会员体验
专利管家(专利管理)
工作空间(专利管理)
风险监控(情报监控)
数据分析(专利分析)
侵权分析(诉讼无效)
联系我们
交流群
官方交流:
QQ群: 891211   
微信请扫码    >>>
现在联系顾问~
热词
    • 4. 发明授权
    • Damascene method for improved MOS transistor
    • 改进MOS晶体管的镶嵌方法
    • US06806534B2
    • 2004-10-19
    • US10342423
    • 2003-01-14
    • Omer H. DokumaciBruce B. DorisOleg GluschenkovJack A. MandelmanCarl J. Radens
    • Omer H. DokumaciBruce B. DorisOleg GluschenkovJack A. MandelmanCarl J. Radens
    • H01L2976
    • H01L29/66583H01L21/26586H01L21/28114H01L29/665H01L29/66553
    • A MOSFET fabrication methodology and device structure, exhibiting improved gate activation characteristics. The gate doping that may be introduced while the source drain regions are protected by a damascene mandrel to allow for a very high doping in the gate conductors, without excessively forming deep source/drain diffusions. The high gate conductor doping minimizes the effects of electrical depletion of carriers in the gate conductor. The MOSFET fabrication methodology and device structure further results in a device having a lower gate conductor width less than the minimum lithographic minimum image, and a wider upper gate conductor portion width which may be greater than the minimum lithographic image. Since the effective channel length of the MOSFET is defined by the length of the lower gate portion, and the line resistance is determined by the width of the upper gate portion, both short channel performance and low gate resistance are satisfied simultaneously.
    • MOSFET制造方法和器件结构,表现出改进的栅极激活特性。 当源极漏极区域被镶嵌心轴保护以允许栅极导体中的非常高的掺杂而不会过度地形成深的源极/漏极扩散时,可以引入栅极掺杂。 高栅极导体掺杂最大限度地减小了栅极导体中载流子的电耗损的影响。 MOSFET制造方法和器件结构进一步导致具有小于最小光刻最小图像的较低栅极导体宽度的器件,以及可能大于最小光刻图像的较宽上部栅极导体部分宽度。 由于MOSFET的有效沟道长度由下栅极部分的长度限定,并且线路电阻由上部栅极部分的宽度决定,所以同时满足短沟道性能和低栅极电阻。
    • 8. 发明授权
    • Method for forming high performance CMOS devices with elevated sidewall spacers
    • 用于形成具有升高的侧壁间隔物的高性能CMOS器件的方法
    • US06509221B1
    • 2003-01-21
    • US10000695
    • 2001-11-15
    • Bruce B. DorisOmer H. DokumaciOleg Gluschenkov
    • Bruce B. DorisOmer H. DokumaciOleg Gluschenkov
    • H01L218238
    • H01L29/6659H01L21/26586H01L21/823864H01L29/7833
    • A method is described for making elevated sidewall spacers on the gate structure of a semiconductor device. A first insulating layer is deposited on the substrate, so that an upper portion of each of the sidewalls extends above the layer. A second insulating layer is deposited on the first layer and on the gate structure. Portions of the second layer disposed on the first layer and on the top surface of the gate structure are removed, so that a remaining portion of the second layer is disposed on the upper portion of each of the sidewalls. The first layer is then removed, so that the remaining portion of the second layer on each of the sidewalls projects laterally therefrom and is elevated with respect to the substrate. This structure is used to implant PFET and NFET extension regions without dose loss.
    • 描述了一种用于在半导体器件的栅极结构上制造升高的侧壁间隔物的方法。 第一绝缘层沉积在衬底上,使得每个侧壁的上部在层上延伸。 第二绝缘层沉积在第一层和栅极结构上。 去除设置在栅极结构的第一层和顶表面上的第二层的部分,使得第二层的剩余部分设置在每个侧壁的上部。 然后去除第一层,使得每个侧壁上的第二层的剩余部分从其侧向突出并且相对于衬底升高。 该结构用于注入PFET和NFET延伸区而没有剂量损失。
    • 9. 发明授权
    • Dual stressed SOI substrates
    • 双重应力SOI衬底
    • US07312134B2
    • 2007-12-25
    • US11741441
    • 2007-04-27
    • Dureseti ChidambarraoOmer H. DokumaciBruce B. DorisOleg GluschenkovHuilong Zhu
    • Dureseti ChidambarraoOmer H. DokumaciBruce B. DorisOleg GluschenkovHuilong Zhu
    • H01L21/84
    • H01L21/84H01L27/1203H01L29/7843Y10S438/938
    • The present invention provides a strained-Si structure, in which the nFET regions of the structure are strained in tension and the pFET regions of the structure are strained in compression. Broadly the strained-Si structure comprises a substrate; a first layered stack atop the substrate, the first layered stack comprising a compressive dielectric layer atop the substrate and a first semiconducting layer atop the compressive dielectric layer, wherein the compressive dielectric layer transfers tensile stresses to the first semiconducting layer; and a second layered stack atop the substrate, the second layered stack comprising an tensile dielectric layer atop the substrate and a second semiconducting layer atop the tensile dielectric layer, wherein the tensile dielectric layer transfers compressive stresses to the second semiconducting layer. The tensile dielectric layer and the compressive dielectric layer preferably comprise nitride, such as Si3N4.
    • 本发明提供一种应变Si结构,其中该结构的nFET区域被拉紧并且该结构的pFET区域被压缩而变形。 广义上,应变Si结构包括基底; 所述第一层叠堆叠包括位于所述衬底顶部的压缩介电层和位于所述压缩介电层顶部的第一半导体层,其中所述压缩介电层将拉伸应力传递到所述第一半导体层; 以及在所述衬底顶部的第二层叠堆叠,所述第二层叠堆叠包括位于所述衬底顶部的拉伸介电层和位于所述拉伸介电层顶部的第二半导体层,其中所述拉伸介电层将压缩应力传递到所述第二半导体层。 拉伸介电层和压电介电层优选包括氮化物,例如Si 3 N 4 N 4。