SELF-ALIGNED EMBEDDED SiGe STRUCTURE AND METHOD OF MANUFACTURING THE SAME
    1.
    发明申请
    SELF-ALIGNED EMBEDDED SiGe STRUCTURE AND METHOD OF MANUFACTURING THE SAME 失效
    自对准嵌入式SiGe结构及其制造方法

    公开(公告)号:US20120208337A1

    公开(公告)日:2012-08-16

    申请号:US13456633

    申请日:2012-04-26

    IPC分类号: H01L21/336

    摘要: A low energy surface is formed by a high temperature anneal of the surfaces of trenches on each side of a gate stack. The material of the semiconductor layer reflows during the high temperature anneal such that the low energy surface is a crystallographic surface that is at a non-orthogonal angle with the surface normal of the semiconductor layer. A lattice mismatched semiconductor material is selectively grown on the semiconductor layer to fill the trenches, thereby forming embedded lattice mismatched semiconductor material portions in source and drain regions of a transistor. The embedded lattice mismatched semiconductor material portions can be in-situ doped without increasing punch-through. Alternately, a combination of intrinsic selective epitaxy and ion implantation can be employed to form deep source and drain regions.

    摘要翻译: 低能量表面通过栅极堆叠的每一侧的沟槽表面的高温退火形成。 半导体层的材料在高温退火期间回流,使得低能表面是与半导体层的表面法线成非正交角的结晶表面。 在半导体层上选择性地生长晶格失配的半导体材料以填充沟槽,从而在晶体管的源极和漏极区域中形成嵌入的晶格失配的半导体材料部分。 嵌入的晶格不匹配的半导体材料部分可以原位掺杂而不增加穿通。 或者,可以采用固有选择性外延和离子注入的组合来形成深的源极和漏极区域。

    Self-aligned embedded SiGe structure and method of manufacturing the same
    2.
    发明授权
    Self-aligned embedded SiGe structure and method of manufacturing the same 失效
    自对准嵌入式SiGe结构及其制造方法

    公开(公告)号:US08598009B2

    公开(公告)日:2013-12-03

    申请号:US13456633

    申请日:2012-04-26

    IPC分类号: H01L21/8222

    摘要: A low energy surface is formed by a high temperature anneal of the surfaces of trenches on each side of a gate stack. The material of the semiconductor layer reflows during the high temperature anneal such that the low energy surface is a crystallographic surface that is at a non-orthogonal angle with the surface normal of the semiconductor layer. A lattice mismatched semiconductor material is selectively grown on the semiconductor layer to fill the trenches, thereby forming embedded lattice mismatched semiconductor material portions in source and drain regions of a transistor. The embedded lattice mismatched semiconductor material portions can be in-situ doped without increasing punch-through. Alternately, a combination of intrinsic selective epitaxy and ion implantation can be employed to form deep source and drain regions.

    摘要翻译: 低能量表面通过栅极堆叠的每一侧的沟槽表面的高温退火形成。 半导体层的材料在高温退火期间回流,使得低能表面是与半导体层的表面法线成非正交角的结晶表面。 在半导体层上选择性地生长晶格失配的半导体材料以填充沟槽,从而在晶体管的源极和漏极区域中形成嵌入的晶格失配的半导体材料部分。 嵌入的晶格不匹配的半导体材料部分可以原位掺杂而不增加穿通。 或者,可以采用固有选择性外延和离子注入的组合来形成深的源极和漏极区域。

    Self-aligned embedded SiGe structure and method of manufacturing the same
    3.
    发明授权
    Self-aligned embedded SiGe structure and method of manufacturing the same 失效
    自对准嵌入式SiGe结构及其制造方法

    公开(公告)号:US08222673B2

    公开(公告)日:2012-07-17

    申请号:US12795683

    申请日:2010-06-08

    IPC分类号: H01L21/02

    摘要: A low energy surface is formed by a high temperature anneal of the surfaces of trenches on each side of a gate stack. The material of the semiconductor layer reflows during the high temperature anneal such that the low energy surface is a crystallographic surface that is at a non-orthogonal angle with the surface normal of the semiconductor layer. A lattice mismatched semiconductor material is selectively grown on the semiconductor layer to fill the trenches, thereby forming embedded lattice mismatched semiconductor material portions in source and drain regions of a transistor. The embedded lattice mismatched semiconductor material portions can be in-situ doped without increasing punch-through. Alternately, a combination of intrinsic selective epitaxy and ion implantation can be employed to form deep source and drain regions.

    摘要翻译: 低能量表面通过栅极堆叠的每一侧的沟槽表面的高温退火形成。 半导体层的材料在高温退火期间回流,使得低能表面是与半导体层的表面法线成非正交角的结晶表面。 在半导体层上选择性地生长晶格失配的半导体材料以填充沟槽,从而在晶体管的源极和漏极区域中形成嵌入的晶格失配的半导体材料部分。 嵌入的晶格不匹配的半导体材料部分可以原位掺杂而不增加穿通。 或者,可以采用固有选择性外延和离子注入的组合来形成深的源极和漏极区域。

    Transistor having V-shaped embedded stressor
    4.
    发明授权
    Transistor having V-shaped embedded stressor 有权
    具有V形嵌入应力的晶体管

    公开(公告)号:US07989298B1

    公开(公告)日:2011-08-02

    申请号:US12692859

    申请日:2010-01-25

    IPC分类号: H01L21/336 H01L21/76

    摘要: A semiconductor device and a method of making the device are provided. The method can include forming a gate conductor overlying a major surface of a monocrystalline semiconductor region and forming first spacers on exposed walls of the gate conductor. Using the gate conductor and the first spacers as a mask, at least extension regions are implanted in the semiconductor region and dummy spacers are formed extending outward from the first spacers. Using the dummy spacers as a mask, the semiconductor region is etched to form recesses having at least substantially straight walls extending downward from the major surface to a bottom surface, such that a substantial angle is defined between the bottom surface and the walls. Subsequently, the process is continued by epitaxially growing regions of stressed monocrystalline semiconductor material within the recesses. Then the dummy spacers are removed and the transistor can be completed by forming source/drain regions of the transistor that are at least partially disposed in the stressed semiconductor material regions.

    摘要翻译: 提供半导体器件和制造该器件的方法。 该方法可以包括形成覆盖在单晶半导体区域的主表面上的栅极导体并且在栅极导体的暴露的壁上形成第一间隔物。 使用栅极导体和第一间隔物作为掩模,至少延伸区域注入到半导体区域中,并且形成从第一间隔物向外延伸的虚设间隔物。 使用虚拟间隔件作为掩模,半导体区域被蚀刻以形成具有从主表面向底表面向下延伸的至少基本上直的壁的凹槽,使得在底表面和壁之间限定大的角度。 随后,通过在凹槽内外延生长应力单晶半导体材料的区域来继续该过程。 然后去除虚拟间隔物,并且可以通过形成至少部分地设置在受应力的半导体材料区域中的晶体管的源极/漏极区域来完成晶体管。

    TRANSISTOR HAVING V-SHAPED EMBEDDED STRESSOR
    5.
    发明申请
    TRANSISTOR HAVING V-SHAPED EMBEDDED STRESSOR 有权
    具有V形嵌入式应力的晶体管

    公开(公告)号:US20110183486A1

    公开(公告)日:2011-07-28

    申请号:US12692859

    申请日:2010-01-25

    IPC分类号: H01L21/336

    摘要: A semiconductor device and a method of making the device are provided. The method can include forming a gate conductor overlying a major surface of a monocrystalline semiconductor region and forming first spacers on exposed walls of the gate conductor. Using the gate conductor and the first spacers as a mask, at least extension regions are implanted in the semiconductor region and dummy spacers are formed extending outward from the first spacers. Using the dummy spacers as a mask, the semiconductor region is etched to form recesses having at least substantially straight walls extending downward from the major surface to a bottom surface, such that a substantial angle is defined between the bottom surface and the walls. Subsequently, the process is continued by epitaxially growing regions of stressed monocrystalline semiconductor material within the recesses. Then the dummy spacers are removed and the transistor can be completed by forming source/drain regions of the transistor that are at least partially disposed in the stressed semiconductor material regions.

    摘要翻译: 提供半导体器件和制造该器件的方法。 该方法可以包括形成覆盖在单晶半导体区域的主表面上的栅极导体并且在栅极导体的暴露的壁上形成第一间隔物。 使用栅极导体和第一间隔物作为掩模,至少延伸区域注入到半导体区域中,并且形成从第一间隔物向外延伸的虚设间隔物。 使用虚拟间隔件作为掩模,半导体区域被蚀刻以形成具有从主表面向底表面向下延伸的至少基本上直的壁的凹槽,使得在底表面和壁之间限定大的角度。 随后,通过在凹槽内外延生长应力单晶半导体材料的区域来继续该过程。 然后去除虚拟间隔物,并且可以通过形成至少部分地设置在受应力的半导体材料区域中的晶体管的源极/漏极区域来完成晶体管。

    EMBEDDED SILICON GERMANIUM SOURCE DRAIN STRUCTURE WITH REDUCED SILICIDE ENCROACHMENT AND CONTACT RESISTANCE AND ENHANCED CHANNEL MOBILITY
    6.
    发明申请
    EMBEDDED SILICON GERMANIUM SOURCE DRAIN STRUCTURE WITH REDUCED SILICIDE ENCROACHMENT AND CONTACT RESISTANCE AND ENHANCED CHANNEL MOBILITY 有权
    嵌入式硅锗锗排水结构,具有降低的硅胶密封性和接触电阻和增强的通道移动性

    公开(公告)号:US20110062498A1

    公开(公告)日:2011-03-17

    申请号:US12561685

    申请日:2009-09-17

    IPC分类号: H01L29/772 H01L21/335

    摘要: Semiconductor devices with embedded silicon germanium source/drain regions are formed with enhanced channel mobility, reduced contact resistance, and reduced silicide encroachment. Embodiments include embedded silicon germanium source/drain regions with a first portion having a relatively high germanium concentration, e.g., about 25 to about 35 at. %, an overlying second portion having a first layer with a relatively low germanium concentration, e.g., about 10 to about 20 at. %, and a second layer having a germanium concentration greater than that of the first layer. Embodiments include forming additional layers on the second layer, each odd numbered layer having relatively low germanium concentration, at. % germanium, and each even numbered layer having a relatively high germanium concentration. Embodiments include forming the first region at a thickness of about 400 Å to 28 about 800 Å, and the first and second layers at a thickness of about 30 Å to about 70 Å.

    摘要翻译: 具有嵌入式硅锗源极/漏极区域的半导体器件形成具有增强的沟道迁移率,降低的接触电阻和减少的硅化物侵蚀。 实施例包括具有较高锗浓度的第一部分的嵌入式硅锗源/漏区,例如约25至约35at。 %,上覆的第二部分具有具有相对低的锗浓度的第一层,例如约10至约20at。 %,第二层的锗浓度大于第一层的浓度。 实施例包括在第二层上形成附加层,每个奇数层具有较低的锗浓度。 %锗,并且每个偶数层具有较高的锗浓度。 实施例包括形成厚度为约400至28约800的第一区域,第一和第二层的厚度为约至大约为70埃。

    Embedded silicon germanium source drain structure with reduced silicide encroachment and contact resistance and enhanced channel mobility
    7.
    发明授权
    Embedded silicon germanium source drain structure with reduced silicide encroachment and contact resistance and enhanced channel mobility 有权
    嵌入式硅锗源极漏极结构,具有减少的硅化物侵蚀和接触电阻以及增强的沟道迁移率

    公开(公告)号:US08120120B2

    公开(公告)日:2012-02-21

    申请号:US12561685

    申请日:2009-09-17

    IPC分类号: H01L29/772 H01L21/335

    摘要: Semiconductor devices with embedded silicon germanium source/drain regions are formed with enhanced channel mobility, reduced contact resistance, and reduced silicide encroachment. Embodiments include embedded silicon germanium source/drain regions with a first portion having a relatively high germanium concentration, e.g., about 25 to about 35 at. %, an overlying second portion having a first layer with a relatively low germanium concentration, e.g., about 10 to about 20 at. %, and a second layer having a germanium concentration greater than that of the first layer. Embodiments include forming additional layers on the second layer, each odd numbered layer having relatively low germanium concentration, at. % germanium, and each even numbered layer having a relatively high germanium concentration. Embodiments include forming the first region at a thickness of about 400 Å to 28 about 800 Å, and the first and second layers at a thickness of about 30 Å to about 70 Å.

    摘要翻译: 具有嵌入式硅锗源极/漏极区域的半导体器件形成具有增强的沟道迁移率,降低的接触电阻和减少的硅化物侵蚀。 实施例包括具有较高锗浓度的第一部分的嵌入式硅锗源/漏区,例如约25至约35at。 %,上覆的第二部分具有具有相对低的锗浓度的第一层,例如约10至约20at。 %,第二层的锗浓度大于第一层的浓度。 实施例包括在第二层上形成附加层,每个奇数层具有较低的锗浓度。 %锗,并且每个偶数层具有较高的锗浓度。 实施例包括形成厚度为约400至28约800的第一区域,第一和第二层的厚度为约至大约为70埃。

    SELF-ALIGNED EMBEDDED SiGe STRUCTURE AND METHOD OF MANUFACTURING THE SAME
    8.
    发明申请
    SELF-ALIGNED EMBEDDED SiGe STRUCTURE AND METHOD OF MANUFACTURING THE SAME 失效
    自对准嵌入式SiGe结构及其制造方法

    公开(公告)号:US20110298008A1

    公开(公告)日:2011-12-08

    申请号:US12795683

    申请日:2010-06-08

    IPC分类号: H01L29/78 H01L21/336

    摘要: A low energy surface is formed by a high temperature anneal of the surfaces of trenches on each side of a gate stack. The material of the semiconductor layer reflows during the high temperature anneal such that the low energy surface is a crystallographic surface that is at a non-orthogonal angle with the surface normal of the semiconductor layer. A lattice mismatched semiconductor material is selectively grown on the semiconductor layer to fill the trenches, thereby forming embedded lattice mismatched semiconductor material portions in source and drain regions of a transistor. The embedded lattice mismatched semiconductor material portions can be in-situ doped without increasing punch-through. Alternately, a combination of intrinsic selective epitaxy and ion implantation can be employed to form deep source and drain regions.

    摘要翻译: 低能量表面通过栅极堆叠的每一侧的沟槽表面的高温退火形成。 半导体层的材料在高温退火期间回流,使得低能表面是与半导体层的表面法线成非正交角的结晶表面。 在半导体层上选择性地生长晶格失配的半导体材料以填充沟槽,从而在晶体管的源极和漏极区域中形成嵌入的晶格失配的半导体材料部分。 嵌入的晶格不匹配的半导体材料部分可以原位掺杂而不增加穿通。 或者,可以采用固有选择性外延和离子注入的组合来形成深的源极和漏极区域。