WO2022219937A1

WO2022219937A1 - Method for cleaning silicon wafer, and method for producing silicon wafer with native oxide film

Info

Publication number: WO2022219937A1
Application number: PCT/JP2022/007392
Authority: WO
Inventors: 康太藤井; 達夫阿部; 健作五十嵐; 剛大槻
Original assignee: 信越半導体株式会社
Priority date: 2021-04-13
Filing date: 2022-02-22
Publication date: 2022-10-20
Also published as: TW202245037A; KR20230169118A; JP7480738B2; CN117136428A; JP2022162915A

Abstract

The present invention is a method for cleaning a silicon wafer, the method comprising: a first cleaning step for cleaning the silicon wafer with hydrofluoric acid; a second cleaning step for cleaning the silicon wafer that has been cleaned with the hydrofluoric acid with ozone water; a third cleaning step for cleaning the silicon wafer that has been cleaned with the ozone water with an SC1 cleaning solution; and a fourth cleaning step for cleaning the silicon wafer that has been cleaned with the SC1 cleaning solution with ozone water. A method for cleaning a silicon wafer is provided, whereby it becomes possible to adjust the thickness of a native oxide film on the silicon wafer to a value falling within a specified range with high reproducibility and with high accuracy while keeping particle quality at a satisfactory level.

Description

Silicon wafer cleaning method and silicon wafer manufacturing method with native oxide film

The present invention relates to a method for cleaning a silicon wafer and a method for manufacturing a silicon wafer with a natural oxide film.

In the manufacturing process of single crystal silicon wafers for semiconductor devices, the main surface is finished in the polishing process. Furthermore, there is a cleaning process to remove abrasives and metal impurities adhered to the surface of the silicon wafer during the polishing process. In this cleaning process, a cleaning method called RCA cleaning is used. This RCA cleaning is a cleaning method in which SC1 (Standard Cleaning 1) cleaning, SC2 (Standard Cleaning 2) cleaning, and DHF (Diluted Hydrofluoric Acid) cleaning are combined according to the purpose.

SC1 cleaning mixes ammonia water and hydrogen peroxide water in an arbitrary ratio, lifts off adhering particles by etching the silicon wafer surface with an alkaline cleaning liquid, and further utilizes electrostatic repulsion between the silicon wafer and the particles. This cleaning method removes particles while suppressing redeposition to the silicon wafer. SC2 cleaning is a cleaning method of dissolving and removing metal impurities on the surface of a silicon wafer with a cleaning liquid obtained by mixing hydrochloric acid and hydrogen peroxide water in an arbitrary ratio. DHF cleaning is a cleaning method for removing a native oxide film on the surface of a silicon wafer with dilute hydrofluoric acid. Ozone water cleaning, which has a strong oxidizing power, may also be used to remove organic matter adhering to the silicon wafer surface and to form a natural oxide film on the silicon wafer surface after DHF cleaning. The particle quality of silicon wafers after cleaning is important, and these cleanings are combined according to the purpose.

Semiconductor elements such as MOS (Metal Oxide Semiconductor) capacitors and transistors are formed on the surface of a semiconductor silicon wafer. Insulating films such as gate oxide films formed in these semiconductor elements are used under high electric field strength, and silicon oxide films are often used as such insulating films because they are easy to form.

Dense silicon oxide films with high insulating properties are produced by thermally oxidizing silicon wafers, but in general, from the viewpoint of particle adhesion, etc., silicon wafers at the time of shipment have a natural oxide film formed during cleaning. . For this reason, thermal oxidation is often applied to silicon wafers on which a natural oxide film is formed. At this time, it is known that the thickness of the thermal oxide film is affected by the film quality (film thickness and structure) of the natural oxide film before thermal oxidation.

JP 2019-207923 A JP 2012-129409 A

In recent years, with the miniaturization and multi-layering of semiconductor integrated circuits, there is a demand for further thinning of various films, including the insulating films that make up the elements. Due to this thinning, it is necessary to form an ultra-thin insulating film, ie, a silicon oxide film, uniformly within the surface of the substrate or between the substrates with good reproducibility. For this purpose, it is required to control the film quality of the native oxide film at the time of shipment of the silicon wafer, especially the film thickness, which affects the quality of the silicon oxide film. In general, the thicker the natural oxide film, the thicker the thermal oxide film. If the thermal oxide film is desired to be thin, the natural oxide film should also be thin, and if the thermal oxide film is to be thick, the natural oxide film should also be thick. Therefore, in recent years, it is especially demanded to control the thickness of the native oxide film within a predetermined range with good reproducibility and high accuracy.

In Patent Document 1, a silicon wafer that has not been cleaned with hydrofluoric acid (simply referred to as “DHF cleaning” or “HF cleaning”) is SC1 cleaned, and then cleaned with an oxidizing cleaning liquid (ozone water or peroxide A cleaning method is described in which the thickness of the natural oxide film is increased by cleaning with hydrogen water). However, since DHF cleaning is not performed in Patent Document 1, particles not removed by SC1 cleaning may remain on the wafer surface, degrading the particle quality. In addition, the film thickness of all of the natural oxide films described in the examples is 1.0 nm, and it cannot be said that the film thickness of the natural oxide film can be controlled within a predetermined range.

In Patent Document 2, after SC1 cleaning, particles not removed by SC1 cleaning are removed by HF cleaning, and then ozone water cleaning is performed to suppress reattachment of particles and reduce surface roughness of the wafer. It describes a cleaning method that However, when the bare surface is cleaned with ozone water, the oxidation progresses rapidly. Therefore, although it is possible to form an oxide film with a uniform thickness with good reproducibility, the rapid oxidation reaction results in the formation of a natural oxide film. It was difficult to change and control the thickness within a predetermined range.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems. An object of the present invention is to provide a method for cleaning a wafer.

The present invention has been made to achieve the above objects, and is a method for cleaning a silicon wafer, comprising: a first cleaning step of cleaning the silicon wafer with hydrofluoric acid; a second cleaning step of cleaning the silicon wafer with ozone water; a third cleaning step of cleaning the silicon wafer cleaned with the ozone water with an SC1 cleaning liquid; and cleaning the silicon wafer cleaned with the SC1 cleaning liquid with the ozone water. and a fourth cleaning step.

With such a silicon wafer cleaning method, particle quality can be improved by performing both cleaning with hydrofluoric acid (HF cleaning) and SC1 cleaning. Further, by performing the fourth cleaning step, the cleaning method can control the natural oxide film thickness with good reproducibility and high accuracy.

At this time, the cleaning time of the fourth cleaning step can be adjusted to control the thickness of the natural oxide film formed on the surface of the silicon wafer.

As a result, it is possible to easily control the thickness of the native oxide film formed on the surface of the silicon wafer with better reproducibility and higher accuracy.

At this time, the correlation between the time for washing the silicon wafer having the natural oxide film formed thereon with ozone water in advance and the natural oxide film thickness increased by washing the silicon wafer having the natural oxide film formed thereon with the ozone water. A method of cleaning a silicon wafer may be provided in which a relationship is obtained and the cleaning time of the fourth cleaning step is set based on the correlation.

By using such a correlation, the cleaning time can be set more easily.

At this time, based on the correlation, the cleaning time of the fourth cleaning process is set so that the thickness of the natural oxide film formed on the surface of the silicon wafer in the second cleaning process is equal to the thickness of the natural oxide film. A method for cleaning a silicon wafer can be set.

As a result, the thickness of the native oxide film that has been thinned by the etching of the SC1 cleaning can be made equal to the thickness before the SC1 cleaning.

At this time, the silicon wafer cleaning method may include an SC2 cleaning step of cleaning the silicon wafer with an SC2 cleaning liquid after the third cleaning step and before the fourth cleaning step.

As a result, the metal impurities on the surface of the silicon wafer can be dissolved and removed, and the quality of the silicon wafer can be improved.

At this time, it can be a method for manufacturing a silicon wafer with a natural oxide film, which manufactures a silicon wafer with a natural oxide film by the above-described method for cleaning a silicon wafer.

As a result, it is possible to manufacture silicon wafers with a native oxide film with high particle quality, good reproducibility, and highly accurate control of the native oxide film thickness.

As described above, according to the silicon wafer cleaning method of the present invention, particle quality can be improved by performing both HF cleaning and SC1 cleaning. Further, by performing the fourth cleaning step, the cleaning method can control the thickness of the natural oxide film with good reproducibility and high accuracy. As a result, even when a thermal oxide film is formed, it is possible to obtain a silicon wafer in which the film thickness of the thermal oxide film can be easily controlled with high precision.

1 is a flow chart showing an example of a silicon wafer cleaning method according to the present invention. The difference in the thickness of the native oxide film formed on the silicon wafer surface due to cleaning conditions is shown. The difference in the thickness of the thermal oxide film formed by thermal oxidation depending on the cleaning conditions is shown.

Although the present invention will be described in detail below, the present invention is not limited to these.

As described above, there has been a demand for a silicon wafer cleaning method that can control the film thickness of the native oxide film on the silicon wafer within the desired range with good reproducibility and high accuracy while maintaining good particle quality.

In order to solve the above problems, the present inventors diligently studied whether it is possible to vary the thickness of the natural oxide film within a predetermined range and control it with high accuracy for silicon wafers that have been subjected to HF cleaning for improving particle quality. did.

As a result, the present inventors found a method for cleaning a silicon wafer, comprising a first cleaning step of cleaning the silicon wafer with hydrofluoric acid and a second cleaning step of cleaning the silicon wafer cleaned with hydrofluoric acid with ozone water. a cleaning step of cleaning the silicon wafer cleaned with the ozone water with an SC1 cleaning liquid; and a fourth cleaning step of cleaning the silicon wafer cleaned with the SC1 cleaning liquid with the ozone water. By performing both HF cleaning and SC1 cleaning according to the wafer cleaning method, the particle quality can be improved, and by performing the fourth cleaning process, the native oxide film thickness can be controlled with good reproducibility and high accuracy. The present invention has been completed by finding that the cleaning method can be used.

The following description will be made with reference to the drawings.

[Method for cleaning silicon wafer]
FIG. 1 is a flow chart showing an example of a silicon wafer cleaning method according to the present invention. The silicon wafer to be cleaned in the present invention is not particularly limited, and examples thereof include polished silicon wafers, epitaxial wafers, SOI wafers, and the like. In particular, it can be suitably applied to cleaning silicon wafers after polishing to which abrasive grains and the like used for polishing have adhered.

(First washing step)
First, as shown in S1 of FIG. 1, a silicon wafer is cleaned with hydrofluoric acid (HF cleaning). It is preferable that the concentration of HF in the hydrofluoric acid to be used is 0.3 to 3.0% by weight, the temperature is 10 to 30° C., and the washing time is 60 to 360 seconds. As a result, for example, abrasive grains remaining in the polishing process, particles strongly associated with the natural oxide film, and metals in the natural oxide film can be removed together with the natural oxide film. If this first cleaning step (S1) is not performed, the load of SC1 cleaning in the third cleaning step (S3) described later increases, and for example, particles strongly adhered to the native oxide film are difficult to be removed by SC1 cleaning. Particles remain. Hereinafter, the "first cleaning step" may be simply referred to as "S1".

(Second washing step)
Next, cleaning is performed with ozone water as in S2. It is preferable that the ozone water used has an ozone concentration of 3 to 25 ppm, a temperature of 10 to 30° C., and a washing time of 60 to 360 seconds. After the HF cleaning in S1, the surface of the silicon wafer becomes a hydrophobic surface, and particles tend to adhere to it. Therefore, reattachment of particles can be suppressed by forming a natural oxide film on the surface of the silicon wafer in a short time by washing with ozone water to make it a hydrophilic surface. Hereinafter, the "second cleaning step" may be simply referred to as "S2".

It should be noted that it is difficult to vary the thickness of the natural oxide film within the desired range by changing the ozone water cleaning time in the step of S2. If there is an oxide film on the surface, the oxidation of silicon proceeds at the interface between the silicon and the oxide film, so the oxidizing species must diffuse in the oxide film. slows down the progress of oxidation. On the other hand, in the case of a bare surface, since no oxide film exists, oxidation proceeds rapidly. Controlling a rapid reaction lacks practicality from the viewpoint of reproducibility. In order to lower the reactivity, the ozone water concentration can be lowered, but in that case, the oxidation reaction does not occur uniformly within the plane, and the oxide film becomes uneven within the plane. As a result of investigation by the present inventors, it was difficult to change the thickness of the oxide film within a predetermined range by cleaning the bare surface with ozone water. Therefore, it was found that the film thickness of the natural oxide film can be controlled with good reproducibility and high accuracy by performing cleaning with ozone water again (S4) after SC1 cleaning (S3), as will be described later.

(Third washing step)
Next, as in S3, cleaning with the SC1 cleaning liquid is performed. The mixing ratio (volume ratio) of the SC1 cleaning solution is, for example, ammonia water (28% by weight):hydrogen peroxide solution (30% by weight):water 1:1:10, temperature is 30 to 80° C., cleaning time is 90 to 360. Seconds are preferred. In addition, it is better to reduce the etching amount of SC1 within a range in which the particle quality can be sufficiently secured. Hereinafter, the "third cleaning step" may be simply referred to as "S3".

(SC2 washing process)
Further, after SC1 cleaning in S3 and before ozone water cleaning in S4 to be described later, cleaning with SC2 cleaning liquid can be performed. Although metal impurities are removed to some extent by the HF cleaning of S1, SC2 cleaning is effective in further reducing the concentration of metal contaminants, and can be performed as necessary.

(Fourth washing step)
Next, as in S4, the silicon wafer that has been cleaned with the SC1 cleaning liquid in S3 and preferably further SC2 cleaned is cleaned with ozone water. This cleaning with ozone water increases the film thickness of the natural oxide film. Hereinafter, the "fourth cleaning step" may be simply referred to as "S4". In the ozone water cleaning of S4, a natural oxide film is already formed on the surface of the silicon wafer. Therefore, compared with the case where the bare surface is oxidized by washing with ozone water, the progress of oxidation is slowed down, and the film thickness of the natural oxide film can be controlled with good reproducibility and high precision.

In the ozone water cleaning in S4, it is preferable to adjust the thickness of the natural oxide film formed on the surface of the silicon wafer by adjusting the cleaning time. This is because the cleaning time adjustment is the simplest and has the highest controllability and accuracy. At this time, the concentration and temperature can be the same as in S2.

Fig. 2 shows the relationship between the cleaning conditions (cleaning process) and the thickness of the native oxide film formed. Silicon wafer after S1, S2 cleaning (S1→S2) Silicon wafer after S1, S2, S3 cleaning (S1→S2→S3), S1, S2, S3, after S4 cleaning (S1→S2→S3→S4) , and shows the respective natural oxide film thicknesses of silicon wafers that have been subjected to ozone water cleaning for 3 minutes, 12 minutes, and 30 minutes. It can be seen that the thickness of the oxide film formed in S1→S2 is reduced by performing SC1 cleaning in S3. This is because the SC1 cleaning (S3) for improving the particle quality etches the natural oxide film. The subsequent S4 cleaning increases the thickness of the natural oxide film. Moreover, the thickness of the natural oxide film depends on the cleaning time of the ozone water cleaning, and the longer the cleaning time, the thicker the natural oxide film thickness. It is understood that Therefore, by adjusting the cleaning time of S4, it is possible to thicken the natural oxide film thinned by the SC1 cleaning of S3 within a predetermined range.

A plurality of silicon wafers on which a natural oxide film is formed, such as the silicon wafers after cleaning in S1, S2, and S3, are prepared in advance, and are cleaned by changing the ozone water cleaning time in S4. It is also preferable to investigate and determine the correlation with the increasing natural oxide film thickness, and to set the cleaning time of S4 to achieve the desired thickness based on this correlation. By using such a correlation, the cleaning time can be set more easily.

Further, based on the correlation, it is possible to set the cleaning time of the fourth cleaning process so that the natural oxide film has the same thickness as the natural oxide film formed in the second cleaning process of S2. As a result, the thickness of the natural oxide film thinned by etching in the SC1 cleaning (S3) can be made equal to the thickness before the SC1 cleaning.

FIG. 3 shows the oxide film thickness after thermal oxidation with a target thickness of 5.1 nm using a wafer of the same level as the silicon wafer shown in FIG. Comparing the levels, the cleaning levels S1, S2 and S3, which have the thinnest natural oxide film, also have the thinnest thermal oxide film. It can be seen that the thickness of the thermally oxidized film is the thickest at the level of 30 minutes of ozone water cleaning time in S4. Further, from FIG. 3, for example, when the target thickness of the thermal oxide film is 5.09 nm, this can be achieved by setting the ozone cleaning time in S4 to 3 minutes. Further, for example, if the cleaning time of S4 is set to 12 minutes in order to improve the electrical characteristics of the oxide film, the natural oxide film thickness (FIG. 2) can be obtained equivalent to that of the cleaning levels of S1 and S2. As a result, the thickness of the thermal oxide film (FIG. 3) can be the same as that of the cleaning levels S1 and S2. Thus, by using the cleaning method of the present invention, the thickness of the native oxide film can be controlled within a predetermined range with high accuracy.

[Manufacturing method of silicon wafer with native oxide film]
By the method for cleaning a silicon wafer according to the present invention as described above, it is possible to manufacture a silicon wafer with a natural oxide film having a desired natural oxide film thickness, a low particle level and a good quality natural oxide film formed thereon. can.

The present invention will be specifically described below with reference to examples and comparative examples, but these are not intended to limit the present invention.

(Example)
A polished silicon wafer was prepared. The prepared silicon wafer was subjected to HF cleaning (S1), then ozone water cleaning (S2), further SC1 cleaning (S3), and finally ozone water cleaning (S4) (Examples 1 and 3). , 5, 7). Further, standards (Examples 2, 4, 6, and 8) were also prepared in which the SC2 cleaning was performed after the SC1 cleaning in S3, and then the ozone water cleaning in S4 was performed.

The HF cleaning of S1 had an HF concentration of 0.5% by weight and a cleaning time of 3 minutes. In the ozone cleaning of S2, the ozone concentration was 20 ppm and the cleaning time was 3 minutes. The SC1 cleaning of S3 was performed using a mixture of ammonia water (28% by weight):hydrogen peroxide solution (30% by weight):water at a ratio of 1:1:10, a liquid temperature of 70° C., and cleaning time of 3 minutes. SC2 cleaning was performed using a mixture of hydrochloric acid:hydrogen peroxide:water of 1:1:100, and cleaning time was 3 minutes. In the ozone cleaning of S4, the ozone concentration was 20 ppm and the cleaning time was 3, 6, 12 and 30 minutes. The quality of particles on the surface of the wafer after cleaning was evaluated with a particle size of 19 nm or more using a particle counter SP5 manufactured by KLA, and the thickness of the natural oxide film was measured according to J. Phys. A. It was evaluated with a spectroscopic ellipsometry M-2000V manufactured by Woollam.

Table 1 shows the wafer cleaning conditions, the natural oxide film thickness, and the number of particles in the example.

First, when comparing the effects of the presence or absence of SC2, as is clear from the comparison of Examples 1 and 2, Examples 3 and 4, Examples 5 and 6, and Examples 7 and 8, the particle quality and the quality of the natural oxide film are compared. (natural oxide film thickness) were the same. Therefore, SC2 cleaning does not affect the quality of particles and the quality of the native oxide film, so it can be seen that SC2 cleaning can be performed when it is desired to further reduce the metal concentration on the surface of the silicon wafer.

Regarding the particle quality, the number of particles detected was 15 to 23 pcs, which was good compared to 72 pcs of the level without HF cleaning (Comparative Example 1), which will be described later. It is considered that the particle quality became good by performing both the HF cleaning of S1 and the SC1 cleaning of S3. The longer the ozone cleaning time in S4 is, the thicker the natural oxide film becomes.

In addition, the amount of thickening of the natural oxide film by changing the ozone water cleaning time in S4 from 3 minutes (Examples 1 and 2) to 12 minutes (Examples 5 and 6) is 1.199-1.128=0.072 nm, and from Examples 2 and 6, 1.203-1.129=0.074 nm.

(Comparative example 1)
In Comparative Example 1, the silicon wafer after polishing was prepared in the same manner as in Example, and after SC1 and SC2 cleanings were performed, ozone water cleaning was performed. SC1 and SC2 were performed under the same conditions as in the example, and the cleaning with ozone water was performed at a concentration of 20 ppm for 3 minutes under the same conditions as in S2 of the example. As in the example, the particle quality of the wafer after cleaning was evaluated with a particle counter, and the natural oxide film thickness was evaluated with spectroscopic ellipsometry.

Table 2 shows the wafer cleaning conditions, the natural oxide film thickness, and the number of particles in the comparative example.

As shown in Table 2, the particle quality in Comparative Example 1 was 72 pcs, which was higher than in Examples 1-8. This is because in Comparative Example 1, only SC1 cleaning was performed without HF cleaning. The thickness of the natural oxide film was the same as in Examples 1 and 2. This is because the ozone water cleaning time is the same as S4 in the first and second embodiments.

(Comparative Examples 2 and 3)
In Comparative Examples 2 and 3, the prepared silicon wafer was subjected to HF cleaning (S1), then ozone water cleaning (S2) for 3 minutes (Comparative Example 2) and 12 minutes (Comparative Example 3), and SC1 cleaning (S3). and SC2 washes. HF cleaning, SC1 cleaning, and SC2 cleaning are the same conditions as in the example. As a result, as shown in Table 2, the particle quality of the resulting natural oxide film was equivalent to that of the example. On the other hand, the thickness of the natural oxide film was 1.022 nm in Comparative Example 2 in which the ozone cleaning time of S2 was 3 minutes, and 1.034 nm in Comparative Example 3 in which the ozone cleaning time was 12 minutes. .022=0.012 nm) was much smaller than the thickening amounts (0.072 nm, 0.074 nm) obtained in Examples 1 and 5 and Examples 2 and 6 described above. Therefore, the methods of Comparative Examples 2 and 3 cannot appropriately control the thickness of the natural oxide film.

(Comparative Examples 4 and 5)
In Comparative Examples 4 and 5, after the silicon wafer was SC1 cleaned, HF cleaning was performed, and ozone water cleaning was performed for 3 minutes (Comparative Example 4) and 12 minutes (Comparative Example 5). SC1 cleaning and HF cleaning are performed under the same conditions as in the example. As shown in Table 2, the particle quality was 25 pcs in Comparative Example 4 and 21 pcs in Comparative Example 5, which were equivalent to those of the example. On the other hand, the natural oxide film thickness was 1.201 nm in Comparative Example 4 in which the ozone cleaning time was 3 minutes, and 1.213 nm in Comparative Example 5 in which the ozone cleaning time was 12 minutes. = 0.012 nm) was much smaller than the thickening amounts (0.072 nm, 0.074 nm) obtained in Examples 1 and 5 and Examples 2 and 6 described above. Therefore, the methods of Comparative Examples 4 and 5 cannot appropriately control the thickness of the natural oxide film.

As described above, according to the embodiment of the present invention, it was found that the natural oxide film thickness can be controlled with high reproducibility and high accuracy while improving the quality of the particles.

The present invention is not limited to the above embodiments. The above-described embodiment is an example, and any device having substantially the same configuration as the technical idea described in the claims of the present invention and exhibiting the same effect is the present invention. included in the technical scope of

Claims

A method for cleaning a silicon wafer,
a first cleaning step of cleaning the silicon wafer with hydrofluoric acid;
a second cleaning step of cleaning the silicon wafer cleaned with the hydrofluoric acid with ozone water;
a third cleaning step of cleaning the silicon wafer cleaned with the ozone water with an SC1 cleaning liquid;
and a fourth cleaning step of cleaning the silicon wafer, which has been cleaned with the SC1 cleaning liquid, with ozone water.
3. The method of cleaning a silicon wafer according to claim 1, wherein the thickness of the natural oxide film formed on the surface of the silicon wafer is controlled by adjusting the cleaning time of the fourth cleaning step.
A correlation between the time for cleaning a silicon wafer having a natural oxide film formed thereon with ozone water and the natural oxide film thickness increased by cleaning the silicon wafer having a natural oxide film formed thereon with ozone water is obtained in advance. 3. The method of cleaning a silicon wafer according to claim 2, wherein the cleaning time of said fourth cleaning step is set based on said correlation.
Based on the correlation, setting the cleaning time of the fourth cleaning step so that the thickness of the natural oxide film formed on the surface of the silicon wafer in the second cleaning step is equal to the thickness of the native oxide film. The method for cleaning a silicon wafer according to claim 3, characterized by:
5. The silicon wafer according to any one of claims 1 to 4, further comprising an SC2 cleaning step of cleaning the silicon wafer with an SC2 cleaning solution after the third cleaning step and before the fourth cleaning step. cleaning method.
A method for manufacturing a silicon wafer with a native oxide film,
A method for producing a silicon wafer with a native oxide film, comprising producing a silicon wafer with a native oxide film by the method for cleaning a silicon wafer according to any one of claims 1 to 5.