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    • 71. 发明授权
    • Integrated circuit having pairs of parallel complementary FinFETs
    • 具有成对的并联互补FinFET的集成电路
    • US07517806B2
    • 2009-04-14
    • US11186748
    • 2005-07-21
    • Andres BryantWilliam F. Clark, Jr.David M. FriedMark D. JaffeEdward J. NowakJohn J. PekarikChristopher S. Putnam
    • Andres BryantWilliam F. Clark, Jr.David M. FriedMark D. JaffeEdward J. NowakJohn J. PekarikChristopher S. Putnam
    • H01L21/302
    • H01L21/84H01L21/3086H01L21/3088H01L21/823821H01L27/1203H01L29/66795H01L29/785Y10S438/947
    • A method and structure for an integrated circuit structure that utilizes complementary fin-type field effect transistors (FinFETs) is disclosed. The invention has a first-type of FinFET which includes a first fin, and a second-type of FinFET which includes a second fin running parallel to the first fin. The invention also has an insulator fin positioned between the source/drain regions of the first first-type of FinFET and the second-type of FinFET. The insulator fin has approximately the same width dimensions as the first fin and the second fin, such that the spacing between the first-type of FinFET and the second-type of FinFET is approximately equal to the width of one fin. The invention also has a common gate formed over channel regions of the first-type of FinFET and the second-type of FinFET. The gate includes a first impurity doping region adjacent the first-type of FinFET and a second impurity doping region adjacent the second-type of FinFET. The differences between the first impurity doping region and the second impurity doping region provide the gate with different work functions related to differences between the first-type of FinFET and the second-type of FinFET. The first fin and the second fin have approximately the same width.
    • 公开了利用互补翅片型场效应晶体管(FinFET)的集成电路结构的方法和结构。 本发明具有包括第一鳍片的第一类型的FinFET和包括与第一鳍片平行的第二鳍片的第二类型的FinFET。 本发明还具有位于第一第一类型FinFET的源极/漏极区域和第二类型FinFET之间的绝缘体鳍片。 绝缘体鳍片具有与第一鳍片和第二鳍片大致相同的宽度尺寸,使得第一类型的FinFET和第二类型的FinFET之间的间隔大致等于一个鳍片的宽度。 本发明还具有形成在第一类型FinFET和第二类型FinFET的沟道区上的公共栅极。 栅极包括与第一类型的FinFET相邻的第一杂质掺杂区域和与第二类型的FinFET相邻的第二杂质掺杂区域。 第一杂质掺杂区域和第二杂质掺杂区域之间的差异为栅极提供与第一类型FinFET和第二类型FinFET之间的差异有关的不同功函数。 第一鳍片和第二鳍片具有大致相同的宽度。
    • 72. 发明申请
    • IMAGERS HAVING ELECTRICALLY ACTIVE OPTICAL ELEMENTS
    • 具有电动活性光学元件的图像
    • US20090065834A1
    • 2009-03-12
    • US11850798
    • 2007-09-06
    • Brent A. AndersonJohn J. Ellis-MonaghanEdward J. Nowak
    • Brent A. AndersonJohn J. Ellis-MonaghanEdward J. Nowak
    • H01L27/146
    • H01L27/14636H01L27/14625
    • A CMOS image sensor comprising an array of active pixel cells. Each active pixel cell includes a substrate; a photosensing device formed at or below a substrate surface for collecting charge carriers in response to incident light; and, one or more light transmissive conductive wire structures formed above the photosensing device, the one or more conductive wire structures being located in an optical path above the photosensing device. The formed light transmissive conductive wire structures provide both an electrical and optical functions. An optical function is provided by tailoring the thickness of the conductive wire layer to filter light according to a pixel color scheme. Alternately, the light transmissive conductive wire structures may be formed as a microlens structure providing a light focusing function. Electrical functions for the conductive wire layer include use as a capacitor plate, as a resistor or as an interconnect.
    • 一种包括有源像素单元阵列的CMOS图像传感器。 每个有源像素单元包括衬底; 形成在基板表面处或下方的光敏装置,用于响应于入射光收集电荷载体; 以及形成在光敏器件上方的一个或多个透光导线结构,所述一个或多个导电线结构位于光敏器件上方的光路中。 形成的透光导线结构提供电和光学功能。 通过根据像素配色方案调整导线层的厚度以过滤光,提供光学功能。 或者,透光导线结构可以形成为提供光聚焦功能的微透镜结构。 用于导线层的电气功能包括用作电容器板,电阻器或互连件。
    • 76. 发明申请
    • DUAL WORK-FUNCTION SINGLE GATE STACK
    • 双功能单门机柜
    • US20080299711A1
    • 2008-12-04
    • US12175528
    • 2008-07-18
    • Brent A. AndersonEdward J. Nowak
    • Brent A. AndersonEdward J. Nowak
    • H01L21/84
    • H01L27/1203H01L21/823807H01L21/82385H01L21/84
    • Disclosed is a complementary CMOS device having a first FET with sidewall channels and a second FET with a planar channel. The first FET can be a p-FET and the second FET can be an n-FET or vice versa. The conductor used to form the gate electrodes of the different type FETs is different and is pre-selected to optimize performance. For example, a p-FET gate electrode material can have a work function near the valence band and an n-FET gate electrode material can have a work function near the conduction band. The first gate electrodes of the first FET are located adjacent to the sidewall channels and the second gate electrode of the second FET is located above the planar channel. However, the device structure is unique in that the second gate electrode extends laterally above the first FET and is electrically coupled to the first gate electrodes.
    • 公开了具有具有侧壁通道的第一FET和具有平面通道的第二FET的互补CMOS器件。 第一个FET可以是p-FET,第二个FET可以是n-FET,反之亦然。 用于形成不同类型FET的栅电极的导体是不同的,并且是预选的以优化性能。 例如,p-FET栅极材料可以在价带附近具有功函数,并且n-FET栅电极材料可以在导带附近具有功函数。 第一FET的第一栅电极位于与侧壁通道相邻并且第二FET的第二栅电极位于平面通道上方。 然而,器件结构是唯一的,因为第二栅电极横向于第一FET上方延伸并且电耦合到第一栅电极。
    • 77. 发明申请
    • Method for FEOL and BEOL Wiring
    • FEOL和BEOL接线方法
    • US20080284021A1
    • 2008-11-20
    • US11749898
    • 2007-05-17
    • Brent A. AndersonJohn J. Ellis-MonaghanEdward J. NowakJed H. Rankin
    • Brent A. AndersonJohn J. Ellis-MonaghanEdward J. NowakJed H. Rankin
    • H01L21/44H01L23/48
    • H01L21/76885H01L21/76843H01L21/76844H01L21/76867H01L21/76895H01L28/91H01L2924/0002H01L2924/00
    • A method for forming a conductive structure of sub-lithographic dimension suitable for FEOL and BEOL semiconductor fabrication applications. The method includes forming a topographic feature of silicon-containing material on a substrate; forming a dielectric cap on the topographic feature; applying a mask structure to expose a pattern on a sidewall of the topographic feature, the exposed pattern corresponding to a conductive structure to be formed; depositing a metal at the exposed portions of the sidewall and forming one or more metal silicide conductive structures at the exposed sidewall portions; removing the dielectric cap layer; and removing the silicon-containing topographic feature. The result is the formation of one or more metal silicide conductor structures formed for a single lithographically defined feature. In example embodiments, the formed metal silicide conductive structures have a high aspect ratio, e.g., ranging from 1:1 to 20:1 (height to width dimension).
    • 一种用于形成适用于FEOL和BEOL半导体制造应用的亚光刻尺寸的导电结构的方法。 该方法包括在衬底上形成含硅材料的形貌特征; 在地形特征上形成介电帽; 施加掩模结构以暴露所述地形特征的侧壁上的图案,所述暴露图案对应于要形成的导电结构; 在所述侧壁的暴露部分处沉积金属并在所述暴露的侧壁部分处形成一个或多个金属硅化物导电结构; 去除所述电介质盖层; 并去除含硅的地形特征。 结果是形成一个或多个金属硅化物导体结构,其形成用于单个光刻定义的特征。 在示例性实施例中,形成的金属硅化物导电结构具有高纵横比,例如从1:1至20:1(高度与宽度尺寸)。
    • 78. 发明授权
    • Dual work-function single gate stack
    • 双功能单门堆叠
    • US07449735B2
    • 2008-11-11
    • US11548020
    • 2006-10-10
    • Brent A. AndersonEdward J. Nowak
    • Brent A. AndersonEdward J. Nowak
    • H01L29/76H01L31/062H01L31/113H01L31/119
    • H01L27/1203H01L21/823807H01L21/82385H01L21/84
    • Disclosed is a complementary CMOS device having a first FET with sidewall channels and a second FET with a planar channel. The first FET can be a p-FET and the second FET can be an n-FET or vice versa. The conductor used to form the gate electrodes of the different type FETs is different and is pre-selected to optimize performance. For example, a p-FET gate electrode material can have a work function near the valence band and an n-FET gate electrode material can have a work function near the conduction band. The first gate electrodes of the first FET are located adjacent to the sidewall channels and the second gate electrode of the second FET is located above the planar channel. However, the device structure is unique in that the second gate electrode extends laterally above the first FET and is electrically coupled to the first gate electrodes.
    • 公开了具有具有侧壁通道的第一FET和具有平面通道的第二FET的互补CMOS器件。 第一个FET可以是p-FET,第二个FET可以是n-FET,反之亦然。 用于形成不同类型FET的栅电极的导体是不同的,并且是预选的以优化性能。 例如,p-FET栅极材料可以在价带附近具有功函数,并且n-FET栅电极材料可以在导带附近具有功函数。 第一FET的第一栅电极位于与侧壁通道相邻并且第二FET的第二栅电极位于平面通道上方。 然而,器件结构是唯一的,因为第二栅电极横向于第一FET上方延伸并且电耦合到第一栅电极。
    • 79. 发明申请
    • SPLIT POLY-SiGe/POLY-Si ALLOY GATE STACK
    • 分散多晶硅/多晶硅合金栅极堆叠
    • US20080200021A1
    • 2008-08-21
    • US12104570
    • 2008-04-17
    • Kevin K. ChanJia ChenShih-Fen HuangEdward J. Nowak
    • Kevin K. ChanJia ChenShih-Fen HuangEdward J. Nowak
    • H01L21/3205
    • H01L21/2807H01L21/28052H01L21/28061H01L21/823835H01L21/823842H01L29/4916H01L29/4925H01L29/665
    • A multi-layered gate electrode stack structure of a field effect transistor device is formed on a silicon nano crystal seed layer on the gate dielectric. The small grain size of the silicon nano crystal layer allows for deposition of a uniform and continuous layer of poly-SiGe with a [Ge] of up to at least 70% using in situ rapid thermal chemical vapor deposition (RTCVD). An in-situ purge of the deposition chamber in a oxygen ambient at rapidly reduced temperatures results in a thin SiO2 or SixGeyOz interfacial layer of 3 to 4A thick. The thin SiO2 or SixGeyOz interfacial layer is sufficiently thin and discontinuous to offer little resistance to gate current flow yet has sufficient [O] to effectively block upward Ge diffusion during heat treatment to thereby allow silicidation of the subsequently deposited layer of cobalt. The gate electrode stack structure is used for both nFETs and pFETs.
    • 在栅极电介质上的硅纳米晶种子层上形成场效应晶体管器件的多层栅电极堆叠结构。 硅纳米晶体层的小晶粒尺寸允许使用原位快速热化学气相沉积(RTCVD)沉积高达至少70%的[Ge]的均匀且连续的多晶硅层。 在快速降低的温度下在氧气环境中原位吹扫沉积室导致薄的SiO 2或Si x O x O O 3至4A厚的界面层。 薄的SiO 2或Si x Si 2 O 3界面层足够薄且不连续以提供很小的电阻 到栅极电流仍具有足够的[O]以在热处理期间有效地阻挡Ge扩散,从而允许后续沉积的钴的硅化物。 栅电极堆叠结构用于nFET和pFET两者。
    • 80. 发明申请
    • Substrate backgate for trigate FET
    • 基板背板用于触发FET
    • US20080185649A1
    • 2008-08-07
    • US12099211
    • 2008-04-08
    • Brent A. AndersonMatthew J. BreitwischEdward J. Nowak
    • Brent A. AndersonMatthew J. BreitwischEdward J. Nowak
    • H01L29/786H01L21/336
    • H01L29/785H01L21/845H01L27/1211H01L29/66795
    • Disclosed is a tri-gate field effect transistor with a back gate and the associated methods of forming the transistor. Specifically, a back gate is incorporated into a lower portion of a fin. A tri-gate structure is formed on the fin and is electrically isolated from the back gate. The back gate can be used to control the threshold voltage of the FET. In one embodiment the back gate extends to an n-well in a p-type silicon substrate. A contact to the n-well allows electrical voltage to be applied to the back gate. A diode created between the n-well and p-substrate isolates the current flowing through the n-well from other devices on the substrate so that the back gate can be independently biased. In another embodiment the back gate extends to n-type polysilicon layer on an insulator layer on a p-type silicon substrate. A contact to the n-type polysilicon layer allows electrical voltage to be applied to the back gate. A trench isolation structure extending through the polysilicon layer to the insulator layer isolates current flowing through the polysilicon layer from other devices on the silicon substrate.
    • 公开了具有背栅的三栅场效应晶体管和形成晶体管的相关方法。 具体地说,后门结合在翅片的下部。 三栅结构形成在翅片上并与后门电隔离。 背栅可用于控制FET的阈值电压。 在一个实施例中,背栅极延伸到p型硅衬底中的n阱。 与n阱的接触允许将电压施加到后门。 在n阱和p衬底之间产生的二极管将流过n阱的电流与衬底上的其他器件隔离,使得后栅极可以被独立地偏置。 在另一个实施例中,背栅极延伸到p型硅衬底上的绝缘体层上的n型多晶硅层。 与n型多晶硅层的接触允许电压施加到后门。 通过多晶硅层延伸到绝缘体层的沟槽隔离结构将流过多晶硅层的电流与硅衬底上的其它器件隔离。