JP2011023550A - Method for manufacturing semiconductor epitaxial wafer, and semiconductor epitaxial wafer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method for manufacturing semiconductor epitaxial wafer, capable of producing and supplying a semiconductor epitaxial wafer in which an epitaxial film has uniform resistivity distribution and a transition width is narrow, with high quality and productivity, and to provide the semiconductor epitaxial wafer. <P>SOLUTION: The method for manufacturing a semiconductor epitaxial wafer is such that a protection film for dopant vaporization prevention is formed on at least of a back surface of the semiconductor wafer; a first polysilicon film is formed so as to cover the protection film for dopant vaporization prevention then the semiconductor wafer is placed in a reactor; and gas for epitaxial growth is introduced to the reactor to form the epitaxial film on the surface of the semiconductor wafer. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a method for manufacturing a semiconductor epitaxial wafer and a semiconductor epitaxial wafer capable of stably manufacturing a high-quality semiconductor epitaxial wafer.

  Semiconductor epitaxial wafers have long been used as wafers for manufacturing discrete semiconductors, bipolar ICs and the like because of their excellent characteristics. MOS LSIs are also widely used in microprocessor units and flash memory devices because of their excellent soft error and latch-up characteristics.

  As an example of the excellent characteristics of the semiconductor epitaxial wafer, since there is substantially no so-called Grown-in defect such as COP (Crystal Originated Particle) introduced at the time of manufacturing a single crystal, defects such as DRAM reliability are reduced. The demand is growing more and more.

Here, an example of a method for manufacturing a semiconductor epitaxial wafer according to the prior art will be described.
A semiconductor single crystal ingot is generally manufactured by the Czochralski (CZ) method or the floating zone (FZ) method. The manufactured semiconductor single crystal ingot is cut into blocks and subjected to a rounding process (cylindrical grinding process) to make the diameters uniform. A wafer-shaped semiconductor wafer is cut out from the semiconductor single crystal ingot (slicing process), and chamfered (beveling process) in order to drop the corners of the peripheral portion of the cut-out semiconductor wafer. Further, mechanical polishing (lapping process; referred to as a lapped wafer at this stage) is performed in order to eliminate unevenness on the surface of the semiconductor wafer, increase the flatness, and minimize processing distortion during slicing. Thereafter, the strained polishing layer formed on the surface layer of the semiconductor wafer during mechanical polishing is removed by mixed acid etching (etching process; called an etched wafer at this stage).

  Next, a protective film for preventing autodoping (a protective film for preventing dopant volatilization) is formed on at least the back surface of the semiconductor wafer, and then chemically and mechanically polished (chemical mechanical polishing: CMP). The semiconductor wafer is subjected to mirror polishing (mirror polishing process; called a polished wafer at this stage) to make the surface of the semiconductor wafer into a mirror surface, and an epitaxial film is formed on the surface of the mirror-polished semiconductor wafer. Epitaxial wafers are manufactured.

Here, a supplementary explanation of autodoping is provided. In an epitaxial process in which a semiconductor single crystal thin film (epitaxial film) is vapor-phase grown on a semiconductor wafer, the semiconductor wafer is usually exposed to a high temperature of approximately 1000 to 1200 ° C. At that time, a phenomenon that the dopant contained in the semiconductor wafer is volatilized during the epitaxial film forming process and taken into the epitaxial film, so-called auto-doping phenomenon occurs.
In particular, in the manufacture of power MOS semiconductor epitaxial wafers, a low resistivity semiconductor wafer of either P-type or N-type conductivity doped with impurities at a high concentration has been used as a substrate for forming an epitaxial film. In this case, the occurrence of auto-doping becomes remarkable.

  That is, when such a highly doped semiconductor wafer is heated, if a protective film for preventing dopant volatilization is not formed on the semiconductor wafer, boron, phosphorus, antimony, arsenic, etc. doped on the semiconductor wafer As a result, an auto-doping phenomenon occurs in which the impurities jump out of the semiconductor wafer and enter the epitaxial film, and an epitaxial film having a desired resistivity cannot be obtained. As a result, the electrical characteristics of the semiconductor epitaxial wafer change, and a semiconductor element manufactured using this semiconductor epitaxial wafer does not exhibit the designed characteristics and becomes defective.

In order to minimize the influence of auto-doping, a protective film for preventing dopant volatilization such as an oxide film (for example, SiO ₂ ) or a nitride film (for example, Si ₃ N ₄ ) is added to the chemical vapor phase in the manufacturing process of the semiconductor epitaxial wafer. A process of forming on the back side of the semiconductor wafer by using a growth (CVD: Chemical Vapor Deposition) method, a thermal oxidation method, a thermal nitridation method or the like is an indispensable manufacturing process (see, for example, Patent Document 1).
In particular, not only when an epitaxial film is formed on a semiconductor wafer having a low resistivity where auto-doping becomes significant, but also when a semiconductor wafer having a high resistivity is used, a high-resistance epitaxial film may be obtained. Yes, it can be said that the manufacturing process is indispensable at such times.

On the other hand, in the process of manufacturing a semiconductor device using such a semiconductor epitaxial wafer, the semiconductor device is exposed to various heavy metal contamination. As a result, the performance, yield, and reliability of the semiconductor device are lowered. In particular, the concentration of heavy metal impurities required for the most advanced devices is considered to be 1 × 10 ¹⁰ atoms / cm ² or less, and heavy metal impurities must be reduced as much as possible. Also in semiconductor epitaxial wafers, gettering technology is becoming increasingly important as one of the technologies for reducing the influence of heavy metal impurities on such semiconductor devices.

  As a method for enhancing such a gettering effect, a method of depositing polysilicon on the back surface of a semiconductor wafer (PBS; Poly Back Seal (registered trademark)) is known (for example, see Patent Document 2), and a semiconductor epitaxial wafer is known. Has been applied to the manufacture of. The PBS (hereinafter also referred to as backside polysilicon film) method is a method in which a polysilicon film of about 0.1 μm to 2.0 μm is grown on the backside of a semiconductor epitaxial wafer by a CVD method of about 650 ° C. Further, various heavy metal impurities are gettered to the grain boundaries of the polysilicon in the polysilicon film.

JP 58-95819 A Japanese Patent Laid-Open No. 52-120777

  By the way, in recent years, higher integration and higher accuracy of semiconductor devices have been progressed, and semiconductor wafers have been increasing in diameter. In particular, the demand for semiconductor wafers having a large diameter of 200 mm or more is increasing.

  In the epitaxial growth of such a large-diameter semiconductor wafer having a diameter of 200 mm or more, the uniformity of the resistivity distribution of the epitaxial film, the transition width (the region where the dopant concentration transitions near the boundary between the epitaxial film and the semiconductor wafer having different dopant concentrations) In order to reduce the width of the semiconductor wafer, the role of the protective film for preventing the volatilization of the highly doped dopant in the semiconductor wafer is very important.

However, an oxide film (for example, SiO ₂ ) or a nitride film (for example, Si ₃ N ₄ ) as a protective film for preventing dopant volatilization is easily etched by a chemical solution (HF) in an epitaxial growth process or a cleaning process in a semiconductor process, There exists a problem that it will be removed or etched in these device manufacturing processes, and it will become impossible to exhibit sufficient dopant volatilization prevention capability.

  Moreover, there is a problem that a sufficient effect of preventing dopant volatilization from the semiconductor wafer cannot be expected simply by forming a polysilicon film on the back surface for the purpose of gettering various heavy metal impurities on the back surface of the semiconductor wafer. It is necessary to form a protective film (oxide film or nitride film) for preventing dopant volatilization, but it is removed or etched by chemicals in the vapor phase growth process or cleaning process of the epitaxial film, and has sufficient ability to prevent dopant volatilization. There is a problem that it cannot be obtained.

Furthermore, after forming a protective film for preventing dopant volatilization, a polysilicon film is continuously formed for the purpose of protecting the protective film, and then the wafer surface is polished in the conventional process of polishing the wafer surface side and the wafer edge. The protective film for preventing dopant volatilization is exposed at the part, and the protective film at the exposed part is etched in the chemical solution use process such as epitaxial growth and cleaning, and the function for preventing dopant volatilization is lowered, and the polysilicon layer is overhanged. Since it becomes a shape and the portion is easily peeled off, there is a problem that dust is generated, the semiconductor process is contaminated, and the product yield is deteriorated.
In addition, during the epitaxial process, there is a problem in that polysilicon is abnormally grown and exfoliated on the exposed protective film and taken into the epitaxial layer, causing a serious crystal defect.

  Accordingly, the present invention has been made in view of such problems, and a semiconductor epitaxial wafer having a uniform resistivity distribution and a narrow transition width is manufactured and supplied with high quality and high productivity. An object of the present invention is to provide a method for manufacturing a semiconductor epitaxial wafer, and such a semiconductor epitaxial wafer.

  In order to solve the above problems, the present invention provides a method for manufacturing a semiconductor epitaxial wafer, wherein at least a protective film for preventing volatilization of dopant is formed on the back side of the semiconductor wafer, and then the entire protective film for preventing volatilization of dopant is covered. After forming the first polysilicon film, the semiconductor wafer is placed in a reaction furnace, and an epitaxial growth gas is introduced into the reaction furnace to form an epitaxial film on the surface side of the semiconductor wafer. A method of manufacturing a semiconductor epitaxial wafer is provided.

In this way, first, a protective film for preventing dopant volatilization is formed on the back surface of the semiconductor wafer, and subsequently, after forming the first polysilicon film so as to cover the entire protective film for preventing volatilization of dopant, an epitaxial film is formed on the surface side. Thus, a semiconductor epitaxial wafer is manufactured.
Thus, the protective film for preventing volatilization of the dopant which is easily removed or etched during the vapor phase growth process of the epitaxial film and the cleaning process before and after the epitaxial film can be protected by the first polysilicon film, thereby preventing the volatilization of the dopant. It can prevent that a protective film becomes thin or lose | disappears. Therefore, it is possible to reliably prevent autodoping from being generated by heat during vapor phase growth or the like.
In addition, by completely covering the protective film for preventing dopant volatilization with the first polysilicon film, granular polysilicon grows abnormally or exfoliates on the exposed protective film for preventing volatilization of the dopant in the epitaxial film forming step. This can be surely prevented.
Accordingly, it is possible to stably manufacture a high-quality semiconductor epitaxial wafer having a stable resistivity distribution, high uniformity, a narrow transition width, and few defects.

Here, it is preferable to form a second polysilicon film on the back surface side of the semiconductor wafer before the formation of the protective film for preventing the volatilization of the dopant.
Thus, before forming the protective film for preventing dopant volatilization, by forming the second polysilicon film on the back side of the semiconductor wafer, a polysilicon film as a gettering site can be formed on the back side. A semiconductor epitaxial wafer having a desired resistivity distribution and a high gettering function can be manufactured at a high yield.

In addition, after forming the dopant volatilization-preventing protective film, etching the outer peripheral part of the dopant volatilization-preventing protective film to expose the outer peripheral part of the semiconductor wafer, the dopant volatilization-preventing protective film and the semiconductor wafer The first polysilicon film is preferably formed so as to cover the entire outer peripheral portion.
In this way, after forming the protective film for preventing volatilization of dopant, etching and removing the outer peripheral portion of the protective film for volatilizing dopant, and then forming the first polysilicon film, the semiconductor wafer exposed to the removed portion and the first 2 A new polysilicon film can be formed in close contact with the polysilicon film, and the protective film for preventing dopant volatilization can be completely covered with the first polysilicon film, which is removed or etched in the epitaxial growth process or the cleaning process. This can be prevented more easily and reliably. Therefore, it can be set as the manufacturing method of the semiconductor epitaxial wafer which can maintain the function as a protective film for dopant volatilization prevention to the maximum.

A silicon oxide film is preferably formed as the protective film for preventing dopant volatilization.
Thus, as the protective film for preventing dopant volatilization, it is preferable to form a silicon oxide film by, for example, atmospheric pressure CVD or thermal oxidation because it can be easily formed.

  According to the present invention, there is provided a semiconductor epitaxial wafer, wherein at least a dopant volatilization-preventing protective film, the entire dopant volatilization-preventing protective film, and the outer periphery of the semiconductor wafer are covered on at least the back surface of the semiconductor wafer. There is provided a semiconductor epitaxial wafer comprising a silicon film and having an epitaxial film on a surface of the semiconductor wafer.

In this way, by forming a semiconductor epitaxial wafer having a protective film for preventing volatilization of dopant, a first polysilicon film covering the entire outer periphery of the semiconductor wafer and the protective film for preventing volatilization of dopant on the back surface side, the first The polysilicon film suppresses the removal and etching of the dopant volatilization-preventing protective film in the epitaxial film forming process and the chemical solution using process such as cleaning. Therefore, the occurrence of problems due to auto-doping during heat treatment is suppressed, and the resistivity distribution is a desired semiconductor epitaxial wafer.
Moreover, since the protective film for preventing dopant volatilization is not exposed, the occurrence of problems due to unintentionally growing the polysilicon film on the protective film for preventing dopant volatilization is suppressed.
Due to these effects, the resistivity of the epitaxial film is a desired value, the transition width is small, and a high-quality semiconductor epitaxial wafer with few defects and the like is obtained.

Here, it is preferable that a second polysilicon film is further provided between the semiconductor wafer and the protective film for preventing dopant volatilization.
As described above, if the second polysilicon film is provided between the semiconductor wafer and the dopant volatilization-preventing protective film, the semiconductor epitaxial wafer has a high gettering function for metal impurities and a desired resistivity distribution. It has become.

The protective film for preventing dopant volatilization is preferably a silicon oxide film.
Thus, since the silicon oxide film can be easily and easily formed by a CVD method or a thermal oxidation method, if the protective film for preventing volatilization of the dopant is a silicon oxide film, it can be easily formed. A semiconductor epitaxial wafer having a low manufacturing cost can be obtained.

  As described above, according to the present invention, a semiconductor epitaxial wafer in which the protective film for preventing dopant volatilization is completely covered with the polysilicon film on the back side and a method for manufacturing the same are provided, and the resistivity distribution of the epitaxial film is uniform. And a high-quality semiconductor epitaxial wafer that achieves a narrow transition width and prevents particle contamination. Therefore, a high-quality semiconductor epitaxial wafer can be manufactured at low cost and with high productivity, and high yield in LSI devices can be expected.

It is a figure which shows an example of the manufacturing flow of the semiconductor epitaxial wafer of this invention. It is a figure which shows another example of the manufacturing flow of the semiconductor epitaxial wafer of this invention. It is a figure which shows an example of the structure of the semiconductor epitaxial wafer of this invention. It is a figure which shows another example of the structure of the semiconductor epitaxial wafer of this invention. It is the figure which showed the relationship between the size and number of particles which exist in the surface of the semiconductor epitaxial wafer in Example 1 and Comparative Example 1 of this invention. 6 is a diagram comparing variations in resistivity of silicon epitaxial layers of semiconductor epitaxial wafers of Example 1 and Comparative Example 2. FIG. 6 is a diagram showing a relationship between a distance from a wafer end portion of a silicon epitaxial layer and resistivity of semiconductor epitaxial wafers of Example 1 and Comparative Example 2. FIG.

Hereinafter, the present invention will be described more specifically.
As described above, a method of manufacturing a semiconductor epitaxial wafer and development of a semiconductor epitaxial wafer capable of manufacturing a semiconductor epitaxial wafer having a uniform epitaxial film resistivity distribution and a narrow transition width with high quality and high productivity. Was waiting.

  Therefore, as a result of intensive studies, the inventor does not expose the protective film for preventing dopant volatilization by forming a protective film for preventing dopant volatilization and a polysilicon film covering the entire surface on the back surface of the semiconductor wafer. The structure prevents the surroundings of the protective film for preventing the volatilization of dopants and the polysilicon film from peeling off, prevents the generation of dust and the performance, and prevents the protective film for preventing the volatilization of dopants from deteriorating, thereby suppressing the occurrence of auto-doping As a result, the present invention was completed.

Hereinafter, the present invention will be described in detail with reference to the drawings, but the present invention is not limited thereto.
FIG. 3 is a view showing an example of the structure of the semiconductor epitaxial wafer of the present invention. FIG. 4 is a view showing another example of the structure of the semiconductor epitaxial wafer of the present invention.

  As shown in FIG. 3, the semiconductor epitaxial wafer 10 of the present invention includes a protective film 12 for preventing dopant volatilization, the entire protective film 12 for preventing dopant volatilization, and the semiconductor wafer 11 at least on the back side of the semiconductor wafer 11. A first polysilicon film 13 covering the outer peripheral portion of the semiconductor wafer 11 and an epitaxial film 15 on the surface side of the semiconductor wafer 11.

  Thus, the protective film for preventing dopant volatilization is etched during the vapor phase growth process of the epitaxial film or during the cleaning process with the cleaning chemical by making the structure not exposing the entire protective film for preventing dopant volatilization. This can be prevented and generation of autodoping can be strongly suppressed. As a result, the resistivity of the epitaxial film is uniform and has a desired value, and the semiconductor epitaxial wafer has a narrow transition width.

In addition, by making the periphery of the protective film for preventing dopant volatilization not exposed, it is possible to prevent abnormal growth (such as nodules) of polycrystalline particles during the vapor phase growth process of the epitaxial film, It is possible to prevent generation of dust due to peeling of the nodules, and troubles (such as catching) due to the generation of friction when the wafers are conveyed in contact with the wafer due to the generation of nodules.
Further, since the back surface is stably protected by the first polysilicon film, the generation of dust due to the exfoliation of the first polysilicon film is prevented. This is a semiconductor epitaxial wafer that can provide a high-quality device.

  As shown in FIG. 4, the semiconductor epitaxial wafer 20 of the present invention includes a second polysilicon film 24 and a protective film for preventing dopant volatilization on the second polysilicon film 24 at least on the back surface of the semiconductor wafer 21. 22, the dopant volatilization-preventing protective film 22, and the first polysilicon film 23 covering the outer peripheral portion of the semiconductor wafer 21, and the epitaxial film 25 on the surface of the semiconductor wafer 21. .

  In this way, the protective film for preventing dopant volatilization is completely covered with the first polysilicon film, and the semiconductor epitaxial wafer has the second polysilicon film between the semiconductor wafer and the protective film for volatilization of dopant. For example, the presence of the second polysilicon film results in a semiconductor epitaxial wafer having a high gettering function for metal impurities, and thus a semiconductor epitaxial wafer having a uniform resistivity distribution and a narrow transition width and a high gettering function. it can.

Moreover, the protective films 12 and 22 for preventing dopant volatilization can be silicon oxide films.
By using a silicon oxide film as the protective film for preventing dopant volatilization, a semiconductor with good resistivity distribution characteristics that can be easily and easily formed by atmospheric pressure CVD or thermal oxidation, and can be manufactured at low cost. It can be an epitaxial wafer.

Next, an example of a method for producing a semiconductor epitaxial wafer according to the present invention will be described below with reference to the drawings. However, the present invention is not limited to this.
FIG. 1 is a diagram showing an example of a manufacturing flow of a semiconductor epitaxial wafer of the present invention.

First, the process up to slicing and wrapping a single crystal ingot to a predetermined thickness is the same as the conventional process in principle.
Specifically, as shown in FIG. 1A, a semiconductor single crystal ingot is manufactured and prepared by a Czochralski (CZ) method or a floating zone (FZ) method. Then, the manufactured semiconductor single crystal ingot is cut into blocks having a predetermined length and subjected to a rounding process (cylindrical grinding process) in order to make the diameters uniform. Then, a wafer-like semiconductor wafer is cut out from the semiconductor single crystal ingot (slicing process).
Then, as shown in FIG. 1B, chamfering (beveling process or edge grinding process) is performed to drop the corners of the peripheral portion of the cut-out semiconductor wafer.
Further, as shown in FIG. 1 (c), mechanical polishing (lapping process; called a lapped wafer at this stage) is performed, and the polishing strain layer formed on the surface layer of the semiconductor wafer during mechanical polishing is subjected to mixed acid etching. Remove (etching process).
The above is a process similar to the conventional process.

In the present invention, as shown in FIG. 1D, a dopant volatilization preventing protective film for preventing autodoping is then formed on the back side of the semiconductor wafer.
By forming this dopant volatilization-preventing protective film, for example, the dopant doped at a high concentration in the semiconductor wafer is volatilized in the epitaxial film formation process and other heat treatment processes, and the dopant is volatilized and taken into the epitaxial film. It can be strongly suppressed.

Here, a silicon oxide film can be formed as the protective film for preventing dopant volatilization.
A silicon oxide film can be easily formed by deposition by atmospheric pressure CVD, formation of a thermal oxide film by thermal oxidation, or the like, and can be manufactured at low cost.

Then, as shown in FIG.1 (e), the outer peripheral part of the protective film for dopant volatilization prevention can be etched.
In this case, the removal range of the protective film for preventing dopant volatilization located on the outer peripheral portion of the semiconductor wafer is about 0 to several millimeters in the vicinity of the wafer surface, an arbitrary position of the wafer edge round portion, and the innermost position on the back surface, and particularly about 0 It is desirable to remove a range of about ˜2 mm.
This is because if it is removed too much, the influence of auto-doping becomes large, the resistivity distribution may be deteriorated, and the quality of the semiconductor epitaxial wafer may be impaired.

Thereafter, as shown in FIG. 1 (f), a first polysilicon film is formed on the back surface of the semiconductor wafer so as to cover the entire dopant volatilization-preventing protective film and the outer periphery of the semiconductor wafer. The formation of the first polysilicon film can be performed by a general method.
Thereby, it is possible to prevent the protective film for preventing dopant volatilization from being exposed to the entire periphery of the wafer. Etching of the protective film for preventing volatilization of dopant by HF, peeling of the protective film, and generation of dust accompanying it. Can be prevented. Further, it is possible to prevent the generation of nodules on the back surface side of the semiconductor wafer in the subsequent epitaxial film formation step.

Thereafter, as shown in FIG. 1G, the edge of the semiconductor wafer can be polished.
At this stage, by performing edge polishing of the semiconductor wafer, it is possible to further reduce the possibility of the polysilicon at the edge portion dropping off. In this edge polishing, only the first polysilicon film is etched so that the protective film for preventing dopant volatilization is not exposed.

Thereafter, mirror polishing for making the surface side of the semiconductor wafer into a mirror surface can be performed.
Then, as shown in FIG. 1 (h), the polished semiconductor wafer is introduced into a reaction furnace, and an epitaxial film forming step for forming an epitaxial film on the surface side is performed to manufacture a semiconductor epitaxial wafer. FIG. 3 is a schematic example of a semiconductor epitaxial wafer manufactured by such a manufacturing method.

As a result, since the protective film for preventing dopant volatilization is entirely covered with the first polysilicon film, the protective film for preventing volatilization of dopant is not consumed by etching or the like, so that autodoping can be suppressed and a desired resistance can be suppressed. A semiconductor epitaxial wafer having a rate distribution can be manufactured.
In addition, since the first polysilicon film can be prevented from being peeled off by etching of the protective film for preventing dopant volatilization, dust generation is small, and in the epitaxial film forming process, nodule generation is strongly suppressed on the back surface side. There is an effect to.

  The fabricated semiconductor epitaxial wafer will be subjected to device manufacturing processes thereafter, and the protective film for preventing dopant volatilization is stably maintained in various processes such as cleaning, CVD processing, and heat treatment in these device processes. Therefore, it contributes to obtaining a high-quality device with a high yield.

  Further, the semiconductor epitaxial wafer of the present invention can also be manufactured by a method as shown in FIG. 2 which is another example of the manufacturing flow of the semiconductor epitaxial wafer of the present invention.

  The steps shown in FIGS. 2A to 2C are the same as the steps up to FIGS. 1A to 1C.

Thereafter, as shown in FIG. 2D, a second polysilicon film is formed on the back surface side in order to provide a gettering function. The second polysilicon film may be formed by a general method.
This second polysilicon film functions as a gettering site, a semiconductor epitaxial wafer having a high gettering capability and a desired resistivity distribution can be manufactured.

Thereafter, as shown in FIG. 2E, a protective film for preventing dopant volatilization is formed on the second polysilicon film.
The silicon oxide film can be formed as the protective film for preventing dopant volatilization as in FIG.

  As the next step, as shown in FIG. 2F, the outer peripheral portion of the dopant volatilization-preventing protective film can be etched, and the outer peripheral portion of the second polysilicon film and the semiconductor wafer can be exposed.

  Thereafter, as shown in FIG. 2G, a first polysilicon film is formed so as to cover the entire dopant volatilization-preventing protective film, and the dopant volatilization-preventing protective film is completely covered. At this time, the first polysilicon film covers the protective film for preventing volatilization of the dopant in a form connected to the second polysilicon film or the semiconductor wafer.

Then, as shown in FIG. 2 (h), the edge portion can be polished.
Thereafter, mirror polishing for making the surface side of the semiconductor wafer into a mirror surface can be performed, and the polished semiconductor wafer is introduced into a reaction furnace as shown in FIG. Then, an epitaxial film is formed on the surface side of the semiconductor wafer to manufacture the semiconductor epitaxial wafer.
FIG. 4 shows the outline of an example of the semiconductor epitaxial wafer manufactured by such a method of manufacturing a semiconductor epitaxial wafer. By such a manufacturing method, a high-quality semiconductor epitaxial wafer having a high gettering capability can be efficiently manufactured.

EXAMPLES Hereinafter, although an Example and a comparative example are shown and this invention is demonstrated more concretely, this invention is not limited to these.
Example 1
Specifically, 48 silicon single crystal wafers (lapping wafers) having a diameter of 200 mm (8 inches), a thickness of 725 μm, and a conductivity type of P type were prepared.
Then, a silicon oxide film having a thickness of about 500 nm was formed on the back side of the prepared semiconductor wafer using SiH ₄ and O ₂ gas as a protective film for preventing volatilization of dopant using an atmospheric pressure CVD apparatus.
Next, a range of 2.0 mm from the outer peripheral portion of the CVD oxide film was removed by etching using a HF 20% solution to expose the surface of the semiconductor wafer only at the outer peripheral portion of 2.0 mm.
Further, using a LP-CVD apparatus, SiH ₄ gas was supplied together with H ₂ carrier gas, and a first polysilicon film was grown on the back surface by 500 nm.
And it processed so that the silicon oxide film as a protective film for dopant volatilization prevention might not be exposed by performing polish to edge part 1.5mm of a semiconductor wafer.
Thereafter, the surface side of the semiconductor wafer was mirror-polished.

Next, the polished silicon wafer was put into an epitaxial growth furnace, SiHCl ₃ was supplied as a source gas together with a hydrogen carrier gas, a silicon epitaxial film was formed on the surface side, and a semiconductor epitaxial wafer was manufactured.

The manufactured semiconductor epitaxial wafer was evaluated as shown below.
First, in order to evaluate the size and number of particles on the surface, a silicon epitaxial film was grown to 10 μm, immersed in 20% HF for 60 minutes, stored in PP-Box, and with wafer holding packing removed, for 5 minutes. After applying vibration manually, the size and number of particles present on the surface were measured. The result is shown in FIG. FIG. 5 is a diagram showing the relationship between the size and number of particles present on the surface of the semiconductor epitaxial wafer in Example 1 and Comparative Example 1 of the present invention.
Further, in order to evaluate the resistivity of the silicon epitaxial film, the resistivity at nine points in the plane of the epitaxial film was measured, and the in-plane distribution and its variation were evaluated. The results are shown in FIGS. FIG. 6 is a diagram comparing variations in resistivity of the silicon epitaxial layers of the semiconductor epitaxial wafers of Example 1 and Comparative Example 2. FIG. 7 is a wafer end portion of the silicon epitaxial layer of the semiconductor epitaxial wafers of Example 1 and Comparative Example 2. It is the figure which showed the relationship between the distance from and resistivity.

(Comparative Example 1)
In Example 1, the formation of the first polysilicon film was performed in the same manner as in Example 1 except that the entire CVD oxide film was not covered and a semiconductor epitaxial wafer was manufactured in the same manner as in Example 1. The particle size and number were evaluated and the results are shown in FIG.

(Comparative Example 2)
In Example 1, a semiconductor epitaxial wafer was manufactured by the same method as in Example 1 except that the CVD oxide film was not formed, and the resistivity of the silicon epitaxial film was evaluated in the same manner as in Example 1. This is shown in FIGS.

  As shown in FIG. 5, the number of particles with a size of around 0.3 μm is slightly smaller in Example 1 and Comparative Example 1 than in Example 1, but the size is large (around 1.0 μm or more than 20 μm). ) The total number of particles was clearly smaller in the semiconductor epitaxial wafer of Example 1 than in Comparative Example 1, and a significant difference appeared at the number of particles of 20 μm or more.

In addition, as shown in FIG. 6, the variation in resistivity of the silicon epitaxial layer of the semiconductor epitaxial wafer of Example 1 was 4% or less, whereas the semiconductor epitaxial wafer of Comparative Example 2 was before the epitaxial growth of the silicon epitaxial layer. In some cases, the back surface oxide film peels off, and the auto-doping phenomenon is remarkably generated. Therefore, the variation in the in-plane distribution of resistivity is 13% or more.
Further, while the resistivity of the semiconductor epitaxial wafer of Comparative Example 2 is sagging, the semiconductor epitaxial wafer of Example 1 is hardly sagging at the wafer end, It was found that the inside was almost uniform.

(Example 2)
Forty eight silicon single crystal wafers (lapping wafers) having a diameter of 200 mm (8 inches), a thickness of 725 μm, and a conductivity type P type were prepared.
Then, for the purpose of impurity gettering, a 1.0 μm second polysilicon film is grown on the back side of the prepared semiconductor wafer by supplying SiH ₄ gas together with H ₂ carrier gas using an LP-CVD apparatus. I let you.
Thereafter, a silicon oxide film having a thickness of 500 nm was formed as a protective film for preventing volatilization of dopant using SiH ₄ and O ₂ gas using an atmospheric pressure CVD apparatus.
Next, a range of 2.0 mm from the outer peripheral portion of the CVD oxide film was removed by etching using a HF 20% solution, and the second polysilicon film was exposed only at the outer peripheral portion.

Further, using a LP-CVD apparatus, SiH ₄ gas was supplied together with H ₂ carrier gas to grow the first polysilicon film by 1.0 μm.
And it processed so that the silicon oxide film as a protective film for dopant volatilization prevention might not be exposed by performing polish to edge part 1.5mm of a semiconductor wafer.
Thereafter, the surface side of the semiconductor wafer was mirror-polished.
Next, the polished silicon wafer was put into an epitaxial growth furnace, SiHCl ₃ was supplied as a source gas together with a hydrogen carrier gas, a silicon epitaxial film was formed on the surface side, and a semiconductor epitaxial wafer was manufactured.

  The semiconductor epitaxial wafer of Example 2 produced in this way was evaluated in the same manner as in Example 1. As a result, it was found that the semiconductor epitaxial wafer was at the same level as in Example 1.

  The present invention is not limited to the above embodiment. The above-described embodiment is an exemplification, and the present invention has any configuration that has substantially the same configuration as the technical idea described in the claims of the present invention and exhibits the same function and effect. Are included in the technical scope.

10, 20 ... Semiconductor epitaxial wafer,
DESCRIPTION OF SYMBOLS 11, 21 ... Semiconductor wafer, 12, 22 ... Protective film for preventing dopant volatilization, 13, 23 ... First polysilicon film, 15, 25 ... Epitaxial film, 24 ... Second polysilicon film.

Claims (7)

A method for manufacturing a semiconductor epitaxial wafer, comprising:
At least after forming a protective film for preventing dopant volatilization on the back side of the semiconductor wafer, and then forming a first polysilicon film so as to cover the entire protective film for preventing volatilization of dopant,
A method for producing a semiconductor epitaxial wafer, comprising: placing the semiconductor wafer in a reaction furnace; and introducing an epitaxial growth gas into the reaction furnace to form an epitaxial film on the surface side of the semiconductor wafer.   2. The method of manufacturing a semiconductor epitaxial wafer according to claim 1, wherein a second polysilicon film is formed on a back surface side of the semiconductor wafer before the formation of the protective film for preventing dopant volatilization.   After forming the protective film for preventing volatilization of dopant, etching the outer peripheral part of the protective film for volatilizing dopant to expose the outer peripheral part of the semiconductor wafer, and then the protective film for preventing volatilization of dopant and the outer peripheral part of the semiconductor wafer 3. The method of manufacturing a semiconductor epitaxial wafer according to claim 1, wherein the first polysilicon film is formed so as to cover the entire surface of the semiconductor epitaxial wafer.   4. The method of manufacturing a semiconductor epitaxial wafer according to claim 1, wherein a silicon oxide film is formed as the protective film for preventing dopant volatilization. A semiconductor epitaxial wafer, at least,
On the back surface of the semiconductor wafer, there is a protective film for preventing dopant volatilization, and a first polysilicon film covering the entire protective film for preventing dopant volatilization and the outer periphery of the semiconductor wafer,
A semiconductor epitaxial wafer comprising an epitaxial film on a surface of the semiconductor wafer.   6. The semiconductor epitaxial wafer according to claim 5, further comprising a second polysilicon film between the semiconductor wafer and the protective film for preventing dopant volatilization.   The semiconductor epitaxial wafer according to claim 5, wherein the protective film for preventing dopant volatilization is a silicon oxide film.

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