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    • 1. 发明授权
    • Semiconductor device
    • 半导体器件
    • US08796744B1
    • 2014-08-05
    • US13812504
    • 2012-10-12
    • Xiaolong MaHuaxiang YinSen XuHuilong Zhu
    • Xiaolong MaHuaxiang YinSen XuHuilong Zhu
    • H01L27/148H01L29/768H01L29/775
    • H01L29/775H01L29/161H01L29/165H01L29/517H01L29/518H01L29/66431H01L29/66545H01L29/7786
    • The present invention discloses a semiconductor device, which comprises a substrate, a buffer layer on the substrate, an inversely doped isolation layer on the buffer layer, a barrier layer on the inversely doped isolation layer, a channel layer on the barrier layer, a gate stack structure on the channel layer, and source and drain regions at both sides of the gate stack structure, characterized in that the buffer layer and/or the barrier layer and/or the inversely doped isolation layer are formed of SiGe alloys or SiGeSn alloys, and the channel layer is formed of a GeSn alloy. The semiconductor device according to the present invention uses a quantum well structure of SiGe/GeSn/SiGe to restrict transportation of carriers, and it introduces a stress through lattice mis-match to greatly increase the carrier mobility, thus improving the device driving capability so as to be adapted to high-speed and high-frequency application.
    • 本发明公开了一种半导体器件,其包括衬底,衬底上的缓冲层,缓冲层上的反掺杂隔离层,反掺杂隔离层上的阻挡层,阻挡层上的沟道层,栅极 沟道层上的堆叠结构以及栅极堆叠结构两侧的源极和漏极区域,其特征在于缓冲层和/或势垒层和/或反向掺杂隔离层由SiGe合金或SiGeSn合金形成, 并且沟道层由GeSn合金形成。 根据本发明的半导体器件使用SiGe / GeSn / SiGe的量子阱结构来限制载流子的传输,并且通过晶格失配引入应力以大大增加载流子迁移率,从而提高器件驱动能力,从而 适应高速高频应用。
    • 2. 发明申请
    • Semiconductor Device
    • 半导体器件
    • US20140197376A1
    • 2014-07-17
    • US13812504
    • 2012-10-12
    • Xiaolong MaHuaxiang YinSen XuHuilong Zhu
    • Xiaolong MaHuaxiang YinSen XuHuilong Zhu
    • H01L29/775
    • H01L29/775H01L29/161H01L29/165H01L29/517H01L29/518H01L29/66431H01L29/66545H01L29/7786
    • The present invention discloses a semiconductor device, which comprises a substrate, a buffer layer on the substrate, an inversely doped isolation layer on the buffer layer, a barrier layer on the inversely doped isolation layer, a channel layer on the barrier layer, a gate stack structure on the channel layer, and source and drain regions at both sides of the gate stack structure, characterized in that the buffer layer and/or the barrier layer and/or the inversely doped isolation layer are formed of SiGe alloys or SiGeSn alloys, and the channel layer is formed of a GeSn alloy. The semiconductor device according to the present invention uses a quantum well structure of SiGe/GeSn/SiGe to restrict transportation of carriers, and it introduces a stress through lattice mis-match to greatly increase the carrier mobility, thus improving the device driving capability so as to be adapted to high-speed and high-frequency application.
    • 本发明公开了一种半导体器件,其包括衬底,衬底上的缓冲层,缓冲层上的反掺杂隔离层,反掺杂隔离层上的阻挡层,阻挡层上的沟道层,栅极 沟道层上的堆叠结构以及栅极堆叠结构两侧的源极和漏极区域,其特征在于缓冲层和/或势垒层和/或反向掺杂隔离层由SiGe合金或SiGeSn合金形成, 并且沟道层由GeSn合金形成。 根据本发明的半导体器件使用SiGe / GeSn / SiGe的量子阱结构来限制载流子的传输,并且通过晶格失配引入应力以大大增加载流子迁移率,从而提高器件驱动能力,从而 适应高速高频应用。
    • 6. 发明授权
    • Semiconductor device and method for manufacturing the same
    • 半导体装置及其制造方法
    • US08846488B2
    • 2014-09-30
    • US13578598
    • 2011-11-30
    • Qingqing LiangHuaxiang YinHuicai ZhongHuilong Zhu
    • Qingqing LiangHuaxiang YinHuicai ZhongHuilong Zhu
    • H01L21/76H01L29/78H01L21/762H01L21/265
    • H01L21/76224H01L21/26506H01L29/7842H01L29/7847
    • The invention relates to a semiconductor device and a method for manufacturing such a semiconductor device. A semiconductor device according to an embodiment of the invention may comprise: a substrate; a device region located on the substrate; and at least one stress introduction region separated from the device region by an isolation structure, with stress introduced into at least a portion of the at least one stress introduction region, wherein the stress introduced into the at least a portion of the at least one stress introduction region is produced by utilizing laser to illuminate an amorphized portion comprised in the at least one stress introduction region to recrystallize the amorphized portion. The semiconductor device according to an embodiment of the invention produces stress in a simpler manner and thereby improves the performance of the device.
    • 本发明涉及半导体器件及其制造方法。 根据本发明的实施例的半导体器件可以包括:衬底; 位于所述基板上的器件区域; 以及至少一个应力引入区域,其通过隔离结构从所述器件区域分离,其中所述应力引入所述至少一个应力引入区域的至少一部分,其中所述应力引入所述至少一个应力的至少一部分 引入区域通过利用激光照射包含在至少一个应力导入区域中的非晶化部分以使非晶化部分重结晶而产生。 根据本发明的实施例的半导体器件以更简单的方式产生应力,从而提高器件的性能。
    • 7. 发明申请
    • Semiconductor Device and Method for Manufacturing the Same
    • 半导体装置及其制造方法
    • US20130093041A1
    • 2013-04-18
    • US13578598
    • 2011-11-30
    • Qingqing LiangHuaxiang YinHuicai ZhongHuilong Zhu
    • Qingqing LiangHuaxiang YinHuicai ZhongHuilong Zhu
    • H01L29/06H01L21/762
    • H01L21/76224H01L21/26506H01L29/7842H01L29/7847
    • The invention relates to a semiconductor device and a method for manufacturing such a semiconductor device. A semiconductor device according to an embodiment of the invention may comprise: a substrate; a device region located on the substrate; and at least one stress introduction region separated from the device region by an isolation structure, with stress introduced into at least a portion of the at least one stress introduction region, wherein the stress introduced into the at least a portion of the at least one stress introduction region is produced by utilizing laser to illuminate an amorphized portion comprised in the at least one stress introduction region to recrystallize the amorphized portion. The semiconductor device according to an embodiment of the invention produces stress in a simpler manner and thereby improves the performance of the device.
    • 本发明涉及半导体器件及其制造方法。 根据本发明的实施例的半导体器件可以包括:衬底; 位于所述基板上的器件区域; 以及至少一个应力引入区域,其通过隔离结构从所述器件区域分离,其中所述应力引入所述至少一个应力引入区域的至少一部分,其中所述应力引入所述至少一个应力的至少一部分 引入区域通过利用激光照射包含在至少一个应力导入区域中的非晶化部分以使非晶化部分重结晶而产生。 根据本发明的实施例的半导体器件以更简单的方式产生应力,从而提高器件的性能。
    • 10. 发明授权
    • Enhancing MOSFET performance with corner stresses of STI
    • 通过STI拐角应力增强MOSFET性能
    • US09356025B2
    • 2016-05-31
    • US14348579
    • 2012-03-29
    • Huilong ZhuZhijiong LuoHaizhou Yin
    • Huilong ZhuZhijiong LuoHaizhou Yin
    • H01L27/092H01L29/78H01L21/8238H01L21/762H01L29/66
    • H01L27/092H01L21/76224H01L21/823807H01L21/823878H01L29/66575H01L29/7846
    • The present invention relates to enhancing MOSFET performance with the corner stresses of STI. A method of manufacturing a MOS device comprises the steps of: providing a semiconductor substrate; forming trenches on the semiconductor substrate and at least a pMOS region and at least an nMOS region surrounded by the trenches; filling the trenches with a dielectric material having a stress; removing at least the dielectric material having a stress in the trenches which is adjacent to a position where a channel is to be formed on each of the pMOS and nMOS regions so as to form exposed regions; filling the exposed regions with a insulating material; and forming pMOS and nMOS devices on the pMOS region and the nMOS region, respectively, wherein each of the pMOS and nMOS devices comprises a channel, a gate formed above the channel, and a source and a drain formed at both sides of the channel; wherein in a channel length direction, the boundary of each exposed region is substantially aligned with the boundary of the position of the channel, or the boundary of each exposed region extends along the channel length direction to be aligned with the boundary of corresponding pMOS or nMOS region.
    • 本发明涉及利用STI的拐角应力来增强MOSFET的性能。 一种制造MOS器件的方法包括以下步骤:提供半导体衬底; 在所述半导体衬底和至少一个pMOS区域和由所述沟槽包围的至少nMOS区域中形成沟槽; 用具有应力的介电材料填充沟槽; 至少去除在沟道中具有应力的介电材料,所述沟槽邻近要在pMOS和nMOS区域中的每一个上形成沟道的位置,以形成暴露区域; 用绝缘材料填充暴露的区域; 以及分别在pMOS区域和nMOS区域上形成pMOS和nMOS器件,其中pMOS和nMOS器件中的每一个包括沟道,形成在沟道上方的栅极以及形成在沟道两侧的源极和漏极; 其中在通道长度方向上,每个曝光区域的边界基本上与通道位置的边界对齐,或者每个曝光​​区域的边界沿着沟道长度方向延伸以与对应的pMOS或nMOS的边界对准 地区。