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    Strained silicon PMOS having silicon germanium source/drain extensions and method for its fabrication
    3.
    发明授权
    Strained silicon PMOS having silicon germanium source/drain extensions and method for its fabrication 有权
    具有硅锗源/漏扩展的应变硅PMOS及其制造方法

    公开(公告)号:US07071065B1

    公开(公告)日:2006-07-04

    申请号:US10738716

    申请日:2003-12-17

    申请人: Qi Xiang Eric N. Paton Haihong Wang

    发明人: Qi Xiang Eric N. Paton Haihong Wang

    IPC分类号: H01L21/336

    CPC分类号: H01L29/6656 H01L29/1054 H01L29/665 H01L29/6659 H01L29/66636 H01L29/66916 H01L29/7842 H01L29/7848 H01L29/802 Y10S438/933

    摘要: A strained silicon p-type MOSFET utilizes a strained silicon channel region formed on a silicon germanium substrate. Silicon germanium regions are formed on the silicon germanium layer adjacent to ends of the strained silicon channel region, and shallow source and drain extensions are implanted in the silicon germanium material. The shallow source and drain extensions do not extend into the strained silicon channel region. By forming the source and drain extensions in silicon germanium material rather than in silicon, source and drain extension distortions caused by the enhanced diffusion rate of boron in silicon are avoided.

    摘要翻译: 应变硅p型MOSFET利用形成在硅锗衬底上的应变硅沟道区。 在邻近于应变硅沟道区的端部的硅锗层上形成硅锗区,并且在硅锗材料中注入浅的源极和漏极延伸。 浅源极和漏极延伸部分不延伸到应变硅沟道区域。 通过在硅锗材料而不是在硅中形成源极和漏极延伸,避免了由硅中的增强的扩散速率引起的源极和漏极扩展失真。

    Strained silicon MOSFET having reduced leakage and method of its formation
    5.
    发明授权
    Strained silicon MOSFET having reduced leakage and method of its formation 有权
    应变硅MOSFET具有减少的泄漏和其形成方法

    公开(公告)号:US06924182B1

    公开(公告)日:2005-08-02

    申请号:US10642375

    申请日:2003-08-15

    申请人: Qi Xiang Ming Ren Lin Minh V. Ngo Eric N. Paton Haihong Wang

    发明人: Qi Xiang Ming Ren Lin Minh V. Ngo Eric N. Paton Haihong Wang

    IPC分类号: H01L21/762 H01L21/8238 H01L21/8234 H01L21/76

    CPC分类号: H01L21/823878 H01L21/76237 H01L21/823807

    摘要: The formation of shallow trench isolations in a strained silicon MOSFET includes performing ion implantation in the strained silicon layer in the regions to be etched to form the trenches of the shallow trench isolations. The dosage of the implanted ions and the energy of implantation are chosen so as to damage the crystal lattice of the strained silicon throughout the thickness of the strained silicon layer in the shallow trench isolation regions to such a degree that the etch rate of the strained silicon in those regions is increased to approximately the same as or greater than the etch rate of the underlying undamaged silicon germanium. Subsequent etching yields trenches with significantly reduced or eliminated undercutting of the silicon germanium relative to the strained silicon. This in turn substantially prevents the formation of fully depleted silicon on insulator regions under the ends of the gate, thus improving the MOSFET leakage current.

    摘要翻译: 应变硅MOSFET中的浅沟槽隔离的形成包括在被蚀刻的区域中的应变硅层中执行离子注入以形成浅沟槽隔离的沟槽。 选择注入离子的剂量和注入能量,以便在浅沟槽隔离区域中的应变硅层的整个厚度上损坏应变硅的晶格,使得应变硅的蚀刻速率 在这些区域中增加到大致等于或大于底层未损坏的硅锗的蚀刻速率。 随后的蚀刻产生相对于应变硅显着减少或消除硅锗底切的沟槽。 这又大大防止了在栅极端部的绝缘体区域上形成完全耗尽的硅,从而改善MOSFET漏电流。

    Offset spacer process for forming N-type transistors
    6.
    发明授权
    Offset spacer process for forming N-type transistors 有权
    用于形成N型晶体管的偏置间隔工艺

    公开(公告)号:US06905923B1

    公开(公告)日:2005-06-14

    申请号:US10619877

    申请日:2003-07-15

    申请人: Eric N. Paton Haihong Wang Qi Xiang

    发明人: Eric N. Paton Haihong Wang Qi Xiang

    IPC分类号: H01L21/8238

    CPC分类号: H01L21/823814 H01L21/823807 H01L21/823864

    摘要: A method of fabricating an SMOS integrated circuit with source and drain junctions utilizes an offset gate spacer for N-type transistors. Ions are implanted to form the source and drain regions in a strained layer. The offset spacer reduces problems associated with Arsenic (As) diffusion on strained semiconductor layers. The process can be utilized for SMOS metal oxide semiconductor field effect transistors (MOSFETs). The strained layer can be a strained silicon layer formed above a germanium layer.

    摘要翻译: 制造具有源极和漏极结的SMOS集成电路的方法利用用于N型晶体管的偏移栅极间隔物。 植入离子以形成应变层中的源区和漏区。 偏移间隔物减少了在应变半导体层上与砷(As)扩散相关的问题。 该工艺可用于SMOS金属氧化物半导体场效应晶体管(MOSFET)。 应变层可以是形成在锗层之上的应变硅层。

    Method of forming a thick strained silicon layer and semiconductor structures incorporating a thick strained silicon layer
    7.
    发明授权
    Method of forming a thick strained silicon layer and semiconductor structures incorporating a thick strained silicon layer 有权
    形成厚应变硅层的方法和掺入厚应变硅层的半导体结构

    公开(公告)号:US06730576B1

    公开(公告)日:2004-05-04

    申请号:US10335447

    申请日:2002-12-31

    申请人: Haihong Wang Paul R. Besser Jung-Suk Goo Minh V. Ngo Eric N. Paton Qi Xiang

    发明人: Haihong Wang Paul R. Besser Jung-Suk Goo Minh V. Ngo Eric N. Paton Qi Xiang

    IPC分类号: H01L21762

    CPC分类号: H01L29/7833 H01L21/02381 H01L21/0245 H01L21/0251 H01L21/02532 H01L21/0262 H01L21/02639 H01L21/76224 H01L29/1054 H01L29/665 H01L29/6656 H01L29/6659

    摘要: A strained silicon layer is grown on a layer of silicon germanium and a layer of silicon germanium is grown on the strained silicon in a single continuous in situ deposition process with the strained silicon. Shallow trench isolations are formed in the lower layer of silicon germanium prior to formation of the strained silicon layer. The two silicon germanium layers effectively provide dual substrates at both surfaces of the strained silicon layer that serve to maintain the tensile strain of the strained silicon layer and resist the formation of misfit dislocations that might otherwise result from temperature changes during processing. Consequently the critical thickness of strained silicon that can be grown without significant misfit dislocations during later processing is effectively doubled for a given germanium content of the silicon germanium layers. The formation of shallow trench isolations prior to formation of the strained silicon layer avoids subjecting the strained silicon layer to extreme thermal stresses and further reduces the formation of misfit dislocations.

    摘要翻译: 应变硅层在硅锗层上生长,并且在应变硅上生长硅锗层,并在应变硅中进行单次连续原位沉积工艺。 在形成应变硅层之前,在硅锗的下层形成浅沟槽隔离。 两个硅锗层有效地在应变硅层的两个表面上提供双重衬底,其用于维持应变硅层的拉伸应变,并抵抗由加工过程中的温度变化引起的失配位错的形成。 因此,对于硅锗层的给定锗含量,可以在后续处理期间可以生长而不显着失配位错的应变硅的临界厚度被有效地加倍。 在形成应变硅层之前形成浅沟槽隔离避免使应变硅层受到极端的热应力,并进一步减少失配位错的形成。

    Strained silicon PMOS having silicon germanium source/drain extensions and method for its fabrication
    10.
    发明授权
    Strained silicon PMOS having silicon germanium source/drain extensions and method for its fabrication 有权
    具有硅锗源/漏扩展的应变硅PMOS及其制造方法

    公开(公告)号:US06703648B1

    公开(公告)日:2004-03-09

    申请号:US10282559

    申请日:2002-10-29

    申请人: Qi Xiang Eric N. Paton Haihong Wang

    发明人: Qi Xiang Eric N. Paton Haihong Wang

    IPC分类号: H01L2904

    CPC分类号: H01L29/6656 H01L29/1054 H01L29/665 H01L29/6659 H01L29/66636 H01L29/66916 H01L29/7842 H01L29/7848 H01L29/802 Y10S438/933

    摘要: A strained silicon p-type MOSFET utilizes a strained silicon channel region formed on a silicon germanium substrate. Silicon germanium regions are formed to the silicon germanium layer adjacent to ends of the strained silicon channel region, and shallow source and drain extensions are implanted in the silicon germanium material. The shallow source and drain extensions do not extend into the strained silicon channel region. By forming the source and drain extensions in silicon germanium material rather than in silicon, source and drain extension distortions caused by the enhanced diffusion rate of boron in silicon are avoided.

    摘要翻译: 应变硅p型MOSFET利用形成在硅锗衬底上的应变硅沟道区。 硅锗区形成在邻近于应变硅沟道区的端部的硅锗层上,并且浅的源极和漏极延伸部被注入到硅锗材料中。 浅源极和漏极延伸部分不延伸到应变硅沟道区域。 通过在硅锗材料而不是在硅中形成源极和漏极延伸,避免了由硅中的增强的扩散速率引起的源极和漏极扩展失真。