as the ambient temperature in the outer vessel tube 5 may be any configuration that heats the reactive gas supply pipe 16, and in this embodiment, the heater 6 of the heating furnace 7 is Also serves as a means for raising the temperature of the reaction gas.
In forming the polysilicon film, the film was formed under the same conditions as those described in the related art.
A large number of wafers 1 are arranged in a row on the support jig 2, the support jig 2 is inserted into a region inside the inner container tube 4, and the opening (lower portion) of the outer container tube 5 is covered with a lid 8. Then, the container tube 5 is set in a reduced pressure atmosphere, and the reactive gas SiH₄Gas and N as carrier gas₂The gas is supplied from respective tanks (not shown), and the mixed reactive gas is introduced into the reactive gas supply pipe 16 and introduced into the respective regions 43, 44 and 45 of the inner container pipe 4. The gas flow flowing from the internal exhaust port 42 is sucked and exhausted from the gas exhaust port 11 by a vacuum pump (not shown) through a gap between the wall surface of the inner container pipe and the wall surface of the external positive air pipe 5. In the figure, the gas flow flows from below to above, so that in each of the regions 43, 44 and 45, the lower portion is the source flow region 21, the upper portion is the downstream region 23, and the middle is the middle flow region 22.
[0029]
With such a configuration, SiH generated by thermal energy in a space (a gas flow path) between the wall surface of the inner vessel tube 4 serving as the reaction chamber 9 and the substrate row is formed.₂By reducing the probability of intrusion into the surface of the substrate, the uniformity of the thickness of the thin film on the wafer 1 can be improved, and the in-plane variation of the thickness of the polysilicon film deposited on the wafer 1 can be improved. Can be improved to about の of the related art.
FIG. 8 shows a film thickness distribution when a polysilicon film is formed on the wafer 1 using the chemical vapor deposition apparatus of FIG.
A total of 180 wafers 1 are divided into three equal parts, and 60 wafers are set on the support jig 2 in each region of the inner container tube 4. In each of the regions 43, 44 and 45, the source gas flows from the side where the reactive gas flows. The region, the middle region is a middle flow region, and the side from which the reactive gas flows out is divided into three regions: a downstream region, and a polysilicon film is formed on the wafer 1 as a thin film. As shown in FIG. 14, the thickness of the formed polysilicon film is measured at 20 points on a straight line including the center of the wafer 1 (at intervals of 10 mm between -40 mm and +40 mm, and at intervals of 5 mm outside thereof). .
[0030]
The measurement of the film thickness was performed on each of 20 wafers set in three regions of the source flow region 21, the middle flow region 22, and the downstream region 23 of the region 45.
The average value of the film thickness at the same measurement point in each region is obtained, and the average value is divided by the average value of the film thickness at the center of the wafer 1 to obtain a normalized film thickness in each region at each measurement point. It was shown as the average value of the thickness (normalized average film thickness). In the figure, D is a source flow region, E is a middle flow region, and F is a normalized average film thickness value at each measurement point in a downstream region.
Since it is difficult for radical reactive species to enter the wafer 1, the variation in the normalized average thickness of the polysilicon film formed in the downstream region F is as small as 0.7%. Further, although not shown, the variation of the maximum value of the normalized film thickness (normalized maximum film thickness value) in the downstream region F is about 1.2 times as large as the variation of the normalized average film thickness value, which is 1%. And small variations.
[0031]
FIG. 9 is a configuration diagram of a main part of a chemical vapor deposition apparatus according to a fifth embodiment of the present invention. The same parts as those in FIG. 7 are denoted by the same reference numerals.
This embodiment is an example in which the inner container tube 4 is divided into a plurality of regions 43, 44 and 45 as in the fourth embodiment.
The difference from the fourth embodiment is that the reaction gas supply pipe 16 passes between the outer vessel pipe 5 and the inner vessel pipe 4 from below the outer vessel pipe 5 and enters the respective regions 43, 44 and 45 of the inner vessel pipe. It is a connected point.
Since the length of the reactive gas supply pipe 16 in the outer vessel tube 5 is longer than in the fourth embodiment, the amount of radical reactive species generated is larger than in the fourth embodiment. Since the flow rate of the reactive gas in the supply pipe 16 is high, the residence time of the reactive gas in the reactive gas supply pipe 16 is short, and the amount of radical reactive species generated is suppressed to a low level. By setting the inner diameter of the tube 16 to 50 mm or less, radical reactive species are also captured, so that the amount of radical reactive species generated can be suppressed lower than in the conventional technique as shown in FIG. Further, since the inner container tube 4 is divided into a plurality of regions, it is possible to form a thin film having less variation in film thickness as compared with the related art.
[0032]
In this embodiment, the wafer 1 is mounted on the thin plate 17 made of quartz or silicon carbide placed on the support jig 2. In this case, the thin plate 17 is formed in a substantially similar shape to the wafer 1, and the wafer 1 is loaded so that the centers of the thin plate 17 and the thin plate 17 coincide with each other, so that radical reactive species can be captured at the outer peripheral portion of the thin plate 17. Therefore, a thin film having less variation can be formed. Needless to say, a configuration in which the wafer 1 is directly disposed on the support jig 2 as in the fourth embodiment may be adopted. Conversely, in the other embodiments described above, the configuration may be such that the thin plate 17 is arranged.
[0033]
【The invention's effect】
According to the present invention, an exhaust opening for exhausting radical reactive species can be formed in the wall surface of the inner container tube that is a reaction chamber, or the inner container tube is divided into a plurality of regions, and the reactive gas is supplied to each inner container tube. The provision of the inlet and the outlet of the exhaust gas can improve the uniformity of the thickness of the thin film deposited on the substrate.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a main part of a chemical vapor deposition apparatus according to a first embodiment of the present invention.
FIG. 2 is a perspective view of an embodiment of the inner container tube of the present invention.
FIG. 3 is a model diagram showing a state in an inner container tube.
FIG. 4 is a diagram showing a film thickness distribution when a polysilicon film is formed on a wafer using the chemical vapor deposition apparatus of FIG. 1;
FIG. 5 is a configuration diagram of a main part of a chemical vapor deposition apparatus according to a second embodiment of the present invention.
FIG. 6 is an enlarged view of a main part of an inner container tube of a chemical vapor deposition apparatus according to a third embodiment of the present invention.
FIG. 7 is a main part configuration diagram of a chemical vapor deposition apparatus according to a fourth embodiment of the present invention.
8 is a film thickness distribution diagram when a polysilicon film is formed on a wafer using the chemical vapor deposition apparatus of FIG. 7;
FIG. 9 is a configuration diagram of a main part of a chemical vapor deposition apparatus according to a fifth embodiment of the present invention.
10A and 10B are main-part configuration diagrams of a conventional batch-type chemical vapor deposition apparatus, where FIG. 10A is an overall view and FIG. 10B is a perspective view of a support jig on which a wafer is set.
FIG. 11 is a main part configuration diagram of a conventional batch type chemical vapor deposition apparatus.
12 is a model diagram showing a state inside an inner vessel tube of the vertical polysilicon chemical vapor deposition apparatus of FIG.
FIG. 13 is a diagram showing a relationship between a wafer position and a film thickness.
FIG. 14 is a diagram showing a portion where the thickness of a polysilicon film on a wafer is measured.
FIG. 15 is a diagram showing inconvenience in the case of a trench groove;
FIG. 16 is a diagram showing inconvenience in the case of a planar;
[Explanation of symbols]
1 wafer
2) Support jig
3 Exhaust opening
4 Inner container tube
5 Outer container tube
6 heater
7 heating furnace
8 lid
9 Reaction chamber
10mm gas inlet
11 Gas outlet
12 gas flow

Claims (11)

A heating furnace, an outer container tube housed in the heating furnace, one end of which is closed; an inner container tube housed in the outer container tube, both ends of which are open; and a plurality of housed in the inner container tube, A supporting jig for arranging the substrates in a row, and forming a thin film on the substrate by flowing a reactive gas between the wall surface of the inner container tube and the supporting jig on which the substrate is arranged. In the vapor phase growth equipment,
A chemical vapor deposition apparatus having an exhaust opening for exhausting a part of the reactive gas on a wall surface of the inner vessel tube. A heating furnace, an outer container tube housed in the heating furnace, one end of which is closed; an inner container tube housed in the outer container tube, both ends of which are open; and a plurality of housed in the inner container tube, A supporting jig for arranging the substrates in a row, and forming a thin film on the substrate by flowing a reactive gas between the wall surface of the inner container tube and the supporting jig on which the substrate is arranged. In the vapor phase growth equipment,
The chemical vapor deposition apparatus according to claim 1, wherein the inner container tube is formed in multiple layers, and has an exhaust opening for exhausting a part of the reactive gas at least on a wall surface of the innermost inner container tube. 3. The chemical vapor deposition apparatus according to claim 1, wherein the exhaust opening is formed symmetrically with respect to a center of the inner vessel tube in a horizontal direction. The chemical vapor deposition apparatus according to claim 1, wherein a wall surface of the inner container tube has a plurality of the exhaust openings formed in a mesh shape. A heating furnace, an outer container tube housed in the heating furnace, one end of which is closed; an inner container tube housed in the outer container tube, both ends of which are open; and a plurality of housed in the inner container tube, A supporting jig for arranging the substrates in a row, in a chemical vapor deposition apparatus for forming a thin film on the substrate by flowing a reactive gas to the inner container tube,
The chemical vapor deposition apparatus, wherein the inner container tube is divided into a plurality of regions in the row direction of the substrate, and each inner container tube has an internal supply port and an internal exhaust port for a reactive gas. The said support jig is provided with the shielding board arrange | positioned between the said board | substrates arrange | positioned in a row, The said inner container pipe | tube is divided into several area | regions by the said shielding board, The Claims characterized by the above-mentioned. Chemical vapor deposition equipment. A reactive gas supply pipe for a reactive gas supplied to each of the plurality of regions of the inner container pipe is provided, and the distance from the outer container pipe to the inner container pipe of the reactive gas supply pipe is substantially equal. 7. The chemical vapor deposition apparatus according to claim 5, wherein: A reactive gas supply pipe for supplying the reactive gas to the inner container pipe, wherein the reactive gas supply pipe connects the outer container pipe from the outside of the heating furnace in a substantially horizontal direction to each region of the inner container pipe. The chemical vapor deposition apparatus according to claim 5, wherein the chemical vapor deposition apparatus is configured to reach the internal vessel tube via a through hole. The chemical vapor deposition apparatus according to any one of claims 5 to 8, further comprising temperature control means for controlling the temperature of the reactive gas to be substantially the same as the ambient temperature in the outer vessel tube. 7. The reactive gas supply pipe for supplying a reactive gas to the inner container pipe, wherein the inner diameter of the reactive gas supply pipe is set to 50 mm or less. Chemical vapor deposition equipment. 10. The chemical vapor deposition apparatus according to claim 7, wherein an inner diameter of the reactive gas supply pipe is set to 50 mm or less.

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