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    • 2. 发明授权
    • High-performance CMOS SOI devices on hybrid crystal-oriented substrates
    • 高性能CMOS SOI器件在混合晶体取向衬底上
    • US07713807B2
    • 2010-05-11
    • US11958877
    • 2007-12-18
    • Bruce B. DorisKathryn W. GuariniMeikei IeongShreesh NarasimhaKern RimJeffrey W. SleightMin Yang
    • Bruce B. DorisKathryn W. GuariniMeikei IeongShreesh NarasimhaKern RimJeffrey W. SleightMin Yang
    • H01L21/8238
    • H01L21/76275H01L21/823807H01L21/84
    • An integrated semiconductor structure containing at least one device formed upon a first crystallographic surface that is optimal for that device, while another device is formed upon a second different crystallographic surface that is optimal for the other device is provided. The method of forming the integrated structure includes providing a bonded substrate including at least a first semiconductor layer of a first crystallographic orientation and a second semiconductor layer of a second different crystallographic orientation. A portion of the bonded substrate is protected to define a first device area, while another portion of the bonded substrate is unprotected. The unprotected portion of the bonded substrate is then etched to expose a surface of the second semiconductor layer and a semiconductor material is regrown on the exposed surface. Following planarization, a first semiconductor device is formed in the first device region and a second semiconductor device is formed on the regrown material.
    • 提供包含至少一个器件的集成半导体结构,所述器件形成在对于该器件最佳的第一晶体表面上,而另一器件形成在对于另一器件最佳的第二不同晶体表面上。 形成集成结构的方法包括提供包括至少第一晶体取向的第一半导体层和第二不同晶体取向的第二半导体层的键合衬底。 键合衬底的一部分被保护以限定第一器件区域,而键合衬底的另一部分是未受保护的。 然后蚀刻键合衬底的未保护部分以暴露第二半导体层的表面,并将半导体材料重新生长在暴露表面上。 在平坦化之后,在第一器件区域中形成第一半导体器件,并且在再生长材料上形成第二半导体器件。
    • 4. 发明授权
    • Super hybrid SOI CMOS devices
    • 超级混合SOI CMOS器件
    • US07619300B2
    • 2009-11-17
    • US12434247
    • 2009-05-01
    • Meikei IeongQiqing C. Ouyang
    • Meikei IeongQiqing C. Ouyang
    • H01L29/04
    • H01L21/84H01L21/823807H01L21/823878H01L27/1203H01L27/1207H01L29/7843
    • The present invention provides semiconductor structures comprised of stressed channels on hybrid oriented. In particular, the semiconductor structures include a first active area having a first stressed semiconductor surface layer of a first crystallographic orientation located on a surface of a buried insulating material and a second active area having a second stressed semiconductor surface layer of a second crystallographic orientation located on a surface of a dielectric material. A trench isolation region is located between the first and second active area, and the trench isolation region is partially filled with a trench dielectric material and the dielectric material that is present underneath said second stressed semiconductor surface layer. The dielectric material within the trench isolation region has lower stress compared to that is used in conventional STI process and it is laterally abuts at least the second stressed semiconductor surface layer and extends to an upper surface of the trench isolation region.
    • 本发明提供由混合取向的应力通道构成的半导体结构。 特别地,半导体结构包括第一有源区,其具有位于掩埋绝缘材料的表面上的第一晶体取向的第一应力半导体表面层和具有位于第二晶体取向的第二应力半导体表面层的第二有源区 在电介质材料的表面上。 沟槽隔离区域位于第一和第二有源区域之间,并且沟槽隔离区域部分地填充有沟槽电介质材料和位于所述第二应力半导体表面层下方的电介质材料。 与常规STI工艺中使用的沟槽隔离区域中的电介质材料相比具有较低的应力,并且它至少侧向邻接第二应力半导体表面层并且延伸到沟槽隔离区域的上表面。
    • 5. 发明授权
    • Highly manufacturable SRAM cells in substrates with hybrid crystal orientation
    • 具有混合晶体取向的基板中的高度可制造的SRAM单元
    • US07605447B2
    • 2009-10-20
    • US11162780
    • 2005-09-22
    • Bruce B. DorisGregory CostriniOleg GluschenkovMeikei IeongNakgeuon Seong
    • Bruce B. DorisGregory CostriniOleg GluschenkovMeikei IeongNakgeuon Seong
    • H01L29/06H01L29/04H01L27/11
    • H01L27/1104H01L27/11Y10S257/903Y10S438/973
    • The present invention relates to a semiconductor device structure that includes at least one SRAM cell formed in a substrate. Such SRAM cell comprises two pull-up transistors, two pull-down transistors, and two pass-gate transistors. The pull-down transistors and the pass-gate transistors are substantially similar in channel widths and have substantially similar source-drain doping concentrations, while the SRAM cell has a beta ratio of at least 1.5. The substrate preferably comprises a hybrid substrate with at two isolated sets of regions, while carrier mobility in these two sets of regions differentiates by a factor of at least about 1.5. More preferably, the pull-down transistors of the SRAM cell are formed in one set of regions, and the pass-gate transistors are formed in the other set of regions, so that current flow in the pull-down transistors is larger than that in the pass-gate transistors.
    • 本发明涉及一种半导体器件结构,其包括在衬底中形成的至少一个SRAM单元。 这样的SRAM单元包括两个上拉晶体管,两个下拉晶体管和两个通过栅极晶体管。 下拉晶体管和栅极晶体管在沟道宽度上基本相似,并且具有基本相似的源极 - 漏极掺杂浓度,而SRAM单元的β比率至少为1.5。 衬底优选地包括具有两个分离的区域集合的混合衬底,而这两组区域中的载流子迁移率以至少约1.5的因子差分。 更优选地,SRAM单元的下拉晶体管形成在一组区域中,并且栅极晶体管形成在另一组区域中,使得下拉晶体管中的电流大于 传输栅晶体管。
    • 7. 发明授权
    • Method for metal gated ultra short MOSFET devices
    • 金属门极超短MOSFET器件的方法
    • US07494861B2
    • 2009-02-24
    • US12013704
    • 2008-01-14
    • Jack Oon ChuBruce B. DorisMeikei IeongJing Wang
    • Jack Oon ChuBruce B. DorisMeikei IeongJing Wang
    • H01L21/8238
    • H01L29/7838H01L21/28017H01L29/105
    • MOSFET devices suitable for operation at gate lengths less than about 40 nm, and methods of their fabrication is being presented. The MOSFET devices include a ground plane formed of a monocrystalline Si based material. A Si based body layer is epitaxially disposed over the ground plane. The body layer is doped with impurities of opposite type than the ground plane. The gate has a metal with a mid-gap workfunction directly contacting a gate insulator layer. The gate is patterned to a length of less than about 40 nm, and possibly less than 20 nm. The source and the drain of the MOSFET are doped with the same type of dopant as the body layer. In CMOS embodiments of the invention the metal in the gate of the NMOS and the PMOS devices may be the same metal.
    • 适用于栅极长度小于约40nm的MOSFET器件及其制造方法。 MOSFET器件包括由单晶Si基材料形成的接地平面。 Si基体层外延地设置在接地平面上。 体层掺杂了与地平面相反的杂质。 栅极具有中间功能函数的金属,其直接接触栅极绝缘体层。 栅极被图案化成小于约40nm,并且可能小于20nm的长度。 MOSFET的源极和漏极掺杂有与体层相同类型的掺杂剂。 在本发明的CMOS实施例中,NMOS和PMOS器件的栅极中的金属可以是相同的金属。