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    • 3. 发明授权
    • Method and apparatus for manufacturing a silicon single crystal having few crystal defects, and a silicon single crystal and silicon wafers manufactured by the same
    • 具有很少晶体缺陷的硅单晶的制造方法和装置以及由其制造的硅单晶硅晶片
    • US06364947B1
    • 2002-04-02
    • US09661985
    • 2000-09-14
    • Makoto IidaEiichi IinoMasanori KimuraShozo MuraokaHideki Yamanaka
    • Makoto IidaEiichi IinoMasanori KimuraShozo MuraokaHideki Yamanaka
    • C30B1500
    • C30B29/06C30B15/14C30B15/203C30B15/206C30B15/22Y10S117/917Y10T117/1024Y10T117/1068Y10T117/1072Y10T117/1076Y10T117/108Y10T117/1088
    • In method for manufacturing a silicon single crystal in accordance with a Czochralski method, during the growth of the silicon single crystal, pulling is performed such that a solid-liquid interface in the crystal, excluding a peripheral 5 mm-width portion, exists within a range of an average vertical position of the solid-liquid interface ±5 mm. There is also disclosed a method for manufacturing a silicon single crystal in accordance with the Czochralski method, wherein during the growth of a silicon single crystal, a furnace temperature is controlled such that a temperature gradient difference &Dgr;G (=Ge−Gc) is not greater than 5° C./cm, where Ge is a temperature gradient (° C./cm) at a peripheral portion of the crystal, and Gc is a temperature gradient (° C./cm) at a central portion of the crystal, both in an in-crystal descending temperature zone between 1420° C. and 1350° C. or between a melting point of silicon and 1400° C. in the vicinity of the solid-liquid interface of the crystal. The method maintains high productivity and enables a silicon single crystal and silicon wafers to be manufactured such that a defect density is very low over the entire crystal cross section, and the oxygen concentration distribution over the surface of each silicon wafer is improved.
    • 在使用Czochralski法制造硅单晶的方法中,在硅单晶的生长期间,进行拉伸,使得晶体内的固体 - 液体界面(不包括外围5mm宽度部分)存在于 固液界面平均垂直位置范围±5 mm。 还公开了根据Czochralski方法制造硅单晶的方法,其中在硅单晶生长期间,控制炉温,使得温度梯度差DELTAG(= Ge-Gc)不大 其中Ge是晶体周边部分的温度梯度(℃/ cm),Gc是晶体中心部分的温度梯度(℃/ cm), 在晶体的固 - 液界面附近,在1420℃和1350℃之间的晶体下降温度区域中,或在硅熔点和1400℃之间。 该方法保持高生产率,并且能够制造硅单晶和硅晶片,使得在整个晶体截面上的缺陷密度非常低,并且提高了每个硅晶片的表面上的氧浓度分布。
    • 9. 发明授权
    • Silicon single crystal wafer having few crystal defects
    • 具有很少晶体缺陷的硅单晶晶片
    • US06348180B1
    • 2002-02-19
    • US09492001
    • 2000-01-26
    • Makoto IidaSatoshi SuzukiEiichi IinoMasanori KimuraShozo Muraoka
    • Makoto IidaSatoshi SuzukiEiichi IinoMasanori KimuraShozo Muraoka
    • C30B1520
    • C30B29/06C30B15/14C30B15/203
    • A method for producing a silicon single crystal in accordance with the Czochralski method. The single crystal is grown in an N2(V) region where a large amount of precipitated oxygen and which is located within an N region located outside an OSF ring region, or is grown in a region including the OSF ring region, N1(V) and N2(V) regions located inside and outside the OSF ring region, in a defect distribution chart which shows a defect distribution in which the horizontal axis represents a radial distance D (mm) from the center of the crystal and the vertical axis represents a value of F/G (mm2/° C.·min), where F is a pulling rate (mm/min) of the single crystal, and G is an average intra-crystal temperature gradient (° C./mm) along the pulling direction within a temperature range of the melting point of silicon to 1400° C. The method allows production of silicon single crystal wafers in which neither FPDs nor L/D defects exist on the wafer surface, and gettering capability stemming from oxygen precipitation is provided over the entire wafer surface, and silicon single crystal wafers wherein OSF nuclei exit but no OSF ring appears when the wafer is subjected to thermal oxidation treatment, neither FPDs nor L/D defects exist on the wafer surface, and gettering capability is provided over the entire wafer surface.
    • 根据Czochralski法生产硅单晶的方法。 单晶生长在大量析出氧并且位于OSF环外部的N区内的N2(V)区域中,或者在包括OSF环区域N1(V)的区域中生长, 和位于OSF环区域内外的N 2(V)区域的缺陷分布图,其表示水平轴表示与晶体中心的径向距离D(mm)的缺陷分布,纵轴表示 F / G的值(mm2 /℃·min),其中F是单晶的拉伸速率(mm / min),G是沿着单晶的平均晶体内温度梯度(°C / mm) 在硅熔点的温度范围内拉伸方向为1400℃。该方法允许生产晶片表面上不存在FPD和L / D缺陷的硅单晶晶片,并且提供由氧沉淀产生的吸杂能力 整个晶圆表面和硅单晶 当晶片进行热氧化处理时,在晶片表面上不存在FPD和L / D缺陷,并且在整个晶片表面上提供吸杂能力,其中OSF核离开但没有OSF环出现。
    • 10. 发明授权
    • Silicon single crystal wafer having few crystal defects, and method for
producing the same
    • 晶体缺陷少的硅单晶晶片及其制造方法
    • US6120599A
    • 2000-09-19
    • US454841
    • 1999-12-06
    • Makoto IidaEiichi IinoMasanori KimuraShozo Muraoka
    • Makoto IidaEiichi IinoMasanori KimuraShozo Muraoka
    • C30B15/00C30B15/20C30B29/06H01L21/02H01L21/208
    • C30B29/06C30B15/203C30B15/206
    • In a method for producing a silicon single crystal wafer, a silicon single crystal is grown in accordance with the Czochralski method such that the F/G value becomes 0.112-0.142 mm.sup.2 /.degree. C..multidot.min at the center of the crystal, where F is a pulling rate (mm/min) of the single crystal, and G is an average intra-crystal temperature gradient (.degree. C./mm) along the pulling direction within a temperature range of the melting point of silicon to 1400.degree. C. Additionally, the single crystal is pulled such that the interstitial oxygen concentration becomes less than 24 ppma, or the time required to pass through a temperature zone of 1050-850.degree. C. within the crystal is controlled to become 140 minutes or less. The method allows production of silicon single crystal wafers in which neither FPDs nor L/D defects exist on the wafer surface, which therefore has an extremely low defect density, and whose entire surface is usable.
    • 在制造硅单晶晶片的方法中,根据Czochralski法生长硅单晶,使得F / G值在晶体中心处为0.112-0.142mm 2 /℃×min,其中F为 单晶的拉伸速度(mm / min),G是在硅熔点至1400℃的温度范围内沿着牵引方向的平均晶体内温度梯度(DEG C./mm)。另外 拉伸单晶,使得间隙氧浓度变得小于24ppma,或者通过晶体内的1050-850℃的温度区所需的时间被控制为140分钟以下。 该方法允许生产其中晶片表面上不存在FPD和L / D缺陷的硅单晶晶片,因此具有极低的缺陷密度,并且其整个表面可用。