公开(公告)号：US07084050B2

公开(公告)日：2006-08-01

申请号：US11039602

申请日：2005-01-19

申请人： Stephen W. Bedell ,  Joel P. de Souza ,  Keith E. Fogel ,  Devendra K. Sadana ,  Ghavam G. Shahidi

发明人： Stephen W. Bedell ,  Joel P. de Souza ,  Keith E. Fogel ,  Devendra K. Sadana ,  Ghavam G. Shahidi

IPC分类号： H01L21/20 ,  H01L21/76 ,  H01L21/31

CPC分类号： H01L21/76243 ,  H01L21/26506 ,  H01L21/76267 ,  Y10T428/12674 ,  Y10T428/12681

摘要： A method of forming a substantially relaxed, high-quality SiGe-on-insulator substrate material using SIMOX and Ge interdiffusion is provided. The method includes first implanting ions into a Si-containing substrate to form an implanted-ion rich region in the Si-containing substrate. The implanted-ion rich region has a sufficient ion concentration such that during a subsequent anneal at high temperatures a barrier layer that is resistant to Ge diffusion is formed. Next, a Ge-containing layer is formed on a surface of the Si-containing substrate, and thereafter a heating step is performed at a temperature which permits formation of the barrier layer and interdiffusion of Ge thereby forming a substantially relaxed, single crystal SiGe layer atop the barrier layer.

摘要翻译： 提供了使用SIMOX和Ge相互扩散形成基本上松弛的，优质的绝缘体上硅衬底材料的方法。 该方法包括首先将离子注入到含Si衬底中以在含Si衬底中形成植入离子富集区。 注入离子富集区具有足够的离子浓度，使得在随后的高温退火期间形成耐Ge扩散的阻挡层。 接下来，在含Si衬底的表面上形成Ge含有层，然后在允许形成阻挡层和Ge的相互扩散的温度下进行加热步骤，从而形成基本上松弛的单晶SiGe层 阻挡层顶部。

公开(公告)号：US08361889B2

公开(公告)日：2013-01-29

申请号：US12830626

申请日：2010-07-06

申请人： Thomas N. Adam ,  Stephen W. Bedell ,  Joel P. de Souza ,  Keith E. Fogel ,  Alexander Reznicek ,  Devendra K. Sadana ,  Ghavam G. Shahidi

发明人： Thomas N. Adam ,  Stephen W. Bedell ,  Joel P. de Souza ,  Keith E. Fogel ,  Alexander Reznicek ,  Devendra K. Sadana ,  Ghavam G. Shahidi

IPC分类号： H01L21/20

CPC分类号： H01L29/1054 ,  H01L29/7833

摘要： A method of forming a strained semiconductor-on-insulator (SSOI) substrate that does not include wafer bonding is provided. In this disclosure a relaxed and doped silicon layer is formed on an upper surface of a silicon-on-insulator (SOI) substrate. In one embodiment, the dopant within the relaxed and doped silicon layer has an atomic size that is smaller than the atomic size of silicon and, as such, the in-plane lattice parameter of the relaxed and doped silicon layer is smaller than the in-plane lattice parameter of the underlying SOI layer. In another embodiment, the dopant within the relaxed and doped silicon layer has an atomic size that is larger than the atomic size of silicon and, as such, the in-plane lattice parameter of the relaxed and doped silicon layer is larger than the in-plane lattice parameter of the underlying SOI layer. After forming the relaxed and doped silicon layer on the SOI substrate, the dopant within the relaxed and doped silicon layer is removed from that layer converting the relaxed and doped silicon layer into a strained (compressively or tensilely) silicon layer that is formed on an upper surface of an SOI substrate.

摘要翻译： 提供了一种形成不包括晶片接合的应变绝缘体上半导体（SSOI）衬底的方法。 在本公开中，在绝缘体上硅（SOI）衬底的上表面上形成松弛和掺杂的硅层。 在一个实施例中，松弛和掺杂硅层内的掺杂剂具有小于硅的原子尺寸的原子尺寸，因此松弛和掺杂硅层的面内晶格参数小于硅的原子尺寸， 下层SOI层的平面晶格参数。 在另一实施例中，松弛和掺杂硅层内的掺杂剂具有大于硅的原子尺寸的原子尺寸，因此松弛和掺杂硅层的面内晶格参数大于硅原子尺寸， 下层SOI层的平面晶格参数。 在SOI衬底上形成松弛和掺杂的硅层之后，从该层去除松弛和掺杂硅层内的掺杂剂，将松散和掺杂的硅层转化成形成在上层的应变（压缩或拉伸）硅层 SOI衬底的表面。

公开(公告)号：US20100221867A1

公开(公告)日：2010-09-02

申请号：US12436249

申请日：2009-05-06

申请人： Stephen W. Bedell ,  Joel P. de Souza ,  Keith E. Fogel ,  Harold J. Hovel ,  Daniel A. Inns ,  Jeehwan Kim ,  Devendra K. Sadana ,  Katherine L. Saenger ,  Ghavam G. Shahidi

发明人： Stephen W. Bedell ,  Joel P. de Souza ,  Keith E. Fogel ,  Harold J. Hovel ,  Daniel A. Inns ,  Jeehwan Kim ,  Devendra K. Sadana ,  Katherine L. Saenger ,  Ghavam G. Shahidi

IPC分类号： H01L31/0376 ,  H01L21/762

CPC分类号： H01L31/03921 ,  H01L21/02529 ,  H01L21/02532 ,  H01L21/02573 ,  H01L21/02667 ,  H01L21/7624 ,  H01L21/76245 ,  H01L21/76262 ,  H01L31/046 ,  H01L31/0463 ,  H01L31/0465 ,  H01L31/1872 ,  Y02E10/50 ,  Y02P70/521

摘要： A lost cost method for fabricating SOI substrates is provided. The method includes forming a stack of p-type doped amorphous Si-containing layers on a semiconductor region of a substrate by utilizing an evaporation deposition process. A solid phase recrystallization step is then performed to convert the amorphous Si-containing layers within the stack into a stack of p-type doped single crystalline Si-containing layers. After recrystallization, the single crystalline Si-containing layers are subjected to anodization and at least an oxidation step to form an SOI substrate. Solar cells and/or other semiconductor devices can be formed on the upper surface of the inventive SOI substrate.

摘要翻译： 提供了一种用于制造SOI衬底的损耗成本方法。 该方法包括通过利用蒸发沉积工艺在衬底的半导体区域上形成一层p型掺杂的非晶态含Si层。 然后进行固相重结晶步骤，以将叠层内的非晶态含硅层转化为p型掺杂单晶含Si层的堆叠。 重结晶后，对单晶含Si层进行阳极氧化和至少氧化步骤以形成SOI衬底。 太阳能电池和/或其他半导体器件可以形成在本发明的SOI衬底的上表面上。

公开(公告)号：US20120009766A1

公开(公告)日：2012-01-12

申请号：US12830626

申请日：2010-07-06

申请人： Thomas N. Adam ,  Stephen W. Bedell ,  Joel P. de Souza ,  Keith E. Fogel ,  Alexander Reznicek ,  Devendra K. Sadana ,  Ghavam G. Shahidi

发明人： Thomas N. Adam ,  Stephen W. Bedell ,  Joel P. de Souza ,  Keith E. Fogel ,  Alexander Reznicek ,  Devendra K. Sadana ,  Ghavam G. Shahidi

IPC分类号： H01L21/20

CPC分类号： H01L29/1054 ,  H01L29/7833

摘要： A method of forming a strained semiconductor-on-insulator (SSOI) substrate that does not include wafer bonding is provided. In this disclosure a relaxed and doped silicon layer is formed on an upper surface of a silicon-on-insulator (SOI) substrate. In one embodiment, the dopant within the relaxed and doped silicon layer has an atomic size that is smaller than the atomic size of silicon and, as such, the in-plane lattice parameter of the relaxed and doped silicon layer is smaller than the in-plane lattice parameter of the underlying SOI layer. In another embodiment, the dopant within the relaxed and doped silicon layer has an atomic size that is larger than the atomic size of silicon and, as such, the in-plane lattice parameter of the relaxed and doped silicon layer is larger than the in-plane lattice parameter of the underlying SOI layer. After forming the relaxed and doped silicon layer on the SOI substrate, the dopant within the relaxed and doped silicon layer is removed from that layer converting the relaxed and doped silicon layer into a strained (compressively or tensilely) silicon layer that is formed on an upper surface of an SOI substrate.

摘要翻译： 提供了一种形成不包括晶片接合的应变绝缘体上半导体（SSOI）衬底的方法。 在本公开中，在绝缘体上硅（SOI）衬底的上表面上形成松弛和掺杂的硅层。 在一个实施例中，松弛和掺杂硅层内的掺杂剂具有小于硅的原子尺寸的原子尺寸，因此松弛和掺杂硅层的面内晶格参数小于硅的原子尺寸， 下层SOI层的平面晶格参数。 在另一实施例中，松弛和掺杂硅层内的掺杂剂具有大于硅的原子尺寸的原子尺寸，因此松弛和掺杂硅层的面内晶格参数大于硅原子尺寸， 下层SOI层的平面晶格参数。 在SOI衬底上形成松弛和掺杂的硅层之后，从该层去除松弛和掺杂硅层内的掺杂剂，将松散和掺杂的硅层转化成形成在上层的应变（压缩或拉伸）硅层 SOI衬底的表面。

公开(公告)号：US06861158B2

公开(公告)日：2005-03-01

申请号：US10696601

申请日：2003-10-29

申请人： Stephen W. Bedell ,  Joel P. de Souza ,  Keith E. Fogel ,  Devendra K. Sadana ,  Ghavam G. Shahidi

发明人： Stephen W. Bedell ,  Joel P. de Souza ,  Keith E. Fogel ,  Devendra K. Sadana ,  Ghavam G. Shahidi

IPC分类号： H01L27/08 ,  H01L21/02 ,  H01L21/20 ,  H01L21/265 ,  H01L21/762 ,  H01L27/12 ,  B32B9/04

CPC分类号： H01L21/76243 ,  H01L21/26506 ,  H01L21/76267 ,  Y10T428/12674 ,  Y10T428/12681

摘要： A method of forming a substantially relaxed, high-quality SiGe-on-insulator substrate material using SIMOX and Ge interdiffusion is provided. The method includes first implanting ions into a Si-containing substrate to form an implanted-ion rich region in the Si-containing substrate. The implanted-ion rich region has a sufficient ion concentration such that during a subsequent anneal at high temperatures a barrier layer that is resistant to Ge diffusion is formed. Next, a Ge-containing layer is formed on a surface of the Si-containing substrate, and thereafter a heating step is performed at a temperature which permits formation of the barrier layer and interdiffusion of Ge thereby forming a substantially relaxed, single crystal SiGe layer atop the barrier layer.

摘要翻译： 提供了使用SIMOX和Ge相互扩散形成基本上松弛的，优质的绝缘体上硅衬底材料的方法。 该方法包括首先将离子注入到含Si衬底中以在含Si衬底中形成植入离子富集区。 注入离子富集区具有足够的离子浓度，使得在随后的高温退火期间形成耐Ge扩散的阻挡层。 接下来，在含Si衬底的表面上形成Ge含有层，然后在允许形成阻挡层和Ge的相互扩散的温度下进行加热步骤，从而形成基本上松弛的单晶SiGe层 阻挡层顶部。

公开(公告)号：US20130025654A1

公开(公告)日：2013-01-31

申请号：US13193871

申请日：2011-07-29

申请人： Stephen W. Bedell ,  Keith E. Fogel ,  Bahman Hekmatshoar-Tabari ,  Devendra K. Sadana ,  Ghavam G. Shahidi ,  Davood Shahrjerdi

发明人： Stephen W. Bedell ,  Keith E. Fogel ,  Bahman Hekmatshoar-Tabari ,  Devendra K. Sadana ,  Ghavam G. Shahidi ,  Davood Shahrjerdi

IPC分类号： H01L31/06 ,  H01L31/18

CPC分类号： H01L31/1892 ,  H01L31/02167 ,  H01L31/0687 ,  H01L31/0725 ,  H01L31/0747 ,  H01L31/076 ,  H01L31/1808 ,  H01L31/1812 ,  Y02E10/544 ,  Y02E10/548 ,  Y02P70/521

摘要： A method of forming a photovoltaic device that includes bonding a substrate to a germanium-containing semiconductor layer with a stressor layer, wherein the stressor layer cleaves the germanium-containing semiconductor layer. At least one semiconductor layer is formed on a cleaved surface of the germanium-containing semiconductor layer that is opposite the conductivity type of the germanium-containing semiconductor layer to provide a first solar cell. The first solar cell absorbs a first range of wavelengths. At least one second solar cell may be formed on the first solar cell, wherein the at least one second solar cell is composed of at least one semiconductor material to absorb a second range of wavelengths that is different than the first range wavelengths absorbed by the first solar cell.

摘要翻译： 一种形成光伏器件的方法，该光电器件包括将衬底粘合到含锗半导体层与应力层，其中所述应力层切割含锗半导体层。 在与含锗半导体层的导电类型相反的含锗半导体层的切割表面上形成至少一个半导体层以提供第一太阳能电池。 第一太阳能电池吸收第一波长范围。 可以在第一太阳能电池上形成至少一个第二太阳能电池，其中至少一个第二太阳能电池由至少一个半导体材料组成，以吸收不同于由第一太阳能电池吸收的第一范围波长的第二波长范围 太阳能电池。

公开(公告)号：US10304984B2

公开(公告)日：2019-05-28

申请号：US13607004

申请日：2012-09-07

申请人： Stephen W. Bedell ,  Keith E. Fogel ,  Bahman Hekmatshoar-Tabari ,  Devendra K. Sadana ,  Ghavam G. Shahidi ,  Davood Shahrjerdi

发明人： Stephen W. Bedell ,  Keith E. Fogel ,  Bahman Hekmatshoar-Tabari ,  Devendra K. Sadana ,  Ghavam G. Shahidi ,  Davood Shahrjerdi

IPC分类号： H01L31/074 ,  H01L31/078 ,  H01L31/0216 ,  H01L31/0224 ,  H01L31/0725 ,  H01L31/0747 ,  C23C14/34 ,  H01L31/18 ,  H01L31/20

摘要： A photovoltaic device and method include a doped germanium-containing substrate, an emitter contact coupled to the substrate on a first side and a back contact coupled to the substrate on a side opposite the first side. The emitter includes at least one doped layer of an opposite conductivity type as that of the substrate and the back contact includes at least one doped layer of the same conductivity type as that of the substrate. The at least one doped layer of the emitter contact or the at least one doped layer of the back contact is in direct contact with the substrate, and the at least one doped layer of the emitter contact or the back contact includes an n-type material having an electron affinity smaller than that of the substrate, or a p-type material having a hole affinity larger than that of the substrate.

公开(公告)号：US20130312819A1

公开(公告)日：2013-11-28

申请号：US13533229

申请日：2012-06-26

申请人： Stephen W. Bedell ,  Keith E. Fogel ,  Bahman Hekmatshoartabari ,  Paul A. Lauro ,  Ning Li ,  Devendra K. Sadana ,  Ghavam G. Shahidi ,  Davood Shahrjerdi

发明人： Stephen W. Bedell ,  Keith E. Fogel ,  Bahman Hekmatshoartabari ,  Paul A. Lauro ,  Ning Li ,  Devendra K. Sadana ,  Ghavam G. Shahidi ,  Davood Shahrjerdi

IPC分类号： H01L31/02 ,  H01L29/06

CPC分类号： H01L31/0684 ,  H01L21/02002 ,  H01L31/1896 ,  Y02E10/547

摘要： A stressor layer used in a controlled spalling method is removed through the use of a cleave layer that can be fractured or dissolved. The cleave layer is formed between a host semiconductor substrate and the metal stressor layer. A controlled spalling process separates a relatively thin residual host substrate layer from the host substrate. Following attachment of a handle substrate to the residual substrate layer or other layers subsequently formed thereon, the cleave layer is dissolved or otherwise compromised to facilitate removal of the stressor layer. Such removal allows the fabrication of a bifacial solar cell.

公开(公告)号：US20130025658A1

公开(公告)日：2013-01-31

申请号：US13607004

申请日：2012-09-07

申请人： Stephen W. Bedell ,  Keith E. Fogel ,  Bahman Hekmatshoar-Tabari ,  Devendra K. Sadana ,  Ghavam G. Shahidi ,  Davood Shahrjerdi

发明人： Stephen W. Bedell ,  Keith E. Fogel ,  Bahman Hekmatshoar-Tabari ,  Devendra K. Sadana ,  Ghavam G. Shahidi ,  Davood Shahrjerdi

IPC分类号： H01L31/0725 ,  H01L31/0224

CPC分类号： H01L31/0725 ,  C23C14/3407 ,  H01L31/02167 ,  H01L31/022441 ,  H01L31/074 ,  H01L31/0747 ,  H01L31/078 ,  H01L31/1808 ,  H01L31/1812 ,  H01L31/204 ,  Y02E10/50 ,  Y02P70/521

摘要： A photovoltaic device and method include a doped germanium-containing substrate, an emitter contact coupled to the substrate on a first side and a back contact coupled to the substrate on a side opposite the first side. The emitter includes at least one doped layer of an opposite conductivity type as that of the substrate and the back contact includes at least one doped layer of the same conductivity type as that of the substrate. The at least one doped layer of the emitter contact or the at least one doped layer of the back contact is in direct contact with the substrate, and the at least one doped layer of the emitter contact or the back contact includes an n-type material having an electron affinity smaller than that of the substrate, or a p-type material having a hole affinity larger than that of the substrate.

公开(公告)号：US20130025655A1

公开(公告)日：2013-01-31

申请号：US13194301

申请日：2011-07-29

申请人： STEPHEN W. BEDELL ,  Keith E. Fogel ,  Bahman Hekmatshoar-Tabari ,  Devendra K. Sadana ,  Ghavam G. Shahidi ,  Davood Shahrjerdi

发明人： STEPHEN W. BEDELL ,  Keith E. Fogel ,  Bahman Hekmatshoar-Tabari ,  Devendra K. Sadana ,  Ghavam G. Shahidi ,  Davood Shahrjerdi

IPC分类号： H01L31/06 ,  H01L31/18

CPC分类号： H01L31/0725 ,  C23C14/3407 ,  H01L31/02167 ,  H01L31/022441 ,  H01L31/074 ,  H01L31/0747 ,  H01L31/078 ,  H01L31/1808 ,  H01L31/1812 ,  H01L31/204 ,  Y02E10/50 ,  Y02P70/521

摘要： A photovoltaic device and method include a doped germanium-containing substrate, an emitter contact coupled to the substrate on a first side and a back contact coupled to the substrate on a side opposite the first side. The emitter includes at least one doped layer of an opposite conductivity type as that of the substrate and the back contact includes at least one doped layer of the same conductivity type as that of the substrate. The at least one doped layer of the emitter contact or the at least one doped layer of the back contact is in direct contact with the substrate, and the at least one doped layer of the emitter contact or the back contact includes an n-type material having an electron affinity smaller than that of the substrate, or a p-type material having a hole affinity larger than that of the substrate.