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    • 1. 发明授权
    • Methods of modulating the work functions of film layers
    • 调制膜层功能的方法
    • US07332433B2
    • 2008-02-19
    • US11233356
    • 2005-09-22
    • Kisik ChoiHusam AlshareefPrashant Majhi
    • Kisik ChoiHusam AlshareefPrashant Majhi
    • H01R24/00
    • H01L21/823842
    • Methods for fabricating two metal gate stacks with varying work functions for complementary metal oxide semiconductor (CMOS) devices are provided A first metal layer may be deposited onto a gate dielectric, followed by the deposition of a second metal layer, where the second metal layer modulated the work function of the first metal layer. The second metal layer and subsequently etch, exposing a portion of the first metal layer. A third metal layer may be deposited on the etched second metal layer and the exposed first metal layer, where the third metal layer may modulate the work function of the exposed first metal layer. Subsequent fabrication techniques may be used to define the gate stack.
    • 提供了用于制造用于互补金属氧化物半导体(CMOS)器件的具有不同功函数的两个金属栅极叠层的方法。第一金属层可沉积在栅极电介质上,随后沉积第二金属层,其中第二金属层调制 第一金属层的功函数。 第二金属层并随后蚀刻,暴露第一金属层的一部分。 可以在蚀刻的第二金属层和暴露的第一金属层上沉积第三金属层,其中第三金属层可以调节暴露的第一金属层的功函数。 可以使用随后的制造技术来定义栅极堆叠。
    • 3. 发明申请
    • Methods of modulating the work functions of film layers
    • 调制膜层功能的方法
    • US20070063296A1
    • 2007-03-22
    • US11233356
    • 2005-09-22
    • Kisik ChoiHusam AlshareefPrashant Majhi
    • Kisik ChoiHusam AlshareefPrashant Majhi
    • H01L29/94
    • H01L21/823842
    • Methods for fabricating two metal gate stacks with varying work functions for complementary metal oxide semiconductor (CMOS) devices are provided A first metal layer may be deposited onto a gate dielectric, followed by the deposition of a second metal layer, where the second metal layer modulated the work function of the first metal layer. The second metal layer and subsequently etch, exposing a portion of the first metal layer. A third metal layer may be deposited on the etched second metal layer and the exposed first metal layer, where the third metal layer may modulate the work function of the exposed first metal layer. Subsequent fabrication techniques were used to define the gate stack.
    • 提供了用于制造用于互补金属氧化物半导体(CMOS)器件的具有不同功函数的两个金属栅极叠层的方法。第一金属层可沉积在栅极电介质上,随后沉积第二金属层,其中第二金属层调制 第一金属层的功函数。 第二金属层并随后蚀刻,暴露第一金属层的一部分。 可以在蚀刻的第二金属层和暴露的第一金属层上沉积第三金属层,其中第三金属层可以调节暴露的第一金属层的功函数。 使用随后的制造技术来定义栅极堆叠。
    • 5. 发明申请
    • Nitrogen Profile in High-K Dielectrics Using Ultrathin Disposable Capping Layers
    • 使用超薄一次性封盖层的高K电介质中的氮分布
    • US20090104743A1
    • 2009-04-23
    • US11860066
    • 2007-09-24
    • Husam AlshareefManuel Quevedo Lopez
    • Husam AlshareefManuel Quevedo Lopez
    • H01L21/8238H01L21/3115
    • H01L21/28238H01L21/28202H01L21/823857H01L29/518H01L29/6659H01L29/7833
    • Metal Oxide Semiconductor (MOS) transistors fabricated using current art may utilize a nitridation process on the gate dielectric to improve transistor reliability. Nitridation by the current art, which involves exposing the gate dielectric to a nitridation source, produces a significant concentration of nitrogen at the interface of the gate dielectric and the transistor substrate, which adversely affects transistor performance. This invention comprises the process of depositing a sacrificial layer on the gate dielectric prior to nitridation, exposing the sacrificial layer to a nitridation source, during which time nitrogen atoms diffuse through the sacrificial layer into the gate dielectric, then removing the sacrificial layer without degrading the gate dielectric. Work associated with this invention on high-k gate dielectrics has demonstrated a 20 percent reduction in nitrogen concentration at the gate dielectric-transistor substrate interface.
    • 使用现有技术制造的金属氧化物半导体(MOS)晶体管可以利用栅极电介质上的氮化工艺来提高晶体管的可靠性。 目前的技术的氮化,其涉及将栅极电介质暴露于氮化源,在栅极电介质和晶体管衬底的界面处产生显着的氮浓度,这对晶体管性能产生不利影响。 本发明包括在氮化之前在栅极电介质上沉积牺牲层的过程,将牺牲层暴露于氮化源,在此期间氮原子通过牺牲层扩散到栅极电介质中,然后去除牺牲层而不降低 栅电介质。 与本发明相关的高k栅极电介质的工作已经证明了在栅极介电晶体管衬底界面处的氮浓度降低了20%。