公开(公告)号：US20120306027A1

公开(公告)日：2012-12-06

申请号：US13483630

申请日：2012-05-30

Applicant: Stephan-Detlef Kronholz ,  Rohit Pal ,  Gunda Beernink

Inventor： Stephan-Detlef Kronholz ,  Rohit Pal ,  Gunda Beernink

IPC: H01L29/78 ,  H01L21/336

CPC classification number: H01L29/7848 ,  H01L21/823412 ,  H01L21/823418 ,  H01L21/823425 ,  H01L21/823807 ,  H01L21/823814 ,  H01L29/165 ,  H01L29/41775 ,  H01L29/665 ,  H01L29/6659 ,  H01L29/66636 ,  H01L29/7834

Abstract: When forming sophisticated semiconductor devices including transistors with sophisticated high-k metal gate electrode structures and a strain-inducing semiconductor alloy, transistor uniformity and performance may be enhanced by providing superior growth conditions during the selective epitaxial growth process. To this end, a semiconductor material may be preserved at the isolation regions in order to avoid the formation of pronounced shoulders. Furthermore, in some illustrative embodiments, additional mechanisms are implemented in order to avoid undue material loss, for instance upon removing a dielectric cap material and the like.

Abstract translation: 当形成具有复杂的高k金属栅电极结构的晶体管和应变诱导半导体合金的复杂半导体器件时，可以通过在选择性外延生长工艺期间提供优异的生长条件来增强晶体管的均匀性和性能。 为此，可以在隔离区域保留半导体材料，以避免突出的肩部的形成。 此外，在一些说明性实施例中，为了避免不适当的材料损失，例如在去除电介质盖材料等时，实施附加机构。

公开(公告)号：US08198192B2

公开(公告)日：2012-06-12

申请号：US12775555

申请日：2010-05-07

Applicant: Richard Carter ,  Martin Trentzsch ,  Sven Beyer ,  Rohit Pal

Inventor： Richard Carter ,  Martin Trentzsch ,  Sven Beyer ,  Rohit Pal

IPC: H01L21/4763

CPC classification number: H01L21/823462 ,  H01L21/28176 ,  H01L21/28194 ,  H01L29/513 ,  H01L29/517

Abstract: Sophisticated gate electrode structures may be formed by providing a cap layer including a desired species that may diffuse into the gate dielectric material prior to performing a treatment for stabilizing the sensitive gate dielectric material. In this manner, complex high-k metal gate electrode structures may be formed on the basis of reduced temperatures and doses for a threshold adjusting species compared to conventional strategies. Moreover, a single metal-containing electrode material may be deposited for both types of transistors.

Abstract translation: 复杂的栅极电极结构可以通过在进行用于稳定敏感栅极介电材料的处理之前提供包括可能扩散到栅极电介质材料中的所需物质的覆盖层来形成。 以这种方式，与常规策略相比，可以基于用于阈值调节物质的降低的温度和剂量来形成复杂的高k金属栅电极结构。 此外，可以为两种类型的晶体管沉积单个含金属的电极材料。

公开(公告)号：US20120119308A1

公开(公告)日：2012-05-17

申请号：US13353013

申请日：2012-01-18

Applicant: Man Fai NG ,  Rohit Pal

Inventor： Man Fai NG ,  Rohit Pal

IPC: H01L29/772

CPC classification number: H01L29/4966 ,  H01L21/28088 ,  H01L21/32155 ,  H01L21/322 ,  H01L29/7833

Abstract: Improved semiconductor devices including metal gate electrodes are formed with reduced performance variability by reducing the initial high dopant concentration at the top portion of the silicon layer overlying the metal layer. Embodiments include reducing the dopant concentration in the upper portion of the silicon layer, by implanting a counter-dopant into the upper portion of the silicon layer, removing the high dopant concentration portion and replacing it with undoped or lightly doped silicon, and applying a gettering agent to the upper surface of the silicon layer to form a thin layer with the gettered dopant, which layer can be removed or retained.

Abstract translation: 包括金属栅电极的改进的半导体器件通过降低覆盖在金属层上的硅层顶部的初始高掺杂剂浓度而形成，具有降低的性能可变性。 实施例包括通过将反掺杂剂注入硅层的上部来去除高掺杂剂浓度部分并用未掺杂的或轻掺杂的硅代替它来减少硅层上部的掺杂剂浓度，并施加吸气 剂到硅层的上表面以形成具有吸收的掺杂剂的薄层，该层可以被去除或保留。

公开(公告)号：US20110095341A1

公开(公告)日：2011-04-28

申请号：US12604281

申请日：2009-10-22

Applicant: Rohit Pal ,  Michael Hargrove ,  Frank Bin Yang

Inventor： Rohit Pal ,  Michael Hargrove ,  Frank Bin Yang

IPC: H01L29/78 ,  H01L21/336

CPC classification number: H01L29/66651 ,  H01L21/28123 ,  H01L21/28194 ,  H01L21/28247 ,  H01L29/495 ,  H01L29/4966 ,  H01L29/517

Abstract: Methods for protecting gate stacks during fabrication of semiconductor devices and semiconductor devices fabricated from such methods are provided. Methods for fabricating a semiconductor device include providing a semiconductor substrate having an active region and a shallow trench isolation (STI) region. Epitaxial layer is formed on the active region to define a lateral overhang portion in a divot at the active region/STI region interface. A gate stack is formed having a first gate stack-forming layer overlying the semiconductor substrate. First gate stack-forming layer includes a non-conformal layer of metal gate-forming material which is directionally deposited to form a thinned break portion just below the lateral overhang portion. After the step of forming the gate stack, a first portion of the non-conformal layer is in the gate stack and a second portion is exposed. The thinned break portion at least partially isolates the first and second portions during subsequent etch chemistries.

公开(公告)号：US07932143B1

公开(公告)日：2011-04-26

申请号：US12604281

申请日：2009-10-22

Applicant: Rohit Pal ,  Michael Hargrove ,  Frank Bin Yang

Inventor： Rohit Pal ,  Michael Hargrove ,  Frank Bin Yang

IPC: H01L21/8238

CPC classification number: H01L29/66651 ,  H01L21/28123 ,  H01L21/28194 ,  H01L21/28247 ,  H01L29/495 ,  H01L29/4966 ,  H01L29/517

Abstract: Methods for protecting gate stacks during fabrication of semiconductor devices and semiconductor devices fabricated from such methods are provided. Methods for fabricating a semiconductor device include providing a semiconductor substrate having an active region and a shallow trench isolation (STI) region. Epitaxial layer is formed on the active region to define a lateral overhang portion in a divot at the active region/STI region interface. A gate stack is formed having a first gate stack-forming layer overlying the semiconductor substrate. First gate stack-forming layer includes a non-conformal layer of metal gate-forming material which is directionally deposited to form a thinned break portion just below the lateral overhang portion. After the step of forming the gate stack, a first portion of the non-conformal layer is in the gate stack and a second portion is exposed. The thinned break portion at least partially isolates the first and second portions during subsequent etch chemistries.

Abstract translation: 提供了在由这些方法制造的半导体器件和半导体器件的制造期间保护栅极堆叠的方法。 制造半导体器件的方法包括提供具有有源区和浅沟槽隔离（STI）区的半导体衬底。 在有源区上形成外延层，以在有源区/ STI区界面上的边界中限定一个横向伸出部分。 形成具有覆盖在半导体衬底上的第一栅叠层形成层的栅叠层。 第一栅极堆叠形成层包括定向沉积以形成刚好在横向突出部分下方的变薄的断裂部分的非保形层的金属栅极形成材料。 在形成栅极堆叠的步骤之后，非共形层的第一部分在栅极堆叠中并且第二部分被暴露。 减薄断裂部分在随后的蚀刻化学过程中至少部分地隔离第一和第二部分。

公开(公告)号：US07767534B2

公开(公告)日：2010-08-03

申请号：US12240682

申请日：2008-09-29

Applicant: Frank Bin Yang ,  Rohit Pal ,  Michael J. Hargrove

Inventor： Frank Bin Yang ,  Rohit Pal ,  Michael J. Hargrove

IPC: H01L21/336

CPC classification number: H01L29/7847 ,  H01L29/66636

Abstract: Methods for forming a semiconductor device comprising a silicon-comprising substrate are provided. One exemplary method comprises depositing a polysilicon layer overlying the silicon-comprising substrate, amorphizing the polysilicon layer, etching the amorphized polysilicon layer to form a gate electrode, depositing a stress-inducing layer overlying the gate electrode, annealing the silicon-comprising substrate to recrystallize the gate electrode, removing the stress-inducing layer, etching recesses into the substrate using the gate electrode as an etch mask, and epitaxially growing impurity-doped, silicon-comprising regions in the recesses.

Abstract translation: 提供了用于形成包括含硅衬底的半导体器件的方法。 一种示例性方法包括沉积覆盖含硅衬底的多晶硅层，使多晶硅层非晶化，蚀刻非晶化多晶硅层以形成栅电极，沉积覆盖栅电极的应力诱导层，退火含硅衬底以重结晶 栅电极，去除应力诱导层，使用栅电极作为蚀刻掩模蚀刻到衬底中的凹槽，以及在凹槽中外延生长杂质掺杂的含硅区域。

公开(公告)号：US20100096698A1

公开(公告)日：2010-04-22

申请号：US12644882

申请日：2009-12-22

Applicant: Igor Peidous ,  Rohit Pal

Inventor： Igor Peidous ,  Rohit Pal

IPC: H01L29/78 ,  H01L29/06

CPC classification number: H01L29/78687 ,  H01L29/66553 ,  H01L29/66621 ,  H01L29/66628 ,  H01L29/66772 ,  H01L29/7848

Abstract: Stress enhanced MOS transistors are provided. A semiconductor device is provided that comprises a semiconductor-on-insulator structure, a gate insulator layer, a source region, a drain region and a conductive gate overlying the gate insulator layer. The semiconductor-on-insulator structure comprises: a substrate, a semiconductor layer, and an insulating layer disposed between the substrate and the semiconductor layer. The semiconductor layer has a first surface, a second surface and a first region. The gate insulator layer overlies the first region, the conductive gate overlies the gate insulator layer, and the source region and the drain region overlie the first surface and comprise a strain-inducing epitaxial layer

Abstract translation: 提供了应力增强型MOS晶体管。 提供一种半导体器件，其包括绝缘体上半导体结构，栅极绝缘体层，源极区域，漏极区域和覆盖栅极绝缘体层的导电栅极。 绝缘体上半导体结构包括：衬底，半导体层和设置在衬底和半导体层之间的绝缘层。 半导体层具有第一表面，第二表面和第一区域。 栅极绝缘体层覆盖第一区域，导电栅极覆盖栅极绝缘体层，源区域和漏极区域覆盖在第一表面上，并且包括应变诱导外延层

公开(公告)号：US20100055394A1

公开(公告)日：2010-03-04

申请号：US12551071

申请日：2009-08-31

Applicant: Zhishan Hua ,  Erdogan Gulari ,  Mark A. Burns ,  Rohit Pal ,  Onnop Srivannavit

Inventor： Zhishan Hua ,  Erdogan Gulari ,  Mark A. Burns ,  Rohit Pal ,  Onnop Srivannavit

IPC: B32B3/10 ,  B32B37/06

CPC classification number: F16K99/0032 ,  B01L3/502707 ,  B01L3/502715 ,  B01L3/50273 ,  B01L3/502738 ,  B01L3/502746 ,  B01L2300/0819 ,  B01L2400/0481 ,  B01L2400/0655 ,  B01L2400/0677 ,  F15B15/10 ,  F16K99/0044 ,  Y10T137/0391 ,  Y10T137/1624 ,  Y10T137/1812 ,  Y10T137/2142 ,  Y10T137/218 ,  Y10T137/2191 ,  Y10T137/2196 ,  Y10T137/2202 ,  Y10T137/2218 ,  Y10T428/23 ,  Y10T428/234 ,  Y10T428/24322 ,  Y10T428/24331 ,  Y10T428/24612

Abstract: A microactuator may be configured by activating a source of electromagnetic radiation to heat and melt a selected set of phase-change plugs embedded in a substrate of the microactuator, pressurizing a common pressure chamber adjacent to each of the plugs to deform the melted plugs, and deactivating the source of electromagnetic radiation to cool and solidify the melted plugs.

Abstract translation: 微致动器可以通过激活电磁辐射源来加热和熔化嵌入在微致动器的衬底中的一组相变插塞，对与每个插塞相邻的公共压力室进行加压以使熔化的插头变形，以及 停用电磁辐射源以冷却和固化熔化的塞子。

公开(公告)号：US20090280627A1

公开(公告)日：2009-11-12

申请号：US12119384

申请日：2008-05-12

Applicant: Rohit Pal ,  Frank Bin Yang ,  Michael Hargrove

Inventor： Rohit Pal ,  Frank Bin Yang ,  Michael Hargrove

IPC: H01L21/322

CPC classification number: H01L29/7848 ,  H01L21/26506 ,  H01L21/26586 ,  H01L21/3065 ,  H01L29/165 ,  H01L29/6653 ,  H01L29/6659 ,  H01L29/66636 ,  H01L29/7833

Abstract: A method of fabricating a semiconductor transistor device is provided. The fabrication method begins by forming a gate structure overlying a layer of semiconductor material, such as silicon. Then, spacers are formed about the sidewalls of the gate structure. Next, ions of an amorphizing species are implanted into the semiconductor material at a tilted angle toward the gate structure. The gate structure and the spacers are used as an ion implantation mask during this step. The ions form amorphized regions in the semiconductor material. Thereafter, the amorphized regions are selectively removed, resulting in corresponding recesses in the semiconductor material. In addition, the recesses are filled with stress inducing semiconductor material, and fabrication of the semiconductor transistor device is completed.

Abstract translation: 提供一种制造半导体晶体管器件的方法。 制造方法通过形成覆盖诸如硅的半导体材料层的栅极结构开始。 然后，围绕栅极结构的侧壁形成间隔物。 接下来，非晶化物质的离子以倾斜的角度注入到栅极结构中。 在该步骤中，栅极结构和间隔物用作离子注入掩模。 离子在半导体材料中形成非晶化区域。 此后，非晶化区域被选择性地去除，从而在半导体材料中产生相应的凹槽。 此外，凹部被应力诱导半导体材料填充，并且半导体晶体管器件的制造完成。

公开(公告)号：US20090228132A1

公开(公告)日：2009-09-10

申请号：US12045081

申请日：2008-03-10

Applicant: Kevin R. Lensing ,  Alok Vaid ,  Rohit Pal

Inventor： Kevin R. Lensing ,  Alok Vaid ,  Rohit Pal

IPC: G06F17/00

CPC classification number: H01L22/12 ,  H01L22/20 ,  H01L29/165 ,  H01L29/66636 ,  H01L29/78 ,  H01L29/7848

Abstract: A method includes receiving a performance distribution for a plurality of devices to be fabricated in a semiconductor process flow. A performance target for a particular device is specified based on the performance distribution. A stressed material is formed in a recess adjacent a gate electrode of a transistor in the particular device in accordance with at least one operating recipe. The recess is spaced from the gate electrode by a gate proximity distance. A target value for the gate proximity distance is determined based on the performance target. At least one parameter of the operating recipe is determined based on the target value for the gate proximity distance.

Abstract translation: 一种方法包括接收要在半导体工艺流程中制造的多个器件的性能分布。 基于性能分布指定特定设备的性能目标。 根据至少一个操作配方，在与特定装置中的晶体管的栅电极相邻的凹部中形成应力材料。 凹槽与栅电极隔开一个栅极接近距离。 基于性能目标确定门接近距离的目标值。 基于门接近距离的目标值确定操作配方的至少一个参数。