公开(公告)号：US07830644B2

公开(公告)日：2010-11-09

申请号：US11713783

申请日：2007-03-05

申请人： Narsingh B. Singh ,  John J. Talvacchio ,  Marc Sherwin ,  Andre Berghmans ,  David J. Knuteson ,  David Kahler ,  Brian Wagner ,  John D. Adam

发明人： Narsingh B. Singh ,  John J. Talvacchio ,  Marc Sherwin ,  Andre Berghmans ,  David J. Knuteson ,  David Kahler ,  Brian Wagner ,  John D. Adam

IPC分类号： H01G4/06 ,  H01G4/005

CPC分类号： C01G23/002 ,  C01P2002/34 ,  C01P2002/72 ,  C01P2006/40 ,  C04B35/462 ,  C04B2235/3208 ,  C04B2235/3227 ,  C04B2235/3281 ,  H01G4/105 ,  H01G4/1209 ,  H01G4/1218 ,  H01G4/306

摘要： Methods of producing polycrystalline and single crystal dielectrics are disclosed, including dielectrics comprising CaCu3Ti4O12 or La3Ga5SiO4. Superior single crystals are manufactured with improved crystallinity by atomic lattice constant adjustments to the dielectric and to the substrate on which it is grown. Dielectric materials made according to the disclosed methods are useful for manufacture of energy storage devices, e.g. capacitors.

摘要翻译： 公开了生产多晶和单晶电介质的方法，包括包含CaCu 3 Ti 4 O 12或La 3 Ga 5 SiO 4的电介质。 通过原子晶格常数调整电介质及其生长衬底，制造出具有改善的结晶度的高级单晶。 根据所公开的方法制备的电介质材料可用于制造储能装置，例如， 电容器

公开(公告)号：US20080218940A1

公开(公告)日：2008-09-11

申请号：US11713783

申请日：2007-03-05

申请人： Narsingh B. Singh ,  John J. Talvacchio ,  Marc Sherwin ,  Andre Berghmans ,  David J. Knuteson ,  David Kahler ,  Brian Wagner ,  John D. Adam

发明人： Narsingh B. Singh ,  John J. Talvacchio ,  Marc Sherwin ,  Andre Berghmans ,  David J. Knuteson ,  David Kahler ,  Brian Wagner ,  John D. Adam

IPC分类号： H01G5/013 ,  C01F11/02 ,  C01F17/00 ,  C01G23/00 ,  C01G3/02 ,  H01G5/011

CPC分类号： C01G23/002 ,  C01P2002/34 ,  C01P2002/72 ,  C01P2006/40 ,  C04B35/462 ,  C04B2235/3208 ,  C04B2235/3227 ,  C04B2235/3281 ,  H01G4/105 ,  H01G4/1209 ,  H01G4/1218 ,  H01G4/306

摘要： Methods of producing polycrystalline and single crystal dielectrics are disclosed, including dielectrics comprising CaCu3Ti4O12 or La3Ga5SiO4. Superior single crystals are manufactured with improved crystallinity by atomic lattice constant adjustments to the dielectric and to the substrate on which it is grown. Dielectric materials made according to the disclosed methods are useful for manufacture of energy storage devices, e.g. capacitors.

摘要翻译： 公开了生产多晶和单晶电介质的方法，包括包含CaC 3 3 Ti 4 O 12或La 3 N 3的电介质 > 5 SiO 4。 通过原子晶格常数调整电介质及其生长衬底，制造出具有改善结晶度的高级单晶。 根据所公开的方法制备的电介质材料可用于制造储能装置，例如， 电容器

公开(公告)号：US09570646B2

公开(公告)日：2017-02-14

申请号：US14185567

申请日：2014-02-20

申请人： Narsingh B. Singh ,  John V. Veliadis ,  Bettina Nechay ,  Andre Berghmans ,  David J. Knuteson ,  David Kahler ,  Brian Wagner ,  Marc Sherwin

发明人： Narsingh B. Singh ,  John V. Veliadis ,  Bettina Nechay ,  Andre Berghmans ,  David J. Knuteson ,  David Kahler ,  Brian Wagner ,  Marc Sherwin

IPC分类号： H01L31/107 ,  H01L31/0336 ,  H01L31/0232 ,  H01L27/144 ,  H01L31/18

CPC分类号： H01L31/1075 ,  H01L27/1443 ,  H01L27/1446 ,  H01L31/02327 ,  H01L31/0336 ,  H01L31/035227 ,  H01L31/18

摘要： An integrated circuit includes a substrate material that includes an epitaxial layer, wherein the substrate material and the epitaxial layer form a first semiconductor material with the epitaxial layer having a first conductivity type. At least one nanowire comprising a second semiconductor material having a second conductivity type doped differently than the first conductivity type of the first semiconductor material forms a junction crossing region with the first semiconductor material. The nanowire and the first semiconductor material form an avalanche photodiode (APD) in the junction crossing region to enable single photon detection. In an alternative configuration, the APD is formed as a p-i-n crossing region where n represents an n-type material, i represents an intrinsic layer, and p represents a p-type material.

摘要翻译： 集成电路包括包括外延层的衬底材料，其中衬底材料和外延层形成具有第一导电类型的外延层的第一半导体材料。 包括不同于第一半导体材料的第一导电类型掺杂的具有第二导电类型的第二半导体材料的至少一个纳米线与第一半导体材料形成结交​​叉区域。 纳米线和第一半导体材料在结交叉区域形成雪崩光电二极管（APD），以实现单光子检测。 在替代配置中，APD形成为p-i-n交叉区域，其中n表示n型材料，i表示本征层，p表示p型材料。

公开(公告)号：US10211359B2

公开(公告)日：2019-02-19

申请号：US15356152

申请日：2016-11-18

申请人： Narsingh B. Singh ,  John V. Veliadis ,  Bettina Nechay ,  Andre Berghmans ,  David J. Knuteson ,  David Kahler ,  Brian Wagner ,  Marc Sherwin

发明人： Narsingh B. Singh ,  John V. Veliadis ,  Bettina Nechay ,  Andre Berghmans ,  David J. Knuteson ,  David Kahler ,  Brian Wagner ,  Marc Sherwin

IPC分类号： H01L31/107 ,  H01L31/0336 ,  H01L31/0232 ,  H01L27/144 ,  H01L31/18 ,  H01L31/0352

摘要： An integrated circuit includes a substrate material that includes an epitaxial layer, wherein the substrate material and the epitaxial layer form a first semiconductor material with the epitaxial layer having a first conductivity type. At least one nanowire comprising a second semiconductor material having a second conductivity type doped differently than the first conductivity type of the first semiconductor material forms a junction crossing region with the first semiconductor material. The nanowire and the first semiconductor material form an avalanche photodiode (APD) in the junction crossing region to enable single photon detection. In an alternative configuration, the APD is formed as a p-i-n crossing region where n represents an n-type material, i represents an intrinsic layer, and p represents a p-type material.

公开(公告)号：US20150236186A1

公开(公告)日：2015-08-20

申请号：US14185567

申请日：2014-02-20

申请人： NARSINGH B. SINGH ,  John V. Veliadis ,  Bettina Nechay ,  Andre Berghmans ,  David J. Knuteson ,  David Kahler ,  Brian Wagner ,  Marc Sherwin

发明人： NARSINGH B. SINGH ,  John V. Veliadis ,  Bettina Nechay ,  Andre Berghmans ,  David J. Knuteson ,  David Kahler ,  Brian Wagner ,  Marc Sherwin

IPC分类号： H01L31/107 ,  H01L31/18 ,  H01L27/144 ,  H01L31/0336 ,  H01L31/0232

CPC分类号： H01L31/1075 ,  H01L27/1443 ,  H01L27/1446 ,  H01L31/02327 ,  H01L31/0336 ,  H01L31/035227 ,  H01L31/18

摘要： An integrated circuit includes a substrate material that includes an epitaxial layer, wherein the substrate material and the epitaxial layer form a first semiconductor material with the epitaxial layer having a first conductivity type. At least one nanowire comprising a second semiconductor material having a second conductivity type doped differently than the first conductivity type of the first semiconductor material forms a junction crossing region with the first semiconductor material. The nanowire and the first semiconductor material form an avalanche photodiode (APD) in the junction crossing region to enable single photon detection. In an alternative configuration, the APD is formed as a p-i-n crossing region where n represents an n-type material, i represents an intrinsic layer, and p represents a p-type material.

摘要翻译： 集成电路包括包括外延层的衬底材料，其中衬底材料和外延层形成具有第一导电类型的外延层的第一半导体材料。 包括不同于第一半导体材料的第一导电类型掺杂的具有第二导电类型的第二半导体材料的至少一个纳米线与第一半导体材料形成结交​​叉区域。 纳米线和第一半导体材料在结交叉区域形成雪崩光电二极管（APD），以实现单光子检测。 在替代配置中，APD形成为p-i-n交叉区域，其中n表示n型材料，i表示本征层，p表示p型材料。

公开(公告)号：US20100192840A1

公开(公告)日：2010-08-05

申请号：US12713753

申请日：2010-02-26

申请人： Narsingh B. Singh ,  Brian P. Wagner ,  David J. Knuteson ,  Michael E. Aumer ,  Andre Berghmans ,  Darren Thomson ,  David Kahler

发明人： Narsingh B. Singh ,  Brian P. Wagner ,  David J. Knuteson ,  Michael E. Aumer ,  Andre Berghmans ,  Darren Thomson ,  David Kahler

IPC分类号： C30B23/02

CPC分类号： H01L29/1608 ,  H01L29/66068 ,  H01L29/66242 ,  H01L29/66431 ,  H01L29/737 ,  H01L29/7781 ,  H01L29/7786

摘要： A Si(1-x)MxC material for heterostructures on SiC can be grown by CVD, PVD and MOCVD. SIC doped with a metal such as Al modifies the bandgap and hence the heterostructure. Growth of SiC Si(1-x)MxC heterojunctions using SiC and metal sources permits the fabrication of improved HFMTs (high frequency mobility transistors), HBTs (heterojunction bipolar transistors), and HEMTs (high electron mobility transistors).

摘要翻译： 可以通过CVD，PVD和MOCVD生长用于SiC上异质结构的Si（1-x）MxC材料。 掺杂有诸如Al的金属的SIC改变带隙并因此改变异质结构。 使用SiC和金属源的SiC Si（1-x）MxC异质结的生长允许制造改进的HFMT（高频迁移率晶体管），HBT（异质结双极晶体管）和HEMT（高电子迁移率晶体管）。

公开(公告)号：US07855108B2

公开(公告)日：2010-12-21

申请号：US12713753

申请日：2010-02-26

申请人： Narsingh B. Singh ,  Brian P. Wagner ,  David J. Knuteson ,  Michael E. Aumer ,  Andre Berghmans ,  Darren Thomson ,  David Kahler

发明人： Narsingh B. Singh ,  Brian P. Wagner ,  David J. Knuteson ,  Michael E. Aumer ,  Andre Berghmans ,  Darren Thomson ,  David Kahler

IPC分类号： H01L21/338

CPC分类号： H01L29/1608 ,  H01L29/66068 ,  H01L29/66242 ,  H01L29/66431 ,  H01L29/737 ,  H01L29/7781 ,  H01L29/7786

摘要： A Si(1-x)MxC material for heterostructures on SiC can be grown by CVD, PVD and MOCVD. SIC doped with a metal such as Al modifies the bandgap and hence the heterostructure. Growth of SiC Si(1-x)MxC heterojunctions using SiC and metal sources permits the fabrication of improved HFMTs (high frequency mobility transistors), HBTs (heterojunction bipolar transistors), and HEMTs (high electron mobility transistors).

摘要翻译： 可以通过CVD，PVD和MOCVD生长用于SiC上异质结构的Si（1-x）MxC材料。 掺杂有诸如Al的金属的SIC改变带隙并因此改变异质结构。 使用SiC和金属源的SiC Si（1-x）MxC异质结的生长允许制造改进的HFMT（高频迁移率晶体管），HBT（异质结双极晶体管）和HEMT（高电子迁移率晶体管）。

公开(公告)号：US07683400B1

公开(公告)日：2010-03-23

申请号：US11474398

申请日：2006-06-26

申请人： Narsingh B. Singh ,  Brian P. Wagner ,  David J. Knuteson ,  Michael E. Aumer ,  Andre Berghmans ,  Darren Thomson ,  David Kahler

发明人： Narsingh B. Singh ,  Brian P. Wagner ,  David J. Knuteson ,  Michael E. Aumer ,  Andre Berghmans ,  Darren Thomson ,  David Kahler

IPC分类号： H01L29/08

CPC分类号： H01L29/1608 ,  H01L29/66068 ,  H01L29/66242 ,  H01L29/66431 ,  H01L29/737 ,  H01L29/7781 ,  H01L29/7786

摘要： A Si(1-x)MxC material for heterostructures on SiC can be grown by CVD, PVD and MOCVD. SIC doped with a metal such as Al modifies the bandgap and hence the heterostructure. Growth of SiC Si(1-x)MxC heterojunctions using SiC and metal sources permits the fabrication of improved HFMTs (high frequency mobility transistors), HBTs (heterojunction bipolar transistors), and HEMTs (high electron mobility transistors).

公开(公告)号：US20090220801A1

公开(公告)日：2009-09-03

申请号：US12040785

申请日：2008-02-29

申请人： Brian Wagner ,  Travis J. Randall ,  Thomas J. Knight ,  David J. Knuteson ,  David Kahler ,  Andre E. Berghmans ,  Sean R. McLaughlin ,  Narsingh B. Singh ,  Mark Usefara

发明人： Brian Wagner ,  Travis J. Randall ,  Thomas J. Knight ,  David J. Knuteson ,  David Kahler ,  Andre E. Berghmans ,  Sean R. McLaughlin ,  Narsingh B. Singh ,  Mark Usefara

IPC分类号： C23C14/34 ,  B32B9/04

CPC分类号： C30B29/36 ,  C30B23/02

摘要： The disclosure relates to a method and apparatus for growth of high-purity 6H SiC single crystal using a sputtering technique. In one embodiment, the disclosure relates to a method for depositing a high purity 6H-SiC single crystal film on a substrate, the method including: providing a silicon substrate having an etched surface; placing the substrate and an SiC source in a deposition chamber; achieving a first vacuum level in the deposition chamber; pressurizing the chamber with a gas; depositing the SiC film directly on the etched silicon substrate from a sputtering source by: heating the substrate to a temperature below silicon melting point, using a low energy plasma in the deposition chamber; and depositing a layer of hexagonal SiC film on the etched surface of the substrate.

摘要翻译： 本公开涉及使用溅射技术生长高纯度6H SiC单晶的方法和装置。 在一个实施方案中，本公开涉及一种用于在基底上沉积高纯度6H-SiC单晶膜的方法，所述方法包括：提供具有蚀刻表面的硅衬底; 将衬底和SiC源放置在沉积室中; 在沉积室中达到第一真空度; 用气体对腔室加压; 通过以下方式将SiC膜直接沉积在蚀刻的硅衬底上：使用沉积室中的低能量等离子体将衬底加热到​​低于硅熔点的温度; 以及在衬底的蚀刻表面上沉积一层六方形的SiC膜。

公开(公告)号：US20090302426A1

公开(公告)日：2009-12-10

申请号：US12136193

申请日：2008-06-10

申请人： Sean R. McLaughlin ,  Narsingh Bahadur Singh ,  Brian Wagner ,  Andre Berghmans ,  David J. Knuteson ,  David Kahler ,  Anthony A. Margarella

发明人： Sean R. McLaughlin ,  Narsingh Bahadur Singh ,  Brian Wagner ,  Andre Berghmans ,  David J. Knuteson ,  David Kahler ,  Anthony A. Margarella

IPC分类号： H01L21/329 ,  H01L29/868

CPC分类号： F01P3/2285 ,  F01P2025/04 ,  Y10S977/774

摘要： A process is provided for fabricating a semiconductor device having a germanium nanofilm layer that is selectively deposited on a silicon substrate in discrete regions or patterns. A semiconductor device is also provided having a germanium film layer that is disposed in desired regions or having desired patterns that can be prepared in the absence of etching and patterning the germanium film layer. A process is also provided for preparing a semiconductor device having a silicon substrate having one conductivity type and a germanium nanofilm layer of a different conductivity type. Semiconductor devices are provided having selectively grown germanium nanofilm layer, such as diodes including light emitting diodes, photodetectors, and like. The method can also be used to make advanced semiconductor devices such as CMOS devices, MOSFET devices, and the like.

摘要翻译： 提供了一种用于制造具有以离散区域或图案选择性地沉积在硅衬底上的锗纳米膜层的半导体器件的工艺。 还提供了一种半导体器件，其具有锗膜层，其设置在期望的区域中或具有可在不进行蚀刻和图案化锗膜层的情况下制备的所需图案。 还提供了制备具有一种导电类型的硅衬底和不同导电类型的锗纳米膜层的半导体器件的工艺。 提供具有选择性生长的锗纳米薄膜层的半导体器件，例如包括发光二极管，光电探测器等的二极管。 该方法也可用于制造诸如CMOS器件，MOSFET器件等的先进的半导体器件。