JP2742247B2 - Manufacturing method and quality control method for silicon single crystal substrate - Google Patents

Manufacturing method and quality control method for silicon single crystal substrate

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Publication number
JP2742247B2
JP2742247B2 JP7127091A JP12709195A JP2742247B2 JP 2742247 B2 JP2742247 B2 JP 2742247B2 JP 7127091 A JP7127091 A JP 7127091A JP 12709195 A JP12709195 A JP 12709195A JP 2742247 B2 JP2742247 B2 JP 2742247B2
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Japan
Prior art keywords
single crystal
resistivity
heat treatment
silicon single
nitrogen
Prior art date
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JP7127091A
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Japanese (ja)
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JPH0891993A (en
Inventor
雅規 木村
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Shin Etsu Handotai Co Ltd
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Shin Etsu Handotai Co Ltd
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Description

【発明の詳細な説明】DETAILED DESCRIPTION OF THE INVENTION

【0001】[0001]

【産業上の利用分野】本発明は、窒素を添加したシリコ
ン単結晶基板の製造方法および品質管理方法に関するも
のである。
BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for manufacturing a silicon single crystal substrate to which nitrogen is added and a quality control method.

【0002】[0002]

【従来の技術】シリコン単結晶基板(以下シリコン基板
という。)の製造またはこれを使用する半導体素子製造
においては、シリコン基板は600℃から1250℃の
広範囲の温度範囲で熱処理を受ける。例えば前者におけ
るものとしては、ドナー消去のための約650℃、30
分間の熱処理があり、後者におけるものとしては、酸化
工程、イントリンシックゲッタリングあるいは拡散のた
めの約1200℃の熱処理などがある。
2. Description of the Related Art In manufacturing a silicon single crystal substrate (hereinafter referred to as a silicon substrate) or a semiconductor device using the same, the silicon substrate is subjected to a heat treatment in a wide temperature range from 600 ° C. to 1250 ° C. For example, in the former, about 650 ° C. and 30
Heat treatment of about 1200 ° C. for the latter, such as an oxidation step, intrinsic gettering or diffusion.

【0003】一方、特に高温領域における熱処理におい
て、その際にシリコン基板内に発生する熱応力による結
晶欠陥の発生を防止する目的で、例えば特開昭57−1
7497号に示されているように、シリコン単結晶中に
窒素を添加することが提案されている。
On the other hand, in order to prevent generation of crystal defects due to thermal stress generated in a silicon substrate at the time of heat treatment especially in a high temperature region, Japanese Patent Application Laid-Open No.
No. 7,497, it has been proposed to add nitrogen to a silicon single crystal.

【0004】[0004]

【発明が解決しようとする課題】ところが、窒素が添加
されたシリコン基板に対し熱処理を施すと、窒素を添加
していないシリコン基板と異なり、その抵抗率が実測値
において、熱処理前後で10%以上変化してしまう場合
があり、窒素が添加されたシリコン基板の抵抗率を保証
することが困難であった。
However, when heat treatment is performed on a silicon substrate to which nitrogen is added, unlike a silicon substrate to which nitrogen is not added, the measured resistivity is 10% or more before and after the heat treatment. In some cases, it has been difficult to guarantee the resistivity of the silicon substrate to which nitrogen has been added.

【0005】本発明は、かかる点に鑑みなされたもので
あり、半導体素子製造工程中のいかなる熱処理によって
も安定した抵抗率を示す、窒素が添加されたシリコン基
板の製造方法および品質管理方法を提供することを目的
としている。
The present invention has been made in view of the above points, and provides a method of manufacturing a nitrogen-doped silicon substrate and a method of controlling the quality thereof, which exhibit a stable resistivity by any heat treatment during a semiconductor device manufacturing process. It is intended to be.

【0006】[0006]

【課題を解決するための手段】請求項1記載のシリコン
単結晶基板の製造方法は、シリコン単結晶の育成中に窒
素を添加する工程と、前記シリコン単結晶を切断する工
程と、切断されたシリコン単結晶基板を、少なくとも半
導体素子製造工程前に900℃〜1250℃の間のいず
れかの温度で保持して約10分〜1時間加熱することに
より、半導体素子製造工程前に、シリコン単結晶基板の
抵抗率を単結晶育成直後の値に回復させる工程とを有す
ることを特徴とする。
A method for manufacturing a silicon single crystal substrate according to claim 1 includes a step of adding nitrogen during the growth of the silicon single crystal, a step of cutting the silicon single crystal, and a step of cutting the silicon single crystal. By heating the silicon single crystal substrate at least at any temperature between 900 ° C. and 1250 ° C. for at least 10 minutes to 1 hour before the semiconductor device manufacturing process, the silicon single crystal substrate can be manufactured before the semiconductor device manufacturing process. Recovering the resistivity of the substrate to a value immediately after growing the single crystal.

【0007】請求項2記載のシリコン単結晶基板の製造
方法は、請求項1記載のシリコン単結晶基板の製造方法
において、添加される前記窒素の濃度は、3×1014at
oms/cm3以上であることを特徴とする。
According to a second aspect of the present invention, in the method of manufacturing a silicon single crystal substrate according to the first aspect, the concentration of the nitrogen added is 3 × 10 14 at.
oms / cm 3 or more.

【0008】請求項3記載のシリコン単結晶基板の製造
方法は、請求項1又は請求項2記載のシリコン単結晶基
板の製造方法において、前記シリコン単結晶の育成は、
FZ法で行うことを特徴とする。
According to a third aspect of the present invention, there is provided a method of manufacturing a silicon single crystal substrate according to the first or second aspect, wherein the growing of the silicon single crystal comprises:
It is characterized by performing by the FZ method.

【0009】請求項4記載のシリコン単結晶基板の製造
方法は、請求項1〜3いずれか記載のシリコン単結晶基
板の製造方法において、前記熱処理は、ウェット酸素雰
囲気、ドライ酸素雰囲気又は窒素雰囲気のいずれか1つ
で行われることを特徴とする。
According to a fourth aspect of the present invention, in the method of manufacturing a silicon single crystal substrate according to any one of the first to third aspects, the heat treatment is performed in a wet oxygen atmosphere, a dry oxygen atmosphere, or a nitrogen atmosphere. It is characterized by being performed in any one of them.

【0010】請求項5記載のシリコン基板の品質管理方
法は、単結晶の育成中に窒素が添加されたシリコン単結
晶基板について、半導体素子製造工程前に900℃〜1
250℃の間のいずれかの温度で保持して約10分〜1
時間加熱することにより、抵抗率が単結晶育成直後の値
に回復した基板の抵抗率を測定することを特徴とする。
According to a fifth aspect of the present invention, there is provided a method for controlling the quality of a silicon substrate, the method comprising the steps of:
Hold at any temperature between 250 ° C for about 10 minutes to 1
It is characterized by measuring the resistivity of the substrate whose resistivity has been restored to a value immediately after the single crystal growth by heating for a time.

【0011】[0011]

【作用】本発明によれば、前記窒素が添加されたシリコ
ン基板の抵抗率を単結晶育成直後の値にほぼ一致させる
ことができ、また、その後の熱処理で抵抗率が変化しな
くなる。さらにまた、本発明に係る熱処理をウェット酸
素雰囲気中で行うと、抵抗率が容易に単結晶育成直後の
値に回復する。したがって、本発明に係る製造方法や抵
抗率の測定方法によると、窒素が添加されたシリコン基
板から高収率をもって半導体素子を製造することができ
る。特に、シリコン単結晶の育成中に添加された窒素の
濃度が3×1014atoms/cm3以上のものの場合には、そ
の効果が高い。
According to the present invention, the resistivity of the silicon substrate to which nitrogen has been added can be made substantially equal to the value immediately after the single crystal is grown, and the resistivity does not change during the subsequent heat treatment. Furthermore, when the heat treatment according to the present invention is performed in a wet oxygen atmosphere, the resistivity easily recovers to the value immediately after the single crystal is grown. Therefore, according to the manufacturing method and the resistivity measuring method according to the present invention, a semiconductor element can be manufactured with high yield from a silicon substrate to which nitrogen is added. In particular, when the concentration of nitrogen added during the growth of the silicon single crystal is 3 × 10 14 atoms / cm 3 or more, the effect is high.

【0012】熱処理の温度が900℃以下の場合には、
冷却後の抵抗率を単結晶育成直後の値に一致させるため
に、熱処理時間が1時間以上必要となるので、工業的と
はいえない。一方、熱処理の温度が1250℃以上の場
合には、シリコン基板中に窒素が添加されているにもか
かわらず、加熱冷却時に熱応力による結晶欠陥が発生す
る可能性が高くなる。また、昇温速度は、例えば毎分1
℃〜10℃が用いられるが、熱処理を受けるシリコン基
板が破壊されたり、あるいは結晶性が劣化したりしない
限り自由に選ぶことができる。
When the temperature of the heat treatment is 900 ° C. or less,
In order to make the resistivity after cooling equal to the value immediately after the growth of the single crystal, a heat treatment time of one hour or more is required, so it is not industrial. On the other hand, when the temperature of the heat treatment is 1250 ° C. or higher, there is a high possibility that crystal defects due to thermal stress will occur during heating and cooling, even though nitrogen is added to the silicon substrate. Further, the heating rate is, for example, 1
C. to 10.degree. C. is used, but can be freely selected as long as the silicon substrate subjected to the heat treatment is not broken or crystallinity is deteriorated.

【0013】[0013]

【実施例】以下、本発明に係るシリコン単結晶基板の製
造方法および品質管理方法を説明する。
DESCRIPTION OF THE PREFERRED EMBODIMENTS A method for manufacturing a silicon single crystal substrate and a quality control method according to the present invention will be described below.

【0014】先ず、シリコン基板の製造方法の一例を図
1を用いて説明する。アルゴンガス又はまれに用いられ
るアルゴンと水素の混合ガスに窒素ガス又は窒素を含む
化合物を添加した雰囲気ガス中で、単結晶中に窒素を添
加しながらシリコン単結晶を育成する。この際のシリコ
ン単結晶の育成は、例えば、浮遊帯域溶融法(FZ法)
によって行われる。次に、このシリコン単結晶を所定の
厚さにスライスしさらに機械研磨して得られたシリコン
基板を、周辺部の面取りをした後にエッチング処理して
表面の破砕層を除去する。続いて、前記シリコン基板の
裏面側にサンドブラスト処理を施して加工歪層を付与す
る。この工程の後で、本発明に係る熱処理を施して室温
まで冷却する。そして、最後に前記シリコン基板の主表
面側を鏡面研磨する。次に、本発明に係る熱処理をその
条件を変えて行い、本発明の目的に最も適した条件を探
し求めた。
First, an example of a method for manufacturing a silicon substrate will be described with reference to FIG. A silicon single crystal is grown while adding nitrogen to the single crystal in an atmosphere gas in which nitrogen gas or a compound containing nitrogen is added to argon gas or a rarely used mixed gas of argon and hydrogen. At this time, the silicon single crystal is grown, for example, by a floating zone melting method (FZ method).
Done by Next, the silicon substrate obtained by slicing the silicon single crystal into a predetermined thickness and further mechanically polishing the silicon substrate is chamfered at its peripheral portion and then subjected to an etching treatment to remove a crushed layer on the surface. Subsequently, sandblasting is performed on the back surface side of the silicon substrate to provide a work strain layer. After this step, the heat treatment according to the present invention is performed and the temperature is cooled to room temperature. Finally, the main surface side of the silicon substrate is mirror-polished. Next, the heat treatment according to the present invention was performed under different conditions, and conditions most suitable for the purpose of the present invention were searched for.

【0015】[実験1]先ず、単結晶の育成中に窒素を
添加して得られたシリコン基板に対して650℃で20
分間の熱処理を行った。また、この熱処理にあたって、
熱処理雰囲気を変えてみた。具体的な条件及び結果は下
記のとおりである。
[Experiment 1] First, a silicon substrate obtained by adding nitrogen during the growth of a single crystal was heated at 650 ° C. for 20 minutes.
Heat treatment for a minute. In this heat treatment,
I changed the heat treatment atmosphere. The specific conditions and results are as follows.

【0016】1.条件 サンプル基板のために、FZ法で単結晶育成中に窒素が
添加された直径76mm、n型、{111}の単結晶を
用いた。また、基板の抵抗率ならびに基板中の窒素濃度
の影響を調査するために、表3に示す8種類の基板を準
備した。また、別のサンプル基板として、p型である以
外は表1と同じ分類で準備された表2に示す基板を用い
た。
1. Conditions For a sample substrate, an n-type, {111} single crystal having a diameter of 76 mm to which nitrogen was added during single crystal growth by the FZ method was used. In addition, eight types of substrates shown in Table 3 were prepared in order to investigate the effects of the substrate resistivity and the nitrogen concentration in the substrate. Further, as another sample substrate, a substrate shown in Table 2 prepared in the same classification as Table 1 except that it was of p-type was used.

【0017】[0017]

【表1】 [Table 1]

【0018】[0018]

【表2】 [Table 2]

【0019】表1および表2に示したように種類が異な
るシリコン基板について、熱処理を行う雰囲気は、窒素
(N2)、ウェット酸素(ウェットO2)、アルゴン
(Ar)の3条件である。そして、シリコン基板を室温
まで冷却した後、熱処理前の抵抗率と熱処理後の抵抗率
とを比べてみた。
As shown in Tables 1 and 2, for the silicon substrates of different types, the heat treatment is performed under three conditions of nitrogen (N2), wet oxygen (wet O2), and argon (Ar). Then, after cooling the silicon substrate to room temperature, the resistivity before the heat treatment was compared with the resistivity after the heat treatment.

【0020】2.結果 その結果が図2(A),(B)及び図3(A),(B)
に示されている。ここで、図2(A)はn型シリコン基
板についての抵抗率変化を、また、図3(A)はp型シ
リコン基板についての抵抗率変化を示している。図2
(A)及び図3(A)からは、650℃の熱処理を行う
とその前後で抵抗率が著しく変化することが分かる。ま
た、650℃の熱処理では熱処理雰囲気を変えても抵抗
率の変化にはあまり影響がないことが分かる。さらに、
p型シリコン基板とn型シリコン基板とを比べた場合、
p型の方が抵抗率変化の割合が大きいことが分かる。な
お、抵抗率が500Ω・cmのp型シリコン基板をウェ
ット酸素雰囲気中で熱処理した場合、抵抗率変化は他の
熱処理雰囲気に比べて小さいことが分かる。
2. Results The results are shown in FIGS. 2 (A) and 2 (B) and FIGS. 3 (A) and 3 (B).
Is shown in Here, FIG. 2A shows a change in resistivity for an n-type silicon substrate, and FIG. 3A shows a change in resistivity for a p-type silicon substrate. FIG.
From FIG. 3A and FIG. 3A, it can be seen that the resistivity changes significantly before and after the heat treatment at 650 ° C. Further, it can be seen that in the heat treatment at 650 ° C., even if the heat treatment atmosphere is changed, the change in the resistivity is not so affected. further,
When comparing a p-type silicon substrate and an n-type silicon substrate,
It can be seen that the p-type has a higher rate of change in resistivity. Note that when a p-type silicon substrate having a resistivity of 500 Ω · cm is heat-treated in a wet oxygen atmosphere, the change in resistivity is smaller than in other heat treatment atmospheres.

【0021】また、図2(B)及び図3(B)はAST
M換算式(F723−82)を用いて、上記抵抗率変化
をキャリヤー濃度変化に直したものである。このように
キャリヤー濃度変化に換算すると、一部の例外を除い
て、窒素濃度が高い程キャリヤー濃度変化が大きいとい
って良い。なお、抵抗率変化の割合についてp型シリコ
ン基板とn型シリコン基板とを比べた場合、p型の方が
1桁大きいことが分かる。
FIGS. 2B and 3B show AST.
The change in the resistivity is converted into a change in the carrier concentration using the M conversion formula (F723-82). When converted into a change in carrier concentration in this way, with some exceptions, it can be said that the higher the nitrogen concentration, the greater the change in carrier concentration. It should be noted that when the p-type silicon substrate and the n-type silicon substrate are compared with respect to the rate of change in resistivity, it is found that the p-type silicon substrate is one digit larger.

【0022】[実験2]この実験では、単結晶育成中に
窒素を添加して得られたシリコン基板を窒素雰囲気中で
熱処理し、その時に温度と時間を変化させながら変えて
実験を行った。この実験の条件及び結果は下記のとおり
である。
[Experiment 2] In this experiment, a silicon substrate obtained by adding nitrogen during the growth of a single crystal was subjected to a heat treatment in a nitrogen atmosphere, and the temperature and time were changed while changing the temperature. The conditions and results of this experiment are as follows.

【0023】1.条件 窒素雰囲気中で熱処理温度を700℃、900℃及び1
000℃に設定し、そのそれぞれについて1分、4分、
8分、20分、60分、120分熱処理し、その後に室
温まで冷却して抵抗率を調べてみた。さらに1200
℃、8分のみの熱処理実験を追加した。本実験には、直
径76mm、面方位{100}、単結晶育成直後の抵抗
率が150Ω・cmのp型シリコン基板を用いた。ま
た、クーリング時間、つまり熱処理後室温(24乃至2
5℃)まで冷却する時間を15秒とした。
1. Conditions Heat treatment temperature in nitrogen atmosphere at 700 ° C, 900 ° C and 1
Set at 000 ° C. for 1 minute, 4 minutes,
Heat treatment was performed for 8 minutes, 20 minutes, 60 minutes, and 120 minutes, and then, the temperature was lowered to room temperature, and the resistivity was examined. Further 1200
A heat treatment experiment at 8 ° C. for only 8 minutes was added. In this experiment, a p-type silicon substrate having a diameter of 76 mm, a plane orientation of {100}, and a resistivity immediately after growing a single crystal was 150 Ω · cm was used. The cooling time, that is, the room temperature after the heat treatment (24 to 2
(5 ° C.) for 15 seconds.

【0024】2.結果 この結果が図4に示されている。この図からは、熱処理
の初期において、一旦抵抗率が大きく上昇するが、さら
に熱処理を継続すると、単結晶育成直後の値まで徐々に
抵抗率が下がってゆく傾向が見られる。例えば、100
0℃で熱処理する場合、約10分間で単結晶育成直後の
抵抗率である150Ω・cmにほぼ回復している。ま
た、1000℃より温度を高くすると、単結晶育成直後
の状態の抵抗率までに回復する時間が少なくてすむこと
が分かる。一方、1000℃より温度を低くすると、単
結晶育成直後の抵抗率まで回復するまでの時間が長くな
ることが分かる。
2. Results The results are shown in FIG. From this figure, it can be seen that the resistivity once increases significantly at the beginning of the heat treatment, but when the heat treatment is further continued, the resistivity tends to gradually decrease to the value immediately after the single crystal growth. For example, 100
When the heat treatment is performed at 0 ° C., the resistivity is almost recovered to 150 Ω · cm, which is the resistivity immediately after growing the single crystal, in about 10 minutes. Also, it can be seen that when the temperature is higher than 1000 ° C., the time required to recover to the resistivity immediately after the single crystal growth is reduced. On the other hand, when the temperature is lower than 1000 ° C., it can be seen that the time required to recover to the resistivity immediately after the growth of the single crystal becomes longer.

【0025】[実験3]次の実験では、単結晶育成中に
窒素を添加して得られたシリコン基板を熱処理する際
に、さまざまな雰囲気中で熱処理を行い、その熱処理前
後における抵抗率変化の割合を比較した。具体的な条件
及び結果は下記のとおりである。
[Experiment 3] In the next experiment, when heat-treating a silicon substrate obtained by adding nitrogen during single crystal growth, heat treatment was performed in various atmospheres, and the change in resistivity before and after the heat treatment was measured. The proportions were compared. The specific conditions and results are as follows.

【0026】1.条件 サンプル基板として、FZ法で単結晶育成中に窒素が添
加された直径76mm、p型、{111}の単結晶を用
いた。また、基板の抵抗率ならびに基板中の窒素濃度の
影響を調査するために、表3に示す8種類の基板を準備
した。
1. Conditions As a sample substrate, a p-type, {111} single crystal with a diameter of 76 mm to which nitrogen was added during single crystal growth by the FZ method was used. In addition, eight types of substrates shown in Table 3 were prepared in order to investigate the effects of the substrate resistivity and the nitrogen concentration in the substrate.

【0027】[0027]

【表3】 [Table 3]

【0028】上記のような各種サンプルについてその熱
処理をウェット酸素(ウェットO2)、ドライ酸素(ド
ライO2 )、窒素(N2 )の3種類の雰囲気中で行っ
た。なお、熱処理温度は1000℃、熱処理時間は20
分に設定した。ウェット酸素での熱処理はスチーム酸化
炉で行った。
The above samples were heat-treated in three kinds of atmospheres of wet oxygen (wet O 2 ), dry oxygen (dry O 2 ), and nitrogen (N 2 ). The heat treatment temperature is 1000 ° C. and the heat treatment time is 20
Set to minutes. The heat treatment with wet oxygen was performed in a steam oxidation furnace.

【0029】2.結果 その結果が図5(A),(B)に示されている。ここ
で、図5(A)は縦軸に抵抗率変化を、また、図5
(B)は図5(A)の抵抗率変化をASTM法(F72
3−82)によってキャリヤー濃度変化に換算したもの
を示している。ここで、抵抗率又はキャリヤー濃度の変
化率が小さいということは、一旦高くなった抵抗率が単
結晶育成直後の値の近傍まで回復したことを意味する。
一方、変化率が大きいということは、抵抗率がまだ回復
途上にあることを意味する。これらの図面より、ウェッ
ト酸素雰囲気中においては、誤差(±0.3〜±0.5
%)も考慮すれば、ほぼ単結晶育成直後の値に抵抗率が
回復していることが分かる。なおドライ酸素雰囲気は、
ウェット酸素雰囲気よりも抵抗率の変化が大きいが、熱
処理時間をウェット酸素雰囲気よりも少し長くとれば、
単結晶育成直後の値に抵抗率が回復することがその後の
実験で確認された。
2. Results The results are shown in FIGS. 5 (A) and (B). Here, FIG. 5A shows the resistivity change on the vertical axis, and FIG.
FIG. 5B shows the change in resistivity in FIG.
3-82) shows the result of conversion into carrier concentration change. Here, that the rate of change of the resistivity or the carrier concentration is small means that the resistivity once increased has recovered to a value close to the value immediately after the growth of the single crystal.
On the other hand, a large change rate means that the resistivity is still recovering. From these figures, it can be seen that the error (± 0.3 to ± 0.5
%), It is understood that the resistivity has recovered to a value almost immediately after the single crystal growth. The dry oxygen atmosphere is
Although the change in resistivity is greater than in a wet oxygen atmosphere, if the heat treatment time is slightly longer than in a wet oxygen atmosphere,
It was confirmed in subsequent experiments that the resistivity was restored to the value immediately after the single crystal was grown.

【0030】次に、上記実験結果に対する原理的考察を
加える。図6に抵抗率の回復過程を概説した。単結晶育
成中に窒素を添加して得られたシリコン単結晶内には、
空孔と窒素分子との複合体が形成されている。前記複合
体を有する結晶に熱処理を施すと、深い準位が形成され
るので、キャリヤーがトラップされやすくなり、その結
果、抵抗率が上昇する。ところが、さらに熱処理を加え
ると、空孔の外方拡散及び/又は格子間のSiの内方拡
散により、一旦形成された深い準位は消滅し、抵抗率が
単結晶育成直後の値まで回復するのである。
Next, a theoretical consideration for the above experimental results will be added. FIG. 6 outlines the recovery process of the resistivity. In a silicon single crystal obtained by adding nitrogen during single crystal growth,
A complex of vacancies and nitrogen molecules is formed. When the crystal having the composite is subjected to heat treatment, a deep level is formed, so that the carrier is easily trapped, and as a result, the resistivity increases. However, when heat treatment is further applied, the deep level once formed disappears due to the outward diffusion of vacancies and / or the inward diffusion of Si between lattices, and the resistivity recovers to the value immediately after the single crystal growth. It is.

【0031】酸素雰囲気中で熱処理すると、シリコン基
板の表面にSiO2 膜が形成されて余分なSiが内方拡
散されるので、空孔が消滅すると同時に深い準位が消滅
する。
When heat treatment is performed in an oxygen atmosphere, a SiO 2 film is formed on the surface of the silicon substrate, and excess Si is diffused inward, so that vacancies disappear and deep levels disappear.

【0032】ウェット酸素とドライ酸素とを比較した場
合にウェット酸素雰囲気の抵抗率変化が小さいのは、ウ
ェットO2 雰囲気の方がSiO2 膜の形成速度が速いの
でSiの内方拡散も早く行われるようになり、その結
果、同じ熱処理温度及び熱処理時間での抵抗率の回復の
割合が大きくなるからである。
The reason why the change in resistivity in the wet oxygen atmosphere is small when wet oxygen and dry oxygen are compared is that the inward diffusion of Si is performed quickly because the formation rate of the SiO 2 film is higher in the wet O 2 atmosphere. This is because, as a result, the rate of recovery of the resistivity at the same heat treatment temperature and heat treatment time increases.

【0033】また、N2 雰囲気の場合には、格子間のS
iの内方拡散のみならず、空孔の外方拡散の影響も大き
いものと推測される。
In the case of an N 2 atmosphere, S
It is presumed that the influence of not only the inward diffusion of i but also the outward diffusion of holes is large.

【0034】なお、実験3において、窒素雰囲気の場合
に、酸素雰囲気に比べて抵抗率変化が大きかったのは、
クーリング時間が長かったことに起因していると思われ
る。つまり、実験3では、クーリング時間を15分程度
としたので、一旦深い準位が消滅したにも拘らず、冷却
中にN2 が内方拡散され、それによって抵抗率変化が再
び生じたのである。したがって、窒素雰囲気の場合には
深い準位の消滅後直ちに冷却することが必要となる。
In Experiment 3, the change in resistivity in a nitrogen atmosphere was larger than that in an oxygen atmosphere because:
This is probably due to the long cooling time. That is, in Experiment 3, since the cooling time was set to about 15 minutes, N 2 was diffused inward during cooling, even though the deep level disappeared, thereby causing a change in resistivity again. . Therefore, in the case of a nitrogen atmosphere, it is necessary to cool immediately after the disappearance of the deep level.

【0035】[実験4]次の実験では、本発明に係る条
件で第1の熱処理をしたシリコン基板を更に種々の条件
で第2の熱処理を行い、熱処理前後の抵抗率変化の程度
を調べた。
[Experiment 4] In the next experiment, the silicon substrate subjected to the first heat treatment under the conditions according to the present invention was further subjected to the second heat treatment under various conditions, and the degree of change in resistivity before and after the heat treatment was examined. .

【0036】1.条件 サンプル基板としては、FZ法で育成中に表4に示す濃
度の窒素が添加された面方位{100}、単結晶育成直
後の抵抗率が150Ω・cmのn型およびp型シリコン
基板を準備し、サンプル1とサンプル2の熱処理を行っ
た。
1. Conditions As sample substrates, n-type and p-type silicon substrates having a plane orientation of {100} to which nitrogen having the concentration shown in Table 4 was added during growth by the FZ method and a resistivity of 150 Ω · cm immediately after growing a single crystal were prepared. Then, the heat treatment of Sample 1 and Sample 2 was performed.

【0037】[0037]

【表4】 [Table 4]

【0038】第1の熱処理は、ウェット酸素中でサンプ
ル1を1200℃60分、サンプル2を1000℃60
分行った。続いて、700℃20分、800℃60分お
よび1100℃60分の3条件で第2の熱処理を行い、
その前後での抵抗率を比較した。
In the first heat treatment, sample 1 was heated at 1200 ° C. for 60 minutes in wet oxygen and sample 2 was heated at 1000 ° C. for 60 minutes.
Minutes went. Subsequently, a second heat treatment is performed under three conditions of 700 ° C. for 20 minutes, 800 ° C. for 60 minutes, and 1100 ° C. for 60 minutes.
The resistivity before and after that was compared.

【0039】2.結果 その結果、第2の熱処理による抵抗率の変化はいずれも
1%以下で無視できる範囲に収まった。つまり、本発明
に係る第1の熱処理は、窒素の添加されたシリコン基板
に施すと、該シリコン基板の抵抗率を単結晶育成直後の
値に回復させ、さらにその値を実質的に一定にするの
で、前記シリコン基板の抵抗率を測定する際に有効であ
る。
2. Results As a result, the change in resistivity due to the second heat treatment was 1% or less and was within a negligible range. That is, when the first heat treatment according to the present invention is performed on a silicon substrate to which nitrogen is added, the resistivity of the silicon substrate is restored to a value immediately after the single crystal is grown, and the value is made substantially constant. Therefore, it is effective when measuring the resistivity of the silicon substrate.

【0040】以上本発明者によってなされた発明を実施
例に基づき具体的に説明したが、本発明は上記実施例に
限定されるものではなく、その要旨を逸脱しない範囲で
種々変更可能であることはいうまでもない。
Although the invention made by the present inventor has been specifically described based on the embodiments, the present invention is not limited to the above-described embodiments, and may be variously modified without departing from the gist thereof. Needless to say.

【0041】上記実施例では、実験2,3で抵抗率変化
の大きいp型シリコン基板について評価を行なったが、
抵抗率変化の小さいn型シリコン基板にも効果があるこ
とは勿論である。
In the above embodiment, the p-type silicon substrate having a large change in resistivity was evaluated in Experiments 2 and 3.
It is needless to say that the present invention is also effective for an n-type silicon substrate having a small change in resistivity.

【0042】また、上記実施例では、FZ法によって得
られたシリコン基板について説明したが、チョクラルス
キー法(CZ法)によって得られるシリコン基板にも適
応できることは勿論である。
In the above embodiment, the silicon substrate obtained by the FZ method has been described. However, it is needless to say that the present invention can be applied to a silicon substrate obtained by the Czochralski method (CZ method).

【0043】さらに、上記実施例では、サンドブラスト
処理されたシリコン基板について説明してきたが、抵抗
率の安定化は前記した原理に基づくものと考えられるか
ら、サンドブラスト処理の施されないシリコン基板にも
本発明は適用できることは勿論である。
Further, in the above embodiment, the silicon substrate subjected to the sandblast treatment has been described. However, since it is considered that the stabilization of the resistivity is based on the above-mentioned principle, the present invention is applied to the silicon substrate which is not subjected to the sandblast treatment. Can of course be applied.

【0044】[0044]

【発明の効果】本願において開示される発明のうち代表
的なものによって得られる効果を簡単に説明すれば下記
のとおりである。単結晶育成中に窒素が添加されたシリ
コン基板に熱処理を施すと、深い準位の発生原因となる
空孔がなくなるので、単結晶育成直後の抵抗率に回復す
ることができ、その結果、品質管理が容易となる。
The effects obtained by typical ones of the inventions disclosed in the present application will be briefly described as follows. When a silicon substrate to which nitrogen is added is subjected to a heat treatment during the growth of a single crystal, the vacancies that cause the generation of a deep level disappear, and the resistivity can be restored to the resistivity immediately after the growth of the single crystal. Management becomes easy.

【図面の簡単な説明】[Brief description of the drawings]

【図1】本発明に係るシリコン単結晶基板の製造方法を
示す工程図である。
FIG. 1 is a process chart showing a method for manufacturing a silicon single crystal substrate according to the present invention.

【図2】(A),(B)は従来の熱処理条件(温度及び
時間)で熱処理を行なった場合のn型シリコン基板の抵
抗率変化及びキャリヤー濃度変化をそれぞれ示す図表で
ある。
FIGS. 2A and 2B are tables respectively showing a change in resistivity and a change in carrier concentration of an n-type silicon substrate when heat treatment is performed under conventional heat treatment conditions (temperature and time).

【図3】(A),(B)は従来の熱処理条件(温度及び
時間)で熱処理を行なった場合のp型シリコン基板の抵
抗率変化及びキャリヤー濃度変化をそれぞれ示す図表で
ある。
FIGS. 3A and 3B are tables respectively showing a change in resistivity and a change in carrier concentration of a p-type silicon substrate when heat treatment is performed under conventional heat treatment conditions (temperature and time).

【図4】熱処理条件(温度及び時間)を変えた場合の抵
抗率変化を示す図表である。
FIG. 4 is a chart showing a change in resistivity when heat treatment conditions (temperature and time) are changed.

【図5】(A),(B)は本実施例の熱処理条件(温度
及び時間)で熱処理を行なった場合のp型シリコン基板
の抵抗率変化及びキャリヤー濃度変化をそれぞれ示す図
表である。
FIGS. 5A and 5B are tables respectively showing a change in resistivity and a change in carrier concentration of a p-type silicon substrate when heat treatment is performed under heat treatment conditions (temperature and time) of the present embodiment.

【図6】抵抗率変化の機構を説明するための図である。FIG. 6 is a diagram for explaining a mechanism of a resistivity change.

Claims (5)

(57)【特許請求の範囲】(57) [Claims] 【請求項1】 シリコン単結晶の育成中に窒素を添加す
る工程と、前記シリコン単結晶を切断する工程と、切断
されたシリコン単結晶基板を、少なくとも半導体素子製
造工程前に900℃〜1250℃の間のいずれかの温度
で保持して約10分〜1時間加熱することにより、半導
体素子製造工程前に、シリコン単結晶基板の抵抗率を単
結晶育成直後の値に回復させる工程とを有することを特
徴とするシリコン単結晶基板の製造方法。
1. A step of adding nitrogen during the growth of a silicon single crystal, a step of cutting the silicon single crystal, and a step of subjecting the cut silicon single crystal substrate to 900 ° C. to 1250 ° C. at least before a semiconductor element manufacturing step. Recovering the resistivity of the silicon single crystal substrate to a value immediately after the single crystal growth before heating the semiconductor single crystal by holding at any temperature between about 10 minutes and 1 hour. A method for manufacturing a silicon single crystal substrate, characterized in that:
【請求項2】 添加される前記窒素の濃度は、3×10
14atoms/cm3以上であることを特徴とする請求項1記載
のシリコン単結晶基板の製造方法。
2. The nitrogen concentration to be added is 3 × 10
2. The method for producing a silicon single crystal substrate according to claim 1, wherein the concentration is 14 atoms / cm 3 or more.
【請求項3】 前記シリコン単結晶の育成は、FZ法で
行うことを特徴とする請求項1又は請求項2記載のシリ
コン単結晶基板の製造方法。
3. The method according to claim 1, wherein the growing of the silicon single crystal is performed by an FZ method.
【請求項4】 前記熱処理は、ウェット酸素雰囲気、ド
ライ酸素雰囲気又は窒素雰囲気のいずれか1つで行われ
ることを特徴とする請求項1〜3いずれか記載のシリコ
ン単結晶基板の製造方法。
4. The method for manufacturing a silicon single crystal substrate according to claim 1, wherein the heat treatment is performed in one of a wet oxygen atmosphere, a dry oxygen atmosphere, and a nitrogen atmosphere.
【請求項5】 単結晶の育成中に窒素が添加されたシリ
コン単結晶基板について、半導体素子製造工程前に90
0℃〜1250℃の間のいずれかの温度で保持して約1
0分〜1時間加熱することにより、抵抗率が単結晶育成
直後の値に回復した基板の抵抗率を測定することを特徴
とするシリコン単結晶基板の品質管理方法。
5. A method for manufacturing a silicon single crystal substrate to which nitrogen is added during the growth of a single crystal, before manufacturing a semiconductor element.
Hold at any temperature between 0 ° C and 1250 ° C for about 1
A quality control method for a silicon single crystal substrate, comprising: measuring a resistivity of a substrate whose resistivity has been restored to a value immediately after growing a single crystal by heating for 0 minute to 1 hour.
JP7127091A 1995-04-27 1995-04-27 Manufacturing method and quality control method for silicon single crystal substrate Expired - Lifetime JP2742247B2 (en)

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JP3988307B2 (en) 1999-03-26 2007-10-10 株式会社Sumco Silicon single crystal, silicon wafer and epitaxial wafer
US20020142170A1 (en) 1999-07-28 2002-10-03 Sumitomo Metal Industries, Ltd. Silicon single crystal, silicon wafer, and epitaxial wafer
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