TW201800625A - Single crystal silicon manufacturing method - Google Patents
Single crystal silicon manufacturing method Download PDFInfo
- Publication number
- TW201800625A TW201800625A TW106104051A TW106104051A TW201800625A TW 201800625 A TW201800625 A TW 201800625A TW 106104051 A TW106104051 A TW 106104051A TW 106104051 A TW106104051 A TW 106104051A TW 201800625 A TW201800625 A TW 201800625A
- Authority
- TW
- Taiwan
- Prior art keywords
- tail
- single crystal
- silicon
- crystal silicon
- rearing
- Prior art date
Links
Classifications
-
- C—CHEMISTRY; METALLURGY
- C30—CRYSTAL GROWTH
- C30B—SINGLE-CRYSTAL GROWTH; UNIDIRECTIONAL SOLIDIFICATION OF EUTECTIC MATERIAL OR UNIDIRECTIONAL DEMIXING OF EUTECTOID MATERIAL; REFINING BY ZONE-MELTING OF MATERIAL; PRODUCTION OF A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; SINGLE CRYSTALS OR HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; AFTER-TREATMENT OF SINGLE CRYSTALS OR A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; APPARATUS THEREFOR
- C30B15/00—Single-crystal growth by pulling from a melt, e.g. Czochralski method
-
- C—CHEMISTRY; METALLURGY
- C30—CRYSTAL GROWTH
- C30B—SINGLE-CRYSTAL GROWTH; UNIDIRECTIONAL SOLIDIFICATION OF EUTECTIC MATERIAL OR UNIDIRECTIONAL DEMIXING OF EUTECTOID MATERIAL; REFINING BY ZONE-MELTING OF MATERIAL; PRODUCTION OF A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; SINGLE CRYSTALS OR HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; AFTER-TREATMENT OF SINGLE CRYSTALS OR A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; APPARATUS THEREFOR
- C30B15/00—Single-crystal growth by pulling from a melt, e.g. Czochralski method
- C30B15/20—Controlling or regulating
- C30B15/22—Stabilisation or shape controlling of the molten zone near the pulled crystal; Controlling the section of the crystal
-
- C—CHEMISTRY; METALLURGY
- C30—CRYSTAL GROWTH
- C30B—SINGLE-CRYSTAL GROWTH; UNIDIRECTIONAL SOLIDIFICATION OF EUTECTIC MATERIAL OR UNIDIRECTIONAL DEMIXING OF EUTECTOID MATERIAL; REFINING BY ZONE-MELTING OF MATERIAL; PRODUCTION OF A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; SINGLE CRYSTALS OR HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; AFTER-TREATMENT OF SINGLE CRYSTALS OR A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; APPARATUS THEREFOR
- C30B15/00—Single-crystal growth by pulling from a melt, e.g. Czochralski method
- C30B15/14—Heating of the melt or the crystallised materials
-
- C—CHEMISTRY; METALLURGY
- C30—CRYSTAL GROWTH
- C30B—SINGLE-CRYSTAL GROWTH; UNIDIRECTIONAL SOLIDIFICATION OF EUTECTIC MATERIAL OR UNIDIRECTIONAL DEMIXING OF EUTECTOID MATERIAL; REFINING BY ZONE-MELTING OF MATERIAL; PRODUCTION OF A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; SINGLE CRYSTALS OR HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; AFTER-TREATMENT OF SINGLE CRYSTALS OR A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; APPARATUS THEREFOR
- C30B15/00—Single-crystal growth by pulling from a melt, e.g. Czochralski method
- C30B15/20—Controlling or regulating
-
- C—CHEMISTRY; METALLURGY
- C30—CRYSTAL GROWTH
- C30B—SINGLE-CRYSTAL GROWTH; UNIDIRECTIONAL SOLIDIFICATION OF EUTECTIC MATERIAL OR UNIDIRECTIONAL DEMIXING OF EUTECTOID MATERIAL; REFINING BY ZONE-MELTING OF MATERIAL; PRODUCTION OF A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; SINGLE CRYSTALS OR HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; AFTER-TREATMENT OF SINGLE CRYSTALS OR A HOMOGENEOUS POLYCRYSTALLINE MATERIAL WITH DEFINED STRUCTURE; APPARATUS THEREFOR
- C30B29/00—Single crystals or homogeneous polycrystalline material with defined structure characterised by the material or by their shape
- C30B29/02—Elements
- C30B29/06—Silicon
Landscapes
- Chemical & Material Sciences (AREA)
- Engineering & Computer Science (AREA)
- Crystallography & Structural Chemistry (AREA)
- Materials Engineering (AREA)
- Metallurgy (AREA)
- Organic Chemistry (AREA)
- Crystals, And After-Treatments Of Crystals (AREA)
Abstract
Description
本發明係有關於使用柴可拉斯基法(以下稱為CZ法)的單晶矽的製造方法,且特別有關於單晶矽棒的尾部的育成方法。 The present invention relates to a method of manufacturing single-crystal silicon using the Tchaisky method (hereinafter referred to as the CZ method), and particularly to a method of cultivating the tail of a single-crystal silicon rod.
做為半導體裝置的基板材料,磊晶矽晶圓被廣泛地使用。磊晶矽晶圓是在整塊矽基板的表面形成磊晶層的產物,因為結晶的完全性高,所以能夠製造出高品質且可靠度高的半導體裝置。 As a substrate material for semiconductor devices, epitaxial silicon wafers are widely used. An epitaxial silicon wafer is a product formed by forming an epitaxial layer on the surface of a monolithic silicon substrate. Because of the high crystal integrity, a high-quality and highly reliable semiconductor device can be manufactured.
做為磊晶矽晶圓的基板材料的單晶矽大多是以CZ法製造。CZ法中,會將多晶矽等的原料填充到石英坩堝,在腔室內加熱矽原料使其熔解。接著,使安裝於拉起軸的下端的種晶從石英坩堝的上方下降,使其接觸矽熔液,一邊旋轉種晶及坩堝一邊慢慢使種晶上升,藉此在種晶的下方成長出大直徑的單晶。 The single crystal silicon used as the substrate material of the epitaxial silicon wafer is mostly manufactured by the CZ method. In the CZ method, raw materials such as polycrystalline silicon are filled into a quartz crucible, and the silicon raw materials are heated and melted in the chamber. Next, the seed crystal attached to the lower end of the pull-up shaft is lowered from above the quartz crucible to contact the silicon melt, and the seed crystal is slowly raised while rotating the seed crystal and the crucible, thereby growing under the seed crystal Large diameter single crystal.
做為磊晶矽晶圓的製造方法,例如專利文獻1揭露了當拉起單晶矽棒時,將拉起途中的1030~920℃的溫度領域以1.0℃/分以上的冷卻速度,接著在920~720℃的溫度領域以0.5℃/分以上的冷卻速度育成出單晶矽後,在從該單晶切出來 的晶圓的表面形成磊晶層。快速地通過OSF(Oxygen induced Stacking Fault:氧感應積層缺陷)的核容易成長的溫度領域(1030~920℃)使OSF核的尺寸縮到非常小,藉此能夠抑制起因於OSF的磊晶缺陷產生。 As a method of manufacturing epitaxial silicon wafers, for example, Patent Document 1 discloses that when pulling up a single crystal silicon rod, the temperature range of 1030 to 920 ° C during the pulling up is cooled at a rate of 1.0 ° C / min or more, and then In the temperature range of 920 ~ 720 ℃, after the single crystal silicon is cultivated at a cooling rate of 0.5 ℃ / min or more, it is cut out from the single crystal Epitaxial layer is formed on the surface of the wafer. The temperature range (1030 ~ 920 ℃) where the core of OSF (Oxygen induced Stacking Fault) is easy to grow quickly is reduced to a very small size, thereby suppressing the generation of epitaxial defects caused by OSF .
單晶的拉起步驟中,會依序進行為了使單晶無錯位化以衝頸法讓結晶值晶變細的縮頸步驟、使結晶直徑逐漸增加的肩部育成步驟、一邊維持結晶直徑於一定值一邊繼續成長結晶的體部育成步驟、逐漸縮小結晶直徑形成圓錐狀的尾部的尾部育成步驟。在這當中,尾部育成步驟是要一邊防止存在於結晶成長界面的熔液與單晶之間的熱均衡崩壞而給予結晶急劇的熱衝擊,導致滑動錯位或氧分析異常等的品質異常發生,一邊將單晶從熔液分離的必要的步驟。 In the pull-up step of the single crystal, a necking step to narrow the crystal value by the punching method to make the single crystal non-displacement, a shoulder cultivating step to gradually increase the crystal diameter, while maintaining the crystal diameter at Continue to grow the body growth step of the crystal at a certain value, and gradually reduce the diameter of the crystal to form the tail growth step of the conical tail. Among them, the tail rearing step is to prevent the thermal equilibrium collapse between the melt and the single crystal existing at the crystal growth interface and give the crystal a sharp thermal shock, resulting in the occurrence of quality abnormalities such as sliding dislocation or abnormal oxygen analysis. Steps necessary to separate the single crystal from the melt.
關於尾部育成步驟,例如專利文獻2記載了將晶棒的末端錐體部(尾部)的拉起速度維持在與晶棒的本體部(體部)的第2半部的拉起速度相同的這種較為一定的速度,又如果有需要的話,會藉由增加供給至加熱器的電力(熱量)、或者是減少結晶旋轉速度或坩堝旋轉速度,來製造出具有均一熱履歷的單晶矽棒。 Regarding the tail rearing step, for example, Patent Document 2 describes that the pulling speed of the tip cone (tail) of the ingot is maintained at the same speed as the second half of the body (body) of the ingot A relatively constant speed, and if necessary, will increase the power (heat) supplied to the heater, or reduce the crystal rotation speed or crucible rotation speed to produce a single crystal silicon rod with a uniform thermal history.
專利文獻1:日本特開2010-30856號公報 Patent Document 1: Japanese Patent Laid-Open No. 2010-30856
專利文獻2:日本特開平10-95698號公報 Patent Document 2: Japanese Patent Laid-Open No. 10-95698
專利文獻1中,使用具備水冷體的單晶拉起裝置, 控制單晶育成時的拉起速度結晶化後單晶的拉起軸方向的溫度變化。然而,做為磊晶矽晶圓的基板材料使用的部分是結晶直徑維持一定的體部(直胴部),尾部是不被當作晶圓產品使用的部位。因此,專利文獻1雖然記載了體部的冷卻條件,切沒有記載尾部的拉起速度、加熱器功率、單晶的旋轉速度等的具體的拉起條件。 In Patent Document 1, a single crystal pulling device equipped with a water cooling body is used, Controlling the pull-up speed during crystallization of the single crystal The temperature change in the direction of the pull-up axis of the single crystal after crystallization. However, the part used as the substrate material of epitaxial silicon wafers is the body part (straight body part) whose crystal diameter is kept constant, and the tail part is not used as a wafer product. Therefore, although Patent Document 1 describes the cooling conditions of the body, it does not describe the specific pulling conditions such as the pulling speed of the tail portion, the heater power, and the rotation speed of the single crystal.
尾部的育成中,加快單晶的拉起速度逐漸縮窄結晶直徑的控制是一般的作法。因為藉由加快單晶的拉起速度能夠簡單地縮窄尾部,且尾部的育成時間變短會關係到製造成本的減低。又,如上所述,尾部是不成為晶圓產品的部位,提高拉起速度讓尾部本身的結晶品質下降也不會造成什麼問題。因為這樣的理由,過去的一般的尾部育成步驟中,會進行加快單晶的拉起速度的控制,即使是專利文獻1中也是採用容易縮窄尾部的條件。 In the rearing of the tail, it is common practice to accelerate the pulling speed of the single crystal and gradually narrow the crystal diameter. This is because the tail can be simply narrowed by increasing the pulling speed of the single crystal, and the shortening of the tail incubation time will reduce the manufacturing cost. In addition, as mentioned above, the tail is a part that does not become a wafer product, and increasing the pulling speed to lower the crystal quality of the tail itself will not cause any problems. For this reason, in the past, in the general tail growing step, the control of increasing the pulling speed of the single crystal is performed, and even in Patent Document 1, the condition that the tail is easily narrowed is adopted.
然而,尾部育成步驟中,加快單晶的拉起速度的情況下,會有結晶彎折或者是單晶突然從熔液分離而造成單晶錯位的風險。 However, in the tail rearing step, if the speed of pulling up the single crystal is increased, there is a risk of the crystal bending or the single crystal suddenly separating from the melt and causing the single crystal to be misaligned.
專利文獻2揭露了將尾部的拉起速度維持在與體部的後半的拉起速度相同的較一定的速度。像這樣將尾部的拉起速度維持一定的控制,乍看之下就會想到整個單晶的體部全體會有比較一定的冷卻速度及滯留時間。 Patent Document 2 discloses that the pulling speed of the tail is maintained at a relatively constant speed that is the same as the pulling speed of the second half of the body. Keeping the pulling speed of the tail part controlled like this, at first glance, the whole body of the single crystal will have a certain cooling rate and residence time.
然而,將尾部的拉起速度設定成與體部相同的速度的話,單晶的拉起速度會變得比起習知的尾部育成步驟慢,因此從矽熔液拉起的單晶矽停留在OSF核形成溫度領域的時間 會實際地變長,會冒著錯位缺陷增大的的風險。 However, if the tail pull-up speed is set to the same speed as the body, the pull-up speed of the single crystal will become slower than the conventional tail growth step, so the single crystal silicon pulled up from the silicon melt stays at OSF nucleation time in the temperature field It will actually become longer, risking increased misalignment defects.
又,尾部育成步驟中,結晶直徑逐漸減少,如第8圖所示,熱遮蔽體17與單晶矽3之間的間隔D變大,來自矽熔液2等的熱會如白色箭頭所示地往上方擴散,結晶化後的單晶矽3的周圍高溫化。在這種環境下,將單晶矽3的尾部3d以和體部3c相同的拉起速度慢慢拉起的情況下,單晶矽3的周圍的高溫化的影響會變更大。也就是說,從矽熔液2拉起的單晶矽3停留在OSF核形成溫度領域的時間變得更長,磊晶缺陷增大。 In addition, in the tail rearing step, the crystal diameter gradually decreases. As shown in FIG. 8, the distance D between the heat shield 17 and the single crystal silicon 3 becomes larger, and the heat from the silicon melt 2 etc. is shown by the white arrow The ground diffuses upward, and the surroundings of the crystallized single crystal silicon 3 increase in temperature. In such an environment, when the tail portion 3d of the single crystal silicon 3 is slowly pulled up at the same pulling speed as the body portion 3c, the influence of the increase in temperature around the single crystal silicon 3 changes greatly. In other words, the time for the single crystal silicon 3 pulled up from the silicon melt 2 to stay in the OSF nucleus formation temperature region becomes longer, and the epitaxial defects increase.
又,與拉起體部3c的情況不同,尾部3d的結晶直徑減小,拉起結晶的狀態時刻地改變,因而容易錯位化。又,尾部育成步驟中,坩堝內的熔液量少,坩堝底部保持著熔液,因此隨著尾部3d的拉起坩堝內的熔液的狀態也時刻地變化,容易發生錯位化。因此,將尾部3d以和體部3c相同的速度拉起的情況下,會有尾部3d的拉起結束為止的時間變得很長,尾部3d的錯位化的風險增大的問題。 In addition, unlike the case where the body portion 3c is pulled up, the crystal diameter of the tail portion 3d is reduced, and the state of pulling up the crystal changes from time to time, so it is easy to be displaced. In addition, in the tail rearing step, the amount of melt in the crucible is small, and the bottom of the crucible holds the melt. Therefore, the state of the melt in the crucible changes with time as the tail 3d is pulled up, and misalignment is likely to occur. Therefore, when the tail portion 3d is pulled up at the same speed as the body portion 3c, there is a problem that the time until the end of the tail portion 3d is pulled up becomes long, and the risk of misalignment of the tail portion 3d increases.
因此,本發明的目的是提供一種單晶矽的製造方法,能夠一邊防止結晶彎曲或從熔液分離所造成的單晶化率的下降,且一邊抑制做為磊晶矽晶圓的基板材料使用時的磊晶缺陷的產生。 Therefore, an object of the present invention is to provide a method for manufacturing single crystal silicon, which can prevent the use of a substrate material as an epitaxial silicon wafer while preventing the reduction of the single crystal rate caused by crystal bending or separation from the melt The occurrence of epitaxial defects at the time.
為了解決上述問題,本發明的單晶矽的製造方法,利用從石英坩堝內的矽熔液中拉起單晶矽的柴可拉斯基法來製造單晶矽,包括:體部育成步驟,育成結晶直徑維持一定的體部;尾部育成步驟,育成結晶直徑逐漸減少的尾部,其中使用水冷體來冷卻從該矽熔液拉起的該單晶矽,該水冷體配置 在比配置在該石英坩堝的上方的熱遮蔽體的下端更上方且該熱遮蔽體的內側,該尾部育成步驟中,從該尾部的育成開始時至結束時為止,使用與該體部育成結束時的拉起速度相同的拉起速度來拉起該單晶矽。 In order to solve the above-mentioned problems, the method for manufacturing single-crystal silicon of the present invention uses the Tchaikovsky method of pulling single-crystal silicon from the silicon melt in a quartz crucible to manufacture single-crystal silicon, including: a body growing step, The rearing crystal diameter maintains a certain body; the rearing step is to rearwardly reduce the rearward diameter of the crystal, wherein a water cooling body is used to cool the single crystal silicon pulled from the silicon melt, the water cooling body is arranged In the tail rearing step, which is higher than the lower end of the heat shield arranged above the quartz crucible and inside the heat shield, from the start of the rear of the tail to the end, the end of the rear of the body is used The single-crystal silicon is pulled up at the same pull-up speed at the same time.
尾部育成步驟中,結晶直徑逐漸減小使得熱遮蔽體與單晶之間的橫方向的間隙逐漸變大,被熱遮蔽體遮蔽的熱往上方擴散,單晶矽變得不容易被冷卻。又,尾部育成步驟中,為了避免熱遮蔽體與坩堝接觸而停止上昇石英坩堝的情況下,熔液面的降低會使得熱遮蔽體與熔液面之間的間隔逐漸變寬,來自石英坩堝的輻射熱更容易往上方擴散。因此,尾部附近的體部的結晶品質會受到熱的影響而變得與上部側的結晶品質不同。也就是,1020~980℃的溫度領域的停留時間變長,形成慢冷狀態,形成含有容易產生磊晶缺陷的大的OSF核的結晶。 In the tail rearing step, the crystal diameter gradually decreases so that the lateral gap between the heat shield and the single crystal gradually becomes larger, the heat shielded by the heat shield diffuses upward, and the single crystal silicon becomes difficult to be cooled. In addition, in the tail rearing step, in order to avoid the contact between the heat shield and the crucible and stop the rise of the quartz crucible, the lowering of the melt surface will gradually widen the gap between the heat shield and the melt surface. Radiant heat is more likely to spread upward. Therefore, the crystal quality of the body near the tail is affected by heat and becomes different from the crystal quality of the upper side. That is, the residence time in the temperature range of 1020 to 980 ° C becomes longer, forming a slow cooling state, and forming crystals containing large OSF nuclei that are prone to epitaxial defects.
然而,根據本發明,在熱遮蔽體的上方的拉起路徑的周圍設置水冷體,因此不需要提高單晶的拉起速度,就能夠縮短一結晶化後的單晶矽停留在OSF形成溫度領域的期間。因此,能夠製造出一種單晶矽,可以防止結晶彎曲或結晶從熔液分離造成的單晶化率的下降,且可以抑制磊晶層形成時產生磊晶缺陷。 However, according to the present invention, since the water-cooling body is provided around the pull-up path above the heat shield, it is possible to shorten the stay of a crystallized single-crystal silicon in the OSF formation temperature range without increasing the pull-up speed of the single crystal Period. Therefore, it is possible to manufacture a single crystal silicon, which can prevent the reduction of the single crystallization rate caused by the warpage of the crystal or the separation of the crystal from the melt, and can suppress the occurrence of epitaxial defects during the formation of the epitaxial layer.
該尾部育成步驟中,該尾部育成步驟中,使該單晶矽的該體部在15分鐘內通過1020℃~980℃的溫度領域為佳。像這樣,從矽熔液拉起的單晶矽快速通過OSF核形成溫度領域,藉此能夠縮小單晶矽的OSF核的尺寸。因此,在從單晶 矽棒切出來的矽晶圓表面形成磊晶層時,能夠抑制起因於OSF的磊晶缺陷。 In the tail rearing step, in the tail rearing step, the body of the single crystal silicon is preferably passed through the temperature range of 1020 ° C to 980 ° C within 15 minutes. In this way, the single-crystal silicon pulled up from the silicon melt quickly passes through the OSF core formation temperature region, whereby the size of the single-crystal silicon OSF core can be reduced. Therefore, in the single crystal When an epitaxial layer is formed on the surface of a silicon wafer cut from a silicon rod, epitaxial defects caused by OSF can be suppressed.
本發明的單晶矽的製造方法,從該尾部的育成開始時至結束時為止,逐漸增加加熱該矽熔液的加熱器的功率,將該尾部的育成結束時的該加熱器的功率設定在該尾部的育成開始時的該加熱器的功率的1.1倍以上1.5倍以下為佳。根據這樣的方法,能夠實現一邊防止結晶彎曲或單晶從矽熔液分離,一邊實現縮尾。 In the method for manufacturing single crystal silicon of the present invention, the power of the heater for heating the silicon melt is gradually increased from the beginning to the end of the rearing of the tail, and the power of the heater is set to It is preferable that the power of the heater is 1.1 times or more and 1.5 times or less at the start of rearing the tail. According to such a method, tail shrinkage can be realized while preventing the crystal from bending or separating the single crystal from the silicon melt.
該尾部育成步驟中,該尾部育成步驟中,上昇該石英坩堝使該熱遮蔽體與該矽熔液之間的間隔維持一定為佳。在尾部育成步驟結束為止,持續上昇石英坩堝將熔液面的高度位置保持一定,藉此能夠抑制來自石英坩堝的輻射熱的影響,能夠抑制OSF核形成溫度領域的擴大。 In the tail rearing step, in the tail rearing step, it is better to raise the quartz crucible to keep the interval between the heat shield and the silicon melt constant. Until the end of the rearing step, the quartz crucible is continuously raised to keep the height of the melt surface constant, thereby suppressing the influence of radiant heat from the quartz crucible and suppressing the expansion of the OSF nucleation temperature range.
該尾部育成步驟中,該尾部育成步驟中,將該石英坩堝或該單晶矽的旋轉速度維持一定為佳,又,施加磁場至該矽熔液也為佳。該尾部育成步驟中,石英坩堝內的熔液量少,且為了以坩堝底部保持熔液,熔液容易受到石英坩堝的旋轉速度的變化的影響,熔液的狀態會不穩定,因此藉由將旋轉速度維持一定,可嘗試讓熔液狀態的穩定化,能夠減低單晶矽的錯位化的風險。同樣地,藉由將單晶矽的旋轉速度維持一定,或者是藉由施加磁場至矽熔液,可嘗試讓尾部育成步驟中的熔液狀態穩定化,能夠減低單晶矽的錯位化的風險。另外,石英坩堝及單晶矽的旋轉速度實質上為一定即可,±2rpm的變動在容許範圍內。 In the tail rearing step, the rotation speed of the quartz crucible or the single crystal silicon is preferably kept constant, and it is also preferable to apply a magnetic field to the silicon melt. In this tail rearing step, the amount of melt in the quartz crucible is small, and in order to hold the melt at the bottom of the crucible, the melt is easily affected by the change in the rotation speed of the quartz crucible, and the state of the melt will be unstable. Keeping the rotation speed constant, you can try to stabilize the melt state, which can reduce the risk of dislocation of single crystal silicon. Similarly, by maintaining a constant rotation speed of the single crystal silicon, or by applying a magnetic field to the silicon melt, an attempt can be made to stabilize the melt state in the rearing step, which can reduce the risk of dislocation of the single crystal silicon . In addition, the rotation speed of the quartz crucible and single crystal silicon may be substantially constant, and the variation of ± 2 rpm is within the allowable range.
根據本發明,能夠提供一種單晶矽的製造方法,可一邊防止結晶彎曲或從熔液分離所造成的單晶化率的下降,且一邊抑制做為磊晶矽晶圓的基板材料使用時的磊晶缺陷的產生。 According to the present invention, it is possible to provide a method for manufacturing single-crystal silicon, which can prevent the reduction of the single-crystallization rate caused by crystal bending or separation from the melt, and at the same time suppress the use of the substrate material as an epitaxial silicon wafer The occurrence of epitaxial defects.
1A、1B‧‧‧單晶製造裝置 1A, 1B‧‧‧Single crystal manufacturing equipment
2‧‧‧矽熔液 2‧‧‧Silver melt
3‧‧‧單晶矽 3‧‧‧Single crystal silicon
3a‧‧‧頸部 3a‧‧‧Neck
3b‧‧‧肩部 3b‧‧‧Shoulder
3c‧‧‧體部 3c‧‧‧Body
3d‧‧‧尾部 3d‧‧‧tail
10‧‧‧腔室 10‧‧‧ chamber
10a‧‧‧主腔室 10a‧‧‧Main chamber
10b‧‧‧牽引腔室 10b‧‧‧traction chamber
10c‧‧‧氣體導入口 10c‧‧‧Gas inlet
10d‧‧‧氣體排出口 10d‧‧‧gas outlet
10e‧‧‧觀察窗 10e‧‧‧ observation window
11‧‧‧石英坩堝 11‧‧‧Quartz crucible
12‧‧‧承載器 12‧‧‧Carrier
13‧‧‧旋轉軸 13‧‧‧rotation axis
14‧‧‧轉軸驅動機構 14‧‧‧Rotary shaft drive mechanism
15‧‧‧加熱器 15‧‧‧heater
16‧‧‧隔熱材 16‧‧‧Insulation
17‧‧‧遮蔽體 17‧‧‧ Cover
17a‧‧‧開口 17a‧‧‧Opening
17b‧‧‧下端 17b‧‧‧lower
17i‧‧‧內側 17i‧‧‧Inside
18‧‧‧水冷體 18‧‧‧Water cooling body
19‧‧‧單晶拉起用的線 19‧‧‧Single crystal pulling wire
20‧‧‧捲線機構 20‧‧‧coil winding mechanism
21‧‧‧磁場產生裝置 21‧‧‧ magnetic field generating device
22‧‧‧CCD相機 22‧‧‧CCD camera
23‧‧‧影像處理部 23‧‧‧Image Processing Department
24‧‧‧控制部 24‧‧‧Control Department
第1圖係概要顯示本發明的第1實施型態的單晶製造裝置的構造的側視剖面圖。 FIG. 1 is a side cross-sectional view schematically showing the structure of a single crystal manufacturing apparatus according to a first embodiment of the present invention.
第2圖係說明本發明的實施型態的單晶矽的製造方法的流程圖。 FIG. 2 is a flowchart illustrating a method for manufacturing single crystal silicon according to an embodiment of the present invention.
第3圖係顯示單晶矽棒的形狀的略剖面圖。 Figure 3 is a schematic cross-sectional view showing the shape of a single crystal silicon rod.
第4圖係顯示尾部育成步驟中的單晶的拉起狀況的略剖面圖。 Fig. 4 is a schematic cross-sectional view showing the state of pulling up of the single crystal in the tail growing step.
第5圖係顯示單晶的拉起速度及加熱器功率的變化的序列圖。 Fig. 5 is a sequence diagram showing the change of the pulling speed of the single crystal and the heater power.
第6圖係概要顯示本發明的第2實施型態的單晶製造裝置的構造的側視剖面圖。 FIG. 6 is a side cross-sectional view schematically showing the structure of a single crystal manufacturing apparatus according to a second embodiment of the present invention.
第7圖係顯示單晶的拉起位置與單晶的OSF核形成溫度領域(1020~980℃的領域)的通過時間的關係圖。 Fig. 7 is a graph showing the relationship between the pulling position of a single crystal and the passage time of the single crystal's OSF nucleation temperature range (1020 to 980 ° C).
第8圖係用以說明在尾部育成步驟中的習知的問題點。 Figure 8 is used to explain the conventional problems in the rearing step.
以下,參照圖式詳細說明本發明較佳的實施型態。 Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the drawings.
第1圖係概要顯示本發明的第1實施型態的單晶製造裝置的構造的側視剖面圖。 FIG. 1 is a side cross-sectional view schematically showing the structure of a single crystal manufacturing apparatus according to a first embodiment of the present invention.
如第1圖所示,單晶製造裝置1A包括:腔室10;石英坩堝11,在腔室10內,保持矽熔液2;石墨製的承載器12,保持石英坩堝11;旋轉軸13,支持承載器12;轉軸驅動機構14,旋轉及升降驅動旋轉軸13;加熱器15,配置於承載器12的周圍;隔熱材16,在加熱側15的外側沿著腔室10的內面配置;熱遮蔽體17,配置於石英坩堝11的上方;水冷體18,在熱遮蔽體的內側,設置於比熱遮蔽體17的下端更上方;單晶拉起用的線19,位於石英坩堝11的上方,配置於與旋轉軸13同軸;捲線機構20,配置於腔室10的上方。 As shown in FIG. 1, the single crystal manufacturing apparatus 1A includes: a chamber 10; a quartz crucible 11 that holds a silicon melt 2 in the chamber 10; a carrier 12 made of graphite that holds a quartz crucible 11; a rotating shaft 13, Support carrier 12; rotating shaft drive mechanism 14, which rotates and lifts the rotating shaft 13; heater 15, which is arranged around the carrier 12; heat insulation material 16, which is arranged along the inner surface of the chamber 10 outside the heating side 15 ; The heat shield 17 is arranged above the quartz crucible 11; the water-cooled body 18, which is arranged above the lower end of the heat shield 17 inside the heat shield; the wire 19 for pulling up the single crystal, is located above the quartz crucible 11 Is arranged coaxially with the rotating shaft 13; the winding mechanism 20 is arranged above the chamber 10.
又,單晶製造裝置1A包括:磁場產生裝置21,配置於腔室10的外側;CCD相機22,拍攝腔室10內;影像處理部23,處理CCD相機22拍攝的影像;控制部24,根據影像處理部23的輸出來控制轉軸驅動機構14、加熱器15及捲線機構20。 Further, the single crystal manufacturing apparatus 1A includes: a magnetic field generating device 21 arranged outside the chamber 10; a CCD camera 22, which shoots inside the chamber 10; an image processing section 23, which processes images shot by the CCD camera 22; a control section 24, based on The output of the image processing unit 23 controls the shaft drive mechanism 14, the heater 15, and the winding mechanism 20.
腔室10是由主腔室10a、以及連結到主腔室10a的上部開口的細長圓筒狀的牽引腔室10b所構成。石英坩堝11、承載器12、加熱器15及熱遮蔽體17設置在主腔室10a內。牽引腔室10b設置有將氬氣等的非活性氣體(沖洗氣體)導入腔室10內的氣體導入口10c,主腔室10a的下部設置有將非活性氣體排出的氣體排出口10d。又,主腔室10a的上部設置有觀察窗10e,透過觀察10e能夠觀察單晶矽3的育成情況。 The chamber 10 is composed of a main chamber 10a and an elongated cylindrical traction chamber 10b connected to the upper opening of the main chamber 10a. The quartz crucible 11, the carrier 12, the heater 15 and the heat shield 17 are provided in the main chamber 10a. The traction chamber 10b is provided with a gas introduction port 10c for introducing inactive gas (rinsing gas) such as argon gas into the chamber 10, and a gas discharge port 10d for discharging the inactive gas is provided in the lower part of the main chamber 10a. In addition, an observation window 10e is provided on the upper portion of the main chamber 10a, and the growth state of the single crystal silicon 3 can be observed through the observation 10e.
石英坩堝11是具有圓筒狀的側壁部及彎曲的底部的石英玻璃製的容器。承載器12為了維持住加熱軟化的石英坩堝11的形狀,會緊貼著石英坩堝11的外表面以包覆石英坩堝11的方式加以保持。石英坩堝11及承載器12構成在腔室10內支持 矽熔液的雙重構造的坩堝。 The quartz crucible 11 is a quartz glass container having a cylindrical side wall portion and a curved bottom. In order to maintain the shape of the quartz crucible 11 softened by heating, the carrier 12 is held so as to cover the quartz crucible 11 so as to cover the quartz crucible 11. The quartz crucible 11 and the carrier 12 constitute a support in the chamber 10 A double-structure crucible of silicon melt.
承載器12固定於延伸於鉛直方向的旋轉軸13的上端部。又,旋轉軸13的下端部貫通腔室10的底部中央,連接到設置於腔室10的外側的轉軸驅動機構14。承載器12、旋轉軸13及轉軸驅動機構14構成石英坩堝11的旋轉機構及升降機構。 The carrier 12 is fixed to the upper end portion of the rotating shaft 13 extending in the vertical direction. In addition, the lower end portion of the rotating shaft 13 penetrates the center of the bottom of the chamber 10 and is connected to the rotating shaft drive mechanism 14 provided outside the chamber 10. The carrier 12, the rotating shaft 13 and the rotating shaft drive mechanism 14 constitute a rotating mechanism and a lifting mechanism of the quartz crucible 11.
加熱器15用於使填充於石英坩堝11內的矽原料熔融以產生矽熔液2。加熱器15是碳製的阻抗加熱式加熱器,設置成包圍承載器12內的石英坩堝11。又,加熱器15的外側被隔熱材16包圍,藉此腔室10內的保溫性提高。 The heater 15 is used to melt the silicon raw material filled in the quartz crucible 11 to produce the silicon melt 2. The heater 15 is an impedance heating heater made of carbon, and is provided so as to surround the quartz crucible 11 in the carrier 12. In addition, the outside of the heater 15 is surrounded by the heat insulating material 16, whereby the heat retention in the chamber 10 is improved.
熱遮蔽體17的設置是為了抑制矽熔液2的溫度變動,在固液界面附近形成適當的熱區,且防止來自加熱器15及石英坩堝11的輻射熱對單晶矽3加熱。熱遮蔽體17是覆蓋住除去單晶矽3向上拉的路徑以外的矽熔液2的上方的領域的石墨製的構件,具有從上方朝向下方縮小直徑的逆圓錐梯形。 The heat shield 17 is provided to suppress the temperature fluctuation of the silicon melt 2, form an appropriate hot zone near the solid-liquid interface, and prevent radiant heat from the heater 15 and the quartz crucible 11 from heating the single crystal silicon 3. The heat shield 17 is a graphite member that covers the area above the silicon melt 2 except for the path through which the single crystal silicon 3 is pulled up, and has a reverse cone trapezoid whose diameter decreases from above to below.
熱遮蔽體17的下端中央形成有比單晶矽3的直徑大的圓形的開口17a,以確保單晶矽3的拉起路徑。如圖所示,單晶矽3通過開口17a被拉到上方。熱遮蔽體17的開口17a的直徑比石英坩堝11的口徑小,且熱遮蔽體17的下端部位於石英坩堝11的內側,因此即使將石英坩堝11的邊緣上端上升到比熱遮蔽體17的下端更上方,熱遮蔽體17也不會干涉到石英坩堝11。 In the center of the lower end of the heat shield 17, a circular opening 17 a larger than the diameter of the single crystal silicon 3 is formed to ensure the pulling path of the single crystal silicon 3. As shown in the figure, the single crystal silicon 3 is pulled upward through the opening 17a. The diameter of the opening 17a of the heat shield 17 is smaller than the diameter of the quartz crucible 11, and the lower end of the heat shield 17 is located inside the quartz crucible 11, so even if the upper edge of the quartz crucible 11 is raised to be more than the lower end of the heat shield 17 Even above, the heat shield 17 does not interfere with the quartz crucible 11.
隨著單晶矽3的成長,石英坩堝11內的熔液量減少,但藉由上昇石英坩堝11使得熔液面與熱遮蔽體17之間的間隔(間隙△G)維持一定,能夠抑制矽熔液2的溫度變化,且能夠將流過熔液面附近(沖洗氣體誘導路徑)的氣體的流速維持 一定,控制來自矽熔液2的摻雜物的蒸發量。因此,能夠提昇單晶的拉起軸方向的結晶缺陷分布、氧濃度分布、以及阻抗率分布等的穩定性。 As the single crystal silicon 3 grows, the amount of molten metal in the quartz crucible 11 decreases, but by raising the quartz crucible 11 the gap (gap ΔG) between the molten surface and the heat shield 17 is kept constant, and the silicon can be suppressed The temperature of the melt 2 changes, and the flow velocity of the gas flowing near the melt surface (flushing gas induction path) can be maintained Certainly, the evaporation amount of the dopant from the silicon melt 2 is controlled. Therefore, the stability of the crystal defect distribution, oxygen concentration distribution, and resistivity distribution of the single crystal in the direction of the pull-up axis can be improved.
在比熱遮蔽體17的下端17b更上方的熱遮蔽體17的內側,配置有水冷體18。與熱遮蔽體17等同樣地,水冷體18是以包圍住單晶矽3的拉起路徑的方式設置。水冷體18是由銅、鐵、不鏽鋼(SUS)、鉬等的熱傳導佳的金屬組成,能夠在其內部使冷卻水流通使表面溫度維持在常溫到200℃的範圍為佳。詳細將於後述,但藉由具備這個水冷體18,能夠促進一結晶化後的單晶矽3的冷卻。 Inside the heat shield 17 above the lower end 17 b of the heat shield 17, a water cooling body 18 is arranged. Like the heat shield 17 and the like, the water cooling body 18 is provided so as to surround the pulling path of the single crystal silicon 3. The water-cooled body 18 is composed of a metal having good thermal conductivity, such as copper, iron, stainless steel (SUS), and molybdenum. It is preferable that the cooling water can be circulated inside to maintain the surface temperature in the range of normal temperature to 200 ° C. The details will be described later, but by including this water-cooling body 18, the cooling of a crystallized single crystal silicon 3 can be promoted.
石英坩堝11的上方設置有做為單晶矽3的拉起軸的線19、以及捲起線19的捲線機構20。捲線機構20具有將線19與單晶一起旋轉的功能。捲線機構20配置在牽引腔室10b的上方,線19從捲線機構20通過牽引腔室10b延伸到下方,線19的前端部到達主腔室10a的內部空間。第1圖顯示育成途中的單晶矽3被吊在線19上的狀態。拉起單晶時會將種晶浸漬到矽熔液2,一邊分別旋轉石英坩堝11及種晶,一邊慢慢拉起線19,藉此成長單晶。 Above the quartz crucible 11, a wire 19 as a pull-up shaft of the single crystal silicon 3 and a wire winding mechanism 20 for winding the wire 19 are provided. The wire winding mechanism 20 has a function of rotating the wire 19 together with the single crystal. The wire winding mechanism 20 is arranged above the traction chamber 10b, the wire 19 extends downward from the wire winding mechanism 20 through the traction chamber 10b, and the front end portion of the wire 19 reaches the internal space of the main chamber 10a. Fig. 1 shows the state in which the single crystal silicon 3 during the breeding is suspended on the wire 19. When the single crystal is pulled up, the seed crystal is immersed in the silicon melt 2. While the quartz crucible 11 and the seed crystal are respectively rotated, the wire 19 is slowly pulled up, thereby growing the single crystal.
牽引腔室10b的上部設置有將非活性氣體導入到腔室10內的氣體導入口10c,主腔室10a的底部設置有將腔室10內的非活性氣體排出的氣體排出口10d。非活性氣體從氣體導入口10c導入到腔室10內,其導入量由閥門控制。又,密閉的腔室10內的非活性氣體會從氣體排出口10d排氣腔室10的外部,因此能夠回收腔室10內產生的SiO氣體或CO氣體,保持腔 室10內的清淨。雖然沒有圖示,但真空泵會透過配管連接到氣體排出口10d,一邊以真空泵吸引腔室10內的非活性氣體一邊以閥門控制其流量,藉此將腔室10內保持在一定的減壓狀態。 The upper part of the traction chamber 10b is provided with a gas inlet 10c for introducing inactive gas into the chamber 10, and the bottom of the main chamber 10a is provided with a gas discharge port 10d for discharging inert gas in the chamber 10. The inert gas is introduced into the chamber 10 from the gas introduction port 10c, and the introduction amount is controlled by a valve. In addition, the inert gas in the sealed chamber 10 is exhausted from the outside of the chamber 10 through the gas discharge port 10d, so the SiO gas or CO gas generated in the chamber 10 can be recovered and the chamber is maintained Clean room 10. Although not shown, the vacuum pump is connected to the gas discharge port 10d through a pipe, and the flow rate is controlled by a valve while sucking the inert gas in the chamber 10 by the vacuum pump, thereby keeping the chamber 10 at a certain decompressed state .
磁場產生裝置21施加水平磁場或垂直磁場到矽熔液2。藉由施加磁場到矽熔液2,能夠抑制與磁力線正交方向的熔液對流。因此,能夠抑制從石英坩堝11溶出氧氣,能夠減低單晶矽中的氧濃度。 The magnetic field generating device 21 applies a horizontal magnetic field or a vertical magnetic field to the silicon melt 2. By applying a magnetic field to the silicon melt 2, it is possible to suppress the convection of the melt in the direction orthogonal to the lines of magnetic force. Therefore, the elution of oxygen from the quartz crucible 11 can be suppressed, and the oxygen concentration in the single crystal silicon can be reduced.
主腔室10a的上部設置有用以觀察內部的觀察窗10e,CCD相機22設置於觀察窗10e的外側。單晶拉起步驟中,CCD相機22從觀察窗10e拍攝通過熱遮蔽體17的開口17a所能看到的單晶矽3與矽熔液2的界面部的影像。CCD相機22連接到影像處理部23,拍攝的影像被影像處理部處理,處理結果在控制部24中被用於拉起條件的控制。 The upper part of the main chamber 10a is provided with an observation window 10e to observe the inside, and the CCD camera 22 is provided outside the observation window 10e. In the step of pulling up the single crystal, the CCD camera 22 captures an image of the interface between the single crystal silicon 3 and the silicon melt 2 that can be seen through the opening 17 a of the heat shield 17 from the observation window 10 e. The CCD camera 22 is connected to the image processing unit 23, and the captured image is processed by the image processing unit, and the processing result is used in the control unit 24 to control the pull-up conditions.
第2係說明本發明的實施型態的單晶矽的製造方法的流程圖。又,第3圖係顯示單晶矽棒的形狀的略剖面圖。 The second part is a flowchart illustrating a method for manufacturing single crystal silicon according to an embodiment of the present invention. FIG. 3 is a schematic cross-sectional view showing the shape of a single crystal silicon rod.
如第2圖及第3圖所示,單晶矽3的製造中,加熱石英坩堝11內的矽原料,產生矽熔液2(步驟S11)。之後,使安裝於線19的前端部的種晶下降,使其接觸矽熔液(步驟S12)。 As shown in FIGS. 2 and 3, in the production of the single crystal silicon 3, the silicon raw material in the quartz crucible 11 is heated to produce a silicon melt 2 (step S11). After that, the seed crystal attached to the tip of the wire 19 is lowered and brought into contact with the silicon melt (step S12).
接著,實施單晶的拉起步驟,一邊維持與矽熔液2的接觸狀態一邊慢慢拉起種晶,育成單晶。單晶的拉起步驟中,依序實施縮頸步驟(步驟S13),為了無錯位化而形成結晶直徑縮細的頸部3a;肩部育成步驟(步驟S14),為了獲得規定的直徑而形成結晶直徑逐漸增加的肩部3b;體部育成步驟(步驟S15),形成結晶直徑維持一定的體部3c;尾部育成步驟(部 奏S16),形成結晶直徑逐漸減少的尾部3d,當單晶最終從熔液面分離出來時尾部育成步驟結束。藉由上述步驟,完成了從單晶的上端到下端依序具有頸部3a、肩部3b、體部3c、及尾部3d的單晶矽棒3。 Next, a single crystal pulling step is carried out, and the seed crystal is slowly pulled up while maintaining contact with the silicon melt 2 to form a single crystal. In the pulling-up step of the single crystal, a necking step (step S13) is sequentially performed to form a neck 3a with a narrowed crystal diameter for dislocation-free; a shoulder growing step (step S14) is formed to obtain a predetermined diameter Shoulder 3b with increasing crystal diameter; body growing step (step S15), forming body 3c with a constant crystal diameter; tail growing step (part Play S16) to form a tail 3d whose crystal diameter gradually decreases. When the single crystal is finally separated from the melt surface, the tail rearing step ends. Through the above steps, the single crystal silicon rod 3 having the neck 3a, the shoulder 3b, the body 3c, and the tail 3d in order from the upper end to the lower end of the single crystal is completed.
單晶拉起步驟中,為了控制單晶矽3的直徑與矽熔液2的液面位置,會以CCD相機拍攝單晶矽3與矽熔液2的界面的影像,從拍攝影像算出在固液界面的單晶的直徑及熔液面與熱遮蔽體17之間的間隔(間隙△G)。控制部24控制線19的拉起速度、加熱器15的功率等的拉起條件,使單晶矽3的直徑成為目標直徑。又,控制部24控制石英坩堝11的高度位置,使熔液面與熱遮蔽體17之間的間隔維持一定。 In the single crystal pulling step, in order to control the diameter of the single crystal silicon 3 and the liquid surface position of the silicon melt 2, a CCD camera is used to capture the image of the interface between the single crystal silicon 3 and the silicon melt 2, and the solid state is calculated from the captured image. The diameter of the single crystal at the liquid interface and the gap (gap ΔG) between the melt surface and the heat shield 17. The control unit 24 controls the pulling conditions such as the pulling speed of the wire 19 and the power of the heater 15 so that the diameter of the single crystal silicon 3 becomes the target diameter. In addition, the control unit 24 controls the height position of the quartz crucible 11 so that the distance between the melt surface and the heat shield 17 is kept constant.
第4圖係顯示尾部育成步驟中的單晶的拉起狀況的略剖面圖。 Fig. 4 is a schematic cross-sectional view showing the state of pulling up of the single crystal in the tail growing step.
如第4圖所示,為了以無錯位的狀態將單晶矽3與矽熔液2分離,在尾部育成步驟中隨著拉起的進行,結晶直徑會逐漸變小,因此熱遮蔽體17與單機性3之間的間隔D逐漸變寬。因此,由矽熔液2朝向上方的放熱路徑的寬度變大,熱變得容易從熱遮蔽體17的下端17b往上方擴散,上方的空間的溫度變得熱遮蔽體17的下端17b高。藉此,熱遮蔽體17的上部被加熱,熱遮蔽體17本身成為熱源,一結晶化後的單晶矽3被加熱。在這個狀態下,單晶矽3變得無法快速通過單晶中容易形成OSF核的1020~980℃的溫度領域(OSF核形成溫度領域),當單晶3的拉起速度減慢的情況下就更變得更難。 As shown in FIG. 4, in order to separate the single crystal silicon 3 from the silicon melt 2 in a state of no misalignment, the crystal diameter will gradually become smaller as the pull-up progresses in the tail rearing step, so the heat shield 17 and The interval D between the stand-alone 3 gradually widens. Therefore, the width of the heat dissipation path from the silicon melt 2 toward the upper side becomes larger, the heat is easily diffused upward from the lower end 17b of the heat shield 17, and the temperature of the space above becomes the lower end 17b of the heat shield 17 high. Thereby, the upper part of the heat shield 17 is heated, the heat shield 17 itself becomes a heat source, and a single crystal 3 after crystallization is heated. In this state, the single crystal silicon 3 becomes unable to quickly pass through the temperature range of 1020 to 980 ° C where the OSF nucleus is easily formed in the single crystal (OSF nucleus formation temperature range), when the pulling speed of the single crystal 3 is slowed down It becomes more difficult.
然而,本實施型態中,因為在比熱遮蔽體17的下 端17b的上方且熱遮蔽體17的內側17i設置了水冷體18,能夠降低通過熱遮蔽體17的下端17b的開口後的高溫領域的溫度,能夠縮窄1020~980℃的溫度領域的結晶成長方向的寬度。因此,即使將單晶矽3的拉起速度變得比習知還慢的情況下,也能夠縮短單晶矽3停留在1020~980℃的溫度領域的時間,能夠快速地通過OSF核形成溫度領域,極度縮小單晶中的OSF核的尺寸。 However, in the present embodiment, because of the heat shield 17 The water cooling body 18 is provided above the end 17b and inside 17i of the heat shield 17 to reduce the temperature in the high-temperature region after passing through the opening of the lower end 17b of the heat shield 17 and to narrow the crystal growth in the temperature region of 1020 to 980 ° C The width of the direction. Therefore, even if the pulling speed of the single crystal silicon 3 becomes slower than conventional knowledge, the time for the single crystal silicon 3 to stay in the temperature range of 1020 to 980 ° C can be shortened, and the temperature can be quickly formed by the OSF core In the field, the size of the OSF core in the single crystal is extremely reduced.
第5圖係顯示單晶矽3的拉起速度與加熱器15的功率變化的序列圖。 FIG. 5 is a sequence diagram showing the pull-up speed of the single crystal silicon 3 and the power change of the heater 15.
如第5圖所示,單晶矽3的拉起速度從體部3c一直到尾部3d都會控制在一定值。而,在尾部育成步驟中一定的拉起速度是指相對於尾部育成步驟開始時的拉起速度的變動率在±3%以內。 As shown in FIG. 5, the pulling speed of the single crystal silicon 3 is controlled to a certain value from the body portion 3c to the tail portion 3d. However, a certain pull-up speed in the tail rearing step means that the rate of change relative to the pull-up speed at the beginning of the tail rearing step is within ± 3%.
習知的一般的尾部育成步驟中,拉起速度比體部育成步驟更快,且輔助地增強加熱器15的功率,藉此縮細結晶直徑。然而,本實施型態中不改變拉起速度,只改變加熱器的功率,來實現縮尾。像這樣,藉由從尾部3d的育成開始時到結束時將拉起速度維持一定,能夠防止結晶彎曲或從熔液分離所造成的單晶的錯位化產生。 In the conventional general tail rearing step, the pull-up speed is faster than the body rearing step, and the power of the heater 15 is supplementarily increased, thereby narrowing the crystal diameter. However, in this embodiment, the pull-up speed is not changed, and only the power of the heater is changed to achieve tail shrinkage. In this way, by keeping the pull-up speed constant from the start to the end of the rearing of the tail 3d, it is possible to prevent the occurrence of dislocation of the single crystal caused by the crystal bending or separation from the melt.
使尾部3d的拉起速度與體部3c的拉起速度相同的情況下,雖然尾部的縮細的控制變得困難,但藉由更加強加熱器15的功率來產生矽熔液2難以固化的狀況,藉此能夠使縮尾變容易。增強加熱器15的功率的情況下,其輻射熱的影響變得更強,如果沒有水冷體18的話,如上述1020~980℃的OSF核形 成溫度領域會變更寬。然而,如上述藉由設置水冷體18能夠縮窄OSF核形成溫度領域,能夠縮短晶矽3通過OSF核形成溫度領域的時間(停留時間)。 When the pull-up speed of the tail portion 3d is the same as the pull-up speed of the body portion 3c, although the control of the narrowing of the tail portion becomes difficult, it is difficult to solidify the silicon melt 2 by strengthening the power of the heater 15 This situation can make tailing easier. When the power of the heater 15 is increased, the influence of its radiant heat becomes stronger. If there is no water cooling body 18, the OSF nucleus as described above at 1020 to 980 ° C The temperature range will change wide. However, as described above, the provision of the water cooling body 18 can narrow the OSF nuclei formation temperature range, and can shorten the time (residence time) for the crystalline silicon 3 to pass through the OSF nuclei formation temperature range.
如上述,尾部育成步驟中的加熱器15的功率會比體部育成步驟結束時的加熱器15的功率更大。特別是,加熱器15的功率在尾部育成步驟開始時漸增,在尾部育成結束時的尾部15的功率為尾部育成開始時的1.1~1.5倍為佳。像這樣,逐漸增加尾部育成步驟中的加熱器15的功率,且將尾部育成結束時的加熱器15的功率收在育成開始時的1.1~1.5倍的範圍內,藉此即使是在使尾部3d的拉起速度與體部3c相同的情況下也能夠實現縮尾,又能夠防止結晶彎曲或錯位化。 As described above, the power of the heater 15 in the tail rearing step will be greater than the power of the heater 15 at the end of the body rearing step. In particular, the power of the heater 15 gradually increases at the beginning of the tail rearing step, and the power of the tail 15 at the end of the rear rearing is preferably 1.1 to 1.5 times the power at the beginning of the rear rearing. In this way, gradually increase the power of the heater 15 in the tail rearing step, and the power of the heater 15 at the end of the rear rearing is within the range of 1.1 to 1.5 times at the start of rearing, whereby even the tail 3d When the pull-up speed is the same as that of the body 3c, tail shrinkage can be achieved, and the crystal can be prevented from bending or dislocation.
即使在尾部育成步驟中,逐漸上昇石英坩堝11使矽熔液2的液面位置維持一定為佳。習知技術為了提高單結晶率而盡可能減少石英坩堝11內的矽熔液2的殘量後再開始尾部育成步驟,因此尾部育成開始時石英坩堝11已經位於很高的位置,再上昇石英坩堝11的話可能會發生石英坩堝11與熱遮蔽體17干涉的狀況。因此,在尾部育成步驟的開始時或途中就必須停止上昇石英坩堝11,而熔液面的降低造成熔液面與熱遮蔽體17之間的間隔變寬,單晶矽3變得容易受到來自石英坩堝11的輻射熱的影響,產生了OSF核形成溫度領域變大的問題。 Even in the tail rearing step, it is better to gradually raise the quartz crucible 11 to maintain the liquid level of the silicon melt 2 constant. In order to improve the single crystallization rate, the conventional technique reduces the residual amount of the silicon melt 2 in the quartz crucible 11 as much as possible, and then starts the tail incubation step. If 11, the quartz crucible 11 may interfere with the heat shield 17. Therefore, it is necessary to stop raising the quartz crucible 11 at the beginning or in the middle of the tail rearing step, and the lowering of the melt surface causes the interval between the melt surface and the heat shield 17 to become wider, and the single crystal silicon 3 becomes more vulnerable to The influence of the radiant heat of the quartz crucible 11 causes a problem that the OSF nucleation temperature range becomes larger.
然而,本實施型態中,在矽熔液2被充分消耗前開始尾部育成步驟,在尾部育成步驟結束為止都一直上昇石英坩堝11使熔液面的高度位置保持一定,藉此能夠抑制來自石英坩堝11的輻射熱的影響,能夠抑制OSF核形成溫度領域變大。 However, in this embodiment, the tail incubation step is started before the silicon melt 2 is fully consumed, and the quartz crucible 11 is raised until the end of the tail incubation step to keep the height position of the melt surface constant, thereby suppressing The influence of the radiant heat of the crucible 11 can suppress the increase in the OSF nucleation temperature range.
尾部育成中結晶直徑逐漸減小,結晶拉起狀態時時刻刻地變化,因此單機性3容易錯位化。而將尾部育成中的拉起速度減慢到比習知還慢的情況下,尾部育成步驟時間變長,更增加了錯位化的風險。為了在這種條件下盡可能地減低錯位化的風險,在尾部育成步驟中將單晶矽3及石英坩堝11的旋轉速度維持一定為佳。這些旋轉速度可以與體部育成步驟中的旋轉速度相同,也可以不同。藉此,能夠使石英坩堝11內的矽熔液2的對流穩定,使熔液溫度穩定化。 The diameter of the crystal gradually decreases during the rearing of the tail, and the crystal pull-up state changes from moment to moment. Therefore, the stand-alone 3 is easily misaligned. However, when the pull-up speed in tail rearing is slowed down to be slower than conventional knowledge, the tail rearing step time becomes longer, which increases the risk of misalignment. In order to reduce the risk of misalignment as much as possible under such conditions, it is preferable to maintain the rotation speed of the single crystal silicon 3 and the quartz crucible 11 in the tail rearing step. These rotation speeds may be the same as or different from those in the body growing step. With this, the convection of the silicon melt 2 in the quartz crucible 11 can be stabilized, and the melt temperature can be stabilized.
即使在尾部育成步驟中,使磁場產生裝置21動作,施加水平磁場及垂直磁場於矽熔液2為佳。藉由這樣做,能夠使石英坩堝11內的矽熔液2的對流更穩定化。單晶矽3的尾部3d是不做為產品使用的部位,產品化的領域是體部3c,因此在尾部育成步驟S16中,不需要施加磁場來控制氧濃度位準及其表面分布等的結晶品質。在尾部育成步驟S16中為了使目前為止育成的單晶矽3的體部3c的品質不降低,迅速從矽熔液2中分離是很重要的。然而,在尾部育成中施加磁場的情況下,能夠使石英坩堝11內的矽熔液2的對流穩定,使熔液溫度穩定化,藉此能夠防止結晶彎曲或錯位化。 Even in the tail rearing step, it is preferable to operate the magnetic field generating device 21 and apply a horizontal magnetic field and a vertical magnetic field to the silicon melt 2. By doing so, the convection of the silicon melt 2 in the quartz crucible 11 can be more stabilized. The tail 3d of the monocrystalline silicon 3 is a part that is not used as a product, and the commercialized area is the body 3c. Therefore, in the tail rearing step S16, there is no need to apply a magnetic field to control the crystals such as the oxygen concentration level and its surface distribution. quality. In the tail rearing step S16, in order not to reduce the quality of the body 3c of the single crystal silicon 3 reared so far, it is important to quickly separate from the silicon melt 2. However, when a magnetic field is applied during tail growth, the convection of the silicon melt 2 in the quartz crucible 11 can be stabilized, and the melt temperature can be stabilized, thereby preventing the crystal from bending or dislocation.
第6圖係概略顯示本發明的第2實施型態的單晶製造裝置的構造的側剖面圖。 FIG. 6 is a side cross-sectional view schematically showing the structure of a single crystal manufacturing apparatus according to a second embodiment of the present invention.
如第6圖所示,單晶製造裝置1B的特徵是水冷體18是由比第1實施型態長許多的圓筒狀的構件所組成,從主腔室的上端(牽引腔室的下端)的位置往下方延伸,一直到圖中一點虛線所包圍的熱遮蔽體17的內側17i為止。也就是,水冷體 18是以盡可能更長地覆蓋單晶矽3的拉起路徑的方式設置。 As shown in FIG. 6, the single crystal manufacturing apparatus 1B is characterized in that the water-cooled body 18 is composed of a cylindrical member much longer than the first embodiment, from the upper end of the main chamber (the lower end of the traction chamber) The position extends downward until the inner side 17i of the heat shield 17 surrounded by a dotted line in the figure. That is, the water-cooled body 18 is set to cover the pulling path of the monocrystalline silicon 3 as long as possible.
本實施型態中,比熱遮蔽體17的下端17b更上方的熱遮蔽體17的內側17i,存在有水冷體18,因此能夠降低通過熱遮蔽體17的下端17b的開口後的高溫領域的溫度,能夠縮窄1020~980℃的溫度領域的結晶成長方向的寬度。因此,即使單晶矽3的拉起速度比習知更慢的情況下,也能夠縮短單晶矽3停留在1020~980℃的溫度領域的時間,能夠更快地通過OSF核形成領域,極度縮小單晶中的OSF核尺寸。 In this embodiment, the inner side 17i of the heat shield 17 above the lower end 17b of the heat shield 17 has the water-cooling body 18, so the temperature in the high-temperature area after passing through the opening of the lower end 17b of the heat shield 17 can be reduced. The width of the crystal growth direction in the temperature range of 1020 to 980 ° C can be narrowed. Therefore, even if the pulling speed of the single crystal silicon 3 is slower than conventional knowledge, the time for the single crystal silicon 3 to stay in the temperature range of 1020 to 980 ° C can be shortened, and it can pass through the OSF core formation field more quickly, extremely Reduce the size of the OSF core in the single crystal.
如以上說明,本實施型態的單晶矽製造方法會在比熱遮蔽體17的下端17b更上方的熱遮蔽體17的內側配置水冷體18,在尾部育成步驟中以水冷體18冷卻結晶化後的單晶矽3,且使用與體部3c相同的速度來拉起尾部3d,因此能夠在尾部育成步驟S16中一邊防止結晶彎曲或從熔液分離,一邊製造出OSF核(磊晶缺陷的原因)極少的高品質的單晶矽。 As described above, in the method for manufacturing single crystal silicon of this embodiment, the water-cooling body 18 is disposed inside the heat-shielding body 17 above the lower end 17b of the heat-shielding body 17, and the water-cooling body 18 is cooled and crystallized in the tail rearing step. Single crystal silicon 3, and use the same speed as the body 3c to pull up the tail 3d, so in the tail incubation step S16 can prevent the crystal bending or separation from the melt, while producing an OSF core (cause of epitaxial defects ) Very few high-quality single crystal silicon.
以上說明了本發明得較佳的實施型態,但本發明並不限定於此,在不脫離本發明的主旨的範圍內能夠做各種變更,當然這些變更也包含於本發明的範圍內。 The above has described a preferred embodiment of the present invention, but the present invention is not limited to this, and various changes can be made within a range not departing from the gist of the present invention, and of course these changes are also included in the scope of the present invention.
[實施例] [Example]
評價尾部育成步驟中的拉起速度與水冷體18的有無的不同所形成的單晶化率與磊晶缺陷的產生情況。使用第1圖所示的單晶製造裝置1A,拉起直徑300mm的單晶矽棒的樣本1~6。此時,將體部的拉起速度設定為1.0mm/min,一邊上昇石英坩堝一邊拉起單晶,使得不只在體部育成中,在尾部育成中,熔液面與熱遮蔽體的下端的間隔也維持一定。 The difference between the pull-up speed in the tail rearing step and the presence or absence of the water-cooled body 18 was evaluated, and the occurrence of the single crystallization rate and epitaxial defects. Using the single crystal manufacturing apparatus 1A shown in FIG. 1, samples 1 to 6 of a single crystal silicon rod having a diameter of 300 mm were pulled up. At this time, the pull-up speed of the body was set to 1.0 mm / min, and the single crystal was pulled up while raising the quartz crucible, so that the melt surface and the lower end of the heat shield were not only grown in the body but also in the tail. The interval is also maintained constant.
在樣本1、2中使尾部3d的拉起速度比體部3c更快(1.1倍)。又,在樣本3、4中使尾部3d的拉起速度與體部3c相等,在樣本5、6中使使尾部3d的拉起速度比體部3c更慢(0.9倍)。又,在樣本1、3、5中使用拿掉水冷體18的單晶製造裝置1A,在樣本2、4、6中使用水冷體18接地的單晶製造裝置1A。 In samples 1 and 2, the tail 3d was pulled up faster than the body 3c (1.1 times). In addition, in samples 3 and 4, the pulling speed of the tail 3d was made equal to the body 3c, and in samples 5 and 6, the pulling speed of the tail 3d was made slower (0.9 times) than the body 3c. In addition, in samples 1, 3, and 5, a single crystal manufacturing apparatus 1A with the water cooling body 18 removed was used, and in samples 2, 4, and 6, a single crystal manufacturing apparatus 1A with the water cooling body 18 grounded was used.
接著,將獲得的單晶矽棒的樣本1~6加工,製造出厚度775μm的矽晶圓(打磨晶圓),矽晶圓的表面形成4μm的磊晶層,製作出對應樣本1~6的磊晶矽晶圓。然後,以微粒子計數器測量各個磊晶矽晶圓的磊晶缺陷的個數。 Next, the samples 1 to 6 of the obtained single crystal silicon rods were processed to produce a silicon wafer (polished wafer) with a thickness of 775 μm. A 4 μm epitaxial layer was formed on the surface of the silicon wafer to produce samples corresponding to samples 1 to 6 Epitaxial silicon wafer. Then, the number of epitaxial defects of each epitaxial silicon wafer is measured by a particle counter.
表1是顯示樣本1~6的單晶化率及磊晶缺陷的評價實驗的結果的表。 Table 1 is a table showing the results of evaluation experiments on the single crystallization rate and epitaxial defects of samples 1 to 6.
如表1所示,不使用水冷體18且尾部3d的拉起速度比體部3c更高速所製造出來的樣本1中,發生尾部3d從矽熔液分離,單晶化率惡化。又,使用水冷體且尾部3d的拉起速度比體部3c更高速所製造出來的樣本2中,也發生尾部3d從矽熔液分離,單晶化率惡化。因此,無法評價這些樣本1、2的磊晶缺陷產生狀況。 As shown in Table 1, in the sample 1 manufactured without using the water-cooled body 18 and the pulling-up speed of the tail portion 3d is higher than that of the body portion 3c, separation of the tail portion 3d from the silicon melt occurs, and the single crystallization rate deteriorates. In addition, in the sample 2 manufactured using a water-cooled body and the tail part 3d is pulled faster than the body part 3c, the tail part 3d is separated from the silicon melt, and the single crystallization rate deteriorates. Therefore, the occurrence of epitaxial defects in these samples 1 and 2 cannot be evaluated.
不使用水冷體18且尾部3d的拉起速度與體部3c等 速所製造出來的樣本3中,單晶化率為75%以上,磊晶缺陷的個數是5~10個/wf。使用水冷體18且尾部3d的拉起速度與體部3c等速所製造出來的樣本4中,單晶化率為75%以上,磊晶缺陷的個數不滿5個/wf,非常地少,能夠確認到滿足了磊晶缺陷的品質基準。 The water-cooling body 18 is not used and the pulling speed of the tail 3d and the body 3c etc. In the sample 3 produced by Su, the single crystallization rate is more than 75%, and the number of epitaxial defects is 5 ~ 10 / wf. In the sample 4 produced using the water-cooled body 18 and the tail 3d is pulled up at the same speed as the body 3c, the single crystallization rate is more than 75%, and the number of epitaxial defects is less than 5 / wf, which is very small. It can be confirmed that the quality standards for epitaxial defects are met.
尾部3d的拉起速度比體部3c更慢速所製造出來的樣本5及6中,無論有無使用水冷體18,都有75%以上的高單晶化率,但磊晶缺陷有超過10個/wf之多。 In the samples 5 and 6, the tail 3d was pulled up at a slower speed than the body 3c, regardless of whether the water-cooled body 18 was used, there was a high single crystallization rate of more than 75%, but there were more than 10 epitaxial defects / wf.
從以上的結果,能夠確認到使用水冷體18且尾部3d的拉起速度與體部3c等速所製造出來的樣本4中,能夠滿足單晶化率與磊晶缺陷的雙方的品質。 From the above results, it can be confirmed that in the sample 4 manufactured using the water-cooled body 18 and the pull-up speed of the tail portion 3d and the body portion 3c at a constant speed, the quality of both the single crystallization rate and the epitaxial defects can be satisfied.
接著,在上述樣本4的條件下,模擬熔液面與熱遮蔽體17之間的間隔對單晶的結晶成長方向的溫度變化有何影響。 Next, under the conditions of the above sample 4, it is simulated how the distance between the melt surface and the heat shield 17 affects the temperature change in the crystal growth direction of the single crystal.
第7圖係顯示單晶的拉起位置與單晶的OSF核形成溫度領域(1020~980℃的領域)的通過時間的關係。第7圖的橫軸表示距離單晶的底部(尾部3d的下端)的距離,縱軸表示OSF核形成溫度領域的通過時間。 Figure 7 shows the relationship between the pull-up position of the single crystal and the passage time of the single crystal's OSF nucleation temperature range (1020 to 980 ° C range). In FIG. 7, the horizontal axis represents the distance from the bottom of the single crystal (the lower end of the tail 3d), and the vertical axis represents the passage time in the OSF nucleation temperature range.
如第7圖所示,熔液面與熱遮蔽體17的間隔(間隙△G)擴大的條件下,也就是相對於熔液面的下降,不控制石英坩堝11的上昇來將熔液面與熱遮蔽體17之間的間隔維持一定的情況下,可知當拉起位置越接近底部單晶的OSF核形成溫度領域的通過時間就變長。尾部的3d的拉起速度一定的情況下,OSF核形成溫度領域的通過時間變長表示拉起位置越接近 底部OSF核形成溫度領域就越往拉起軸方向擴大。 As shown in FIG. 7, under the condition that the gap (gap ΔG) between the melt surface and the heat shield 17 is enlarged, that is, relative to the decrease of the melt surface, the rise of the quartz crucible 11 is not controlled to change the melt surface and When the interval between the heat shields 17 is kept constant, it can be seen that the passing time of the OSF nucleus formation temperature range of the bottom single crystal becomes longer as the pulling position is closer to the bottom. When the pull-up speed of the tail 3d is constant, the passage time of the OSF nucleus formation temperature range becomes longer, indicating that the pull-up position is closer The bottom OSF nucleus formation temperature range expands toward the pull-up axis.
相對於此,熔液面與熱遮蔽體17的間隔維持一定的條件下,可知即使拉起位置接近尾部3d的下端,單晶的OSF核形成溫度領域的通過時間也沒有變得那麼長,從以上的結果,可確認到藉由在尾部育成步驟中也將熔液面與熱遮蔽體17的間隔維持一定的話,就能夠抑制OSF核形成溫度領域的擴大。 On the other hand, if the distance between the melt surface and the heat shield 17 is kept constant, it can be seen that even if the pull-up position is close to the lower end of the tail 3d, the passage time of the single crystal OSF nucleus formation temperature range does not become so long. From the above results, it can be confirmed that by maintaining a constant distance between the melt surface and the heat shield 17 during the tail rearing step, the expansion of the OSF nucleation temperature range can be suppressed.
接著,評價尾部育成步驟中的加熱器15的輸出的不同對單晶的品質的影響。將尾部育成開始時及結束時的加熱器15的功率分別設定為CkW及DkW時,在評價實驗中將加熱器功率比D/C在0.9到1.8的範圍內變化。其他的拉起條件與上述單晶化率及磊晶缺陷的評價實驗相同。 Next, the influence of the difference in the output of the heater 15 in the tail rearing step on the quality of the single crystal was evaluated. When the powers of the heater 15 at the beginning and the end of tail rearing were set to CkW and DkW, respectively, the heater power ratio D / C was changed in the range of 0.9 to 1.8 in the evaluation experiment. The other pull-up conditions are the same as the evaluation experiments of the single crystallization rate and epitaxial defects described above.
表2是顯示加熱器功率比的不同所造成的結晶育成狀況的評價實驗的結果。 Table 2 shows the results of evaluation experiments showing the crystal growth conditions caused by different heater power ratios.
如表2所示,當加熱器功率比D/C低於1.1會無法縮尾。又,當加熱器功率比超過1.5就會發生結晶彎曲,無法將尾部3d整理成漂亮的錐狀。另一方面,當加熱器功率比D/C在1.1~1.5的範圍內就能夠縮尾,能夠育成出尾部3d。 As shown in Table 2, when the heater power ratio D / C is less than 1.1, the tail will not shrink. Also, when the heater power ratio exceeds 1.5, crystal bending occurs, and the tail 3d cannot be organized into a beautiful cone shape. On the other hand, when the heater power ratio D / C is in the range of 1.1 to 1.5, the tail can be shrunk, and the tail can be bred 3d.
從以上的結果,尾部育成結束時相對於尾部育成開始時的加熱器功率比D/C滿足1.1~1.5,且尾部育成中的加熱器功率始終比尾部育成開始時大的條件下育成單晶矽,在這個情況下能夠育成出漂亮的形狀的尾部,不會發生結晶彎曲或單晶從矽熔液分離。 From the above results, the heater power ratio D / C at the end of tail rearing relative to the beginning of tail rearing satisfies 1.1 to 1.5, and the power of the heater during tail rearing is always larger than that at the beginning of tail rearing. In this case, a beautifully shaped tail can be bred without crystal bending or single crystal separation from the silicon melt.
2‧‧‧矽熔液 2‧‧‧Silver melt
3‧‧‧單晶矽 3‧‧‧Single crystal silicon
3c‧‧‧體部 3c‧‧‧Body
3d‧‧‧尾部 3d‧‧‧tail
11‧‧‧石英坩堝 11‧‧‧Quartz crucible
12‧‧‧承載器 12‧‧‧Carrier
15‧‧‧加熱器 15‧‧‧heater
17‧‧‧遮蔽體 17‧‧‧ Cover
17b‧‧‧遮蔽體下端 17b‧‧‧The lower end of the cover
17i‧‧‧遮蔽體內側 17i‧‧‧Inside of the cover
18‧‧‧水冷體 18‧‧‧Water cooling body
D‧‧‧間隔 D‧‧‧Interval
Claims (7)
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2016-049164 | 2016-03-14 | ||
JP2016049164A JP6202119B2 (en) | 2016-03-14 | 2016-03-14 | Method for producing silicon single crystal |
Publications (2)
Publication Number | Publication Date |
---|---|
TW201800625A true TW201800625A (en) | 2018-01-01 |
TWI632257B TWI632257B (en) | 2018-08-11 |
Family
ID=59850929
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
TW106104051A TWI632257B (en) | 2016-03-14 | 2017-02-08 | Single crystal silicon manufacturing method |
Country Status (6)
Country | Link |
---|---|
JP (1) | JP6202119B2 (en) |
KR (1) | KR102095597B1 (en) |
CN (1) | CN108779577B (en) |
DE (1) | DE112017001292B4 (en) |
TW (1) | TWI632257B (en) |
WO (1) | WO2017159028A1 (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI698557B (en) * | 2018-12-28 | 2020-07-11 | 環球晶圓股份有限公司 | Mono-crystalline silicon growth method and mono-crystalline silicon growth apparatus |
TWI835330B (en) * | 2022-05-31 | 2024-03-11 | 大陸商西安奕斯偉材料科技股份有限公司 | A thermal field control device for crystal pulling furnace and crystal pulling furnace |
Families Citing this family (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP6885301B2 (en) * | 2017-11-07 | 2021-06-09 | 株式会社Sumco | Single crystal manufacturing method and equipment |
JP7006573B2 (en) * | 2018-11-30 | 2022-01-24 | 株式会社Sumco | Single crystal pulling device and method for manufacturing silicon single crystal |
KR102147459B1 (en) * | 2019-01-08 | 2020-08-24 | 에스케이실트론 주식회사 | Apparatus for growing monocrystalline ingot and method for manufacturing monocrystalline ingot using the same |
JP6777908B1 (en) * | 2019-11-19 | 2020-10-28 | Ftb研究所株式会社 | Single crystal growth device, how to use the single crystal growth device, and single crystal growth method |
CN115369482A (en) * | 2021-05-21 | 2022-11-22 | 内蒙古中环协鑫光伏材料有限公司 | Limit crystal pulling process suitable for material suction experiment |
Family Cites Families (11)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH1045493A (en) * | 1996-07-30 | 1998-02-17 | Sumitomo Sitix Corp | Production op single crystal |
CN1178844A (en) * | 1996-08-08 | 1998-04-15 | Memc电子材料有限公司 | Control method for temperature and time relation of silicon by checaoski growing |
US5779791A (en) | 1996-08-08 | 1998-07-14 | Memc Electronic Materials, Inc. | Process for controlling thermal history of Czochralski-grown silicon |
JPH10194890A (en) * | 1996-12-27 | 1998-07-28 | Komatsu Electron Metals Co Ltd | Manufacture of silicon single crystal |
JP4806974B2 (en) * | 2005-06-20 | 2011-11-02 | 株式会社Sumco | Silicon single crystal growth method |
JP4760822B2 (en) * | 2007-12-14 | 2011-08-31 | 株式会社Sumco | Epitaxial wafer manufacturing method |
JP5417735B2 (en) * | 2008-04-21 | 2014-02-19 | 株式会社Sumco | Method for growing silicon single crystal |
JP5151777B2 (en) | 2008-07-30 | 2013-02-27 | 株式会社Sumco | Method for manufacturing silicon epitaxial wafer and silicon epitaxial wafer |
JP5375636B2 (en) | 2010-01-29 | 2013-12-25 | 株式会社Sumco | Method for producing silicon single crystal |
KR101467103B1 (en) | 2013-06-21 | 2014-11-28 | 주식회사 엘지실트론 | Apparatus for Growing Silicon Single Crystal And Method For Growing the Same |
CN104313682A (en) * | 2014-11-17 | 2015-01-28 | 天津市环欧半导体材料技术有限公司 | Heat field structure for fast increasing growth speed of czochralski silicon single crystal |
-
2016
- 2016-03-14 JP JP2016049164A patent/JP6202119B2/en active Active
-
2017
- 2017-01-18 WO PCT/JP2017/001493 patent/WO2017159028A1/en active Application Filing
- 2017-01-18 DE DE112017001292.9T patent/DE112017001292B4/en active Active
- 2017-01-18 CN CN201780017529.6A patent/CN108779577B/en active Active
- 2017-01-18 KR KR1020187024238A patent/KR102095597B1/en active IP Right Grant
- 2017-02-08 TW TW106104051A patent/TWI632257B/en active
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
TWI698557B (en) * | 2018-12-28 | 2020-07-11 | 環球晶圓股份有限公司 | Mono-crystalline silicon growth method and mono-crystalline silicon growth apparatus |
TWI835330B (en) * | 2022-05-31 | 2024-03-11 | 大陸商西安奕斯偉材料科技股份有限公司 | A thermal field control device for crystal pulling furnace and crystal pulling furnace |
Also Published As
Publication number | Publication date |
---|---|
JP2017165593A (en) | 2017-09-21 |
DE112017001292B4 (en) | 2023-03-16 |
DE112017001292T5 (en) | 2018-12-06 |
WO2017159028A1 (en) | 2017-09-21 |
CN108779577B (en) | 2021-01-01 |
KR102095597B1 (en) | 2020-03-31 |
CN108779577A (en) | 2018-11-09 |
JP6202119B2 (en) | 2017-09-27 |
TWI632257B (en) | 2018-08-11 |
KR20180101586A (en) | 2018-09-12 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
TWI632257B (en) | Single crystal silicon manufacturing method | |
KR102157388B1 (en) | Silicon single crystal manufacturing method and apparatus | |
US9217208B2 (en) | Apparatus for producing single crystal | |
CN110904504B (en) | Crystal pulling furnace and preparation method of single crystal silicon rod | |
US9885122B2 (en) | Method of manufacturing silicon single crystal | |
JP2001518442A (en) | Heat shield for crystal puller | |
JP2001220289A (en) | Production unit of high quality silicon single crystal | |
CN114318500A (en) | Crystal pulling furnace and method for pulling single crystal silicon rod and single crystal silicon rod | |
JP4193610B2 (en) | Single crystal manufacturing method | |
JP5145721B2 (en) | Method and apparatus for producing silicon single crystal | |
US20120279438A1 (en) | Methods for producing single crystal silicon ingots with reduced incidence of dislocations | |
TWI635199B (en) | Manufacturing method of single crystal silicon | |
JP3867476B2 (en) | Silicon single crystal manufacturing method and silicon single crystal manufacturing apparatus | |
JP6958632B2 (en) | Silicon single crystal and its manufacturing method and silicon wafer | |
JP3719088B2 (en) | Single crystal growth method | |
JP5375636B2 (en) | Method for producing silicon single crystal | |
JP5489064B2 (en) | Method for growing silicon single crystal | |
JP4272449B2 (en) | Single crystal pulling method | |
JP2020037499A (en) | Heat shield member, apparatus for pulling single crystal and method for manufacturing single crystal | |
WO2021162046A1 (en) | Method for producing silicon single crystal | |
JP2011020882A (en) | Growing method of silicon single crystal | |
JP6414161B2 (en) | Method and apparatus for producing silicon single crystal | |
JP6699620B2 (en) | Method for producing silicon single crystal | |
TW202305198A (en) | Method for producing silicon monocrystal | |
JP2002137987A (en) | Silicon single crystal pull up device, method of manufacturing silicon single crystal using that device and silicon single crystal |