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    • 3. 发明授权
    • Semiconductor device and its manufacturing method
    • 半导体器件及其制造方法
    • US08043918B2
    • 2011-10-25
    • US12840430
    • 2010-07-21
    • Takashi KuroiKatsuyuki HoritaMasashi KitazawaMasato Ishibashi
    • Takashi KuroiKatsuyuki HoritaMasashi KitazawaMasato Ishibashi
    • H01L21/336
    • H01L21/823475H01L21/743H01L21/76229H01L21/763H01L21/823481H01L21/823871H01L21/823878H01L29/7833H01L2924/0002H01L2924/00
    • To manufacture in high productivity a semiconductor device capable of securely achieving element isolation by a trench-type element isolation and capable of effectively preventing potentials of adjacent elements from affecting other nodes, a method of manufacturing the semiconductor device includes: a step of forming a first layer on a substrate; a step of forming a trench by etching the first layer and the substrate; a step of thermally oxidizing an inner wall of the trench; a step of depositing a first conductive film having a film thickness equal to or larger than one half of the trench width of the trench on the substrate including the trench; a step of removing a first conductive film from the first layer by a CMP method and keeping the first conductive film left in only the trench; a step of anisotropically etching the first conductive film within the trench to adjust the height of the conductive film to become lower than the height of the surface of the substrate; a step of depositing an insulating film on the first conductive film by the CVD method to embed the upper part of the first conductive film within the trench; a step of flattening the insulating film by the CMP method; and a step of removing the first layer.
    • 为了以高生产率制造能够通过沟槽型元件隔离可靠地实现元件隔离并且能够有效地防止相邻元件的电位影响其他节点的半导体器件,制造半导体器件的方法包括:形成第一 层; 通过蚀刻第一层和衬底形成沟槽的步骤; 热氧化沟槽内壁的步骤; 在包括沟槽的衬底上沉积膜厚度等于或大于沟槽的沟槽宽度的一半的第一导电膜的步骤; 通过CMP方法从第一层除去第一导电膜并保持第一导电膜仅留在沟槽中的步骤; 在沟槽内各向异性蚀刻第一导电膜的步骤,以调节导电膜的高度,使其低于衬底表面的高度; 通过CVD法在第一导电膜上沉积绝缘膜以将第一导电膜的上部嵌入沟槽内的步骤; 通过CMP方法使绝缘膜平坦化的步骤; 以及去除第一层的步骤。
    • 8. 发明授权
    • Semiconductor device and manufacturing method thereof
    • 半导体装置及其制造方法
    • US06707099B2
    • 2004-03-16
    • US10218444
    • 2002-08-15
    • Katsuomi ShiozawaTakashi KuroiKatsuyuki Horita
    • Katsuomi ShiozawaTakashi KuroiKatsuyuki Horita
    • H01L29792
    • H01L29/66651H01L21/28123H01L29/1033
    • A semiconductor device less susceptible to inverse narrow channel effect and its manufacturing method are provided. A silicon nitride film (13) is adopted as element isolation regions; the silicon nitride film (13) has a smaller etch rate than a sacrificial silicon oxide film (7) which serves as a sacrificial layer during ion implantation (8). This prevents formation of recesses in the silicon nitride film (13) during the removal of the sacrificial silicon oxide film (7), which weakens the strength of the electric fields at the gate edges. Weakening the strength of the electric fields at the gate edges suppresses the inverse narrow channel effect, so that the MOS transistor offers a characteristic closer to a characteristic in which the threshold voltage keeps a constant value independently of the channel width. Thus an MOS transistor having a good characteristic can be manufactured.
    • 提供了一种不易反向窄通道效应的半导体器件及其制造方法。 采用氮化硅膜(13)作为元件隔离区域; 氮化硅膜(13)具有比在离子注入期间用作牺牲层的牺牲氧化硅膜(7)更小的蚀刻速率(8)。 这样可以防止在去除牺牲氧化硅膜(7)期间在氮化硅膜(13)中形成凹陷,这削弱了栅极边缘处的电场强度。 削弱栅极边缘处的电场强度抑制了反向窄通道效应,使得MOS晶体管具有更接近阈值电压独立于沟道宽度保持恒定值的特性。 因此,可以制造具有良好特性的MOS晶体管。
    • 9. 发明授权
    • Semiconductor device and method of manufacturing same
    • 半导体装置及其制造方法
    • US06498077B2
    • 2002-12-24
    • US09816519
    • 2001-03-26
    • Shuuichi UenoKatsuyuki HoritaTakashi Kuroi
    • Shuuichi UenoKatsuyuki HoritaTakashi Kuroi
    • H01L21425
    • H01L29/1083H01L21/26586H01L27/10808H01L27/10829H01L27/10841H01L27/10873H01L29/1045H01L29/105H01L29/66537H01L29/66545H01L29/7836
    • Provided are a semiconductor device having a MOS transistor of a structure capable of obtaining a good characteristic particularly about assurance of resistance to punch-through and leak current reduction, as well as a method of manufacturing the same. That is, in addition to the usual MOS transistor structure, a channel dope region (1) is disposed at a predetermined depth so as to extend substantially the entire surface of a flat surface in a P well region (22) including a channel region. In the channel dope region (1), it is set so that the maximum value of the P type impurity concentration (MAX of P) ranges from 1×1018 to 1×1019, and the maximum value of the N type impurity concentration (MAX of N) of a source/drain region (31 (32)) is not less than 10% and not more than 100%. Note that the surface proximate region of the P well region (22) is to be beyond the object.
    • 本发明提供一种半导体器件及其制造方法,该半导体器件具有能够获得特别是耐穿孔和漏电流降低的保证的良好特性的结构的MOS晶体管。 也就是说,除了通常的MOS晶体管结构之外,通道掺杂区域(1)以预定深度设置,以便在包括沟道区域的P阱区域(22)中的基本上平坦表面的整个表面上延伸。 在通道掺杂区域(1)中,将P型杂质浓度(P的最大值)的最大值设定为1×1018〜1×1019,N型杂质浓度的最大值(N的最大值)为 源极/漏极区域(31(32))不小于10%且不大于100%。 注意,P阱区域(22)的表面邻近区域将超出对象。
    • 10. 发明授权
    • Semiconductor device
    • 半导体器件
    • US06399985B2
    • 2002-06-04
    • US09750759
    • 2001-01-02
    • Katsuyuki HoritaTakashi KuroiYoshinori Okumura
    • Katsuyuki HoritaTakashi KuroiYoshinori Okumura
    • H01L2976
    • H01L21/823481H01L21/26586H01L21/76229H01L21/76235H01L27/0207H01L29/41758
    • Provided are a semiconductor device that can obtain more output current without increasing the occupied area of a MOS transistor, and a method for manufacturing the same. MOS transistors (M11, M12) are electrically isolated by a trench isolation oxide film (21). The MOS transistor (M11) has a groove portion (GP) in which the width of the top is 20 nm to 80 nm and the depth is 50 nm to 150 nm. The groove portion (GP) is disposed at the boundary part between a trench isolation insulating film (22) and an active region (AR1) so as to surround the active region (AR1). A gate electrode (31A) is not only disposed above the active region (AR1) but also buried in the groove (GP) with a gate oxide film (30) interposed therebetween. Similarly, in the MOS transistor (M12), a groove portion (GP) is disposed at the boundary part between the trench isolation insulating film (21) and an active region (AR2) so as to surround the active region (AR2), and a gate electrode (32A) is also buried in the groove (GP) with the gate oxide film (30) interposed therebetween.
    • 提供一种可以在不增加MOS晶体管的占用面积的情况下获得更多的输出电流的半导体器件及其制造方法。 MOS晶体管(M11,M12)通过沟槽隔离氧化膜(21)电隔离。 MOS晶体管(M11)具有其顶部宽度为20nm〜80nm,深度为50nm〜150nm的槽部(GP)。 沟槽部分(GP)设置在沟道隔离绝缘膜(22)和有源区域(AR1)之间的边界部分,以围绕有源区域(AR1)。 栅电极(31A)不仅设置在有源区(AR1)的上方,而且还以栅介质膜(30)插入槽(GP)中。 类似地,在MOS晶体管(M12)中,沟槽部分(GP)设置在沟道隔离绝缘膜(21)和有源区域(AR2)之间的边界部分以包围有源区域(AR2),并且 栅极电极(32A)也被埋置在沟槽(GP)中,栅氧化膜(30)插入其间。