公开(公告)号：US07829883B2

公开(公告)日：2010-11-09

申请号：US10777576

申请日：2004-02-12

申请人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

发明人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

IPC分类号： H01L29/06

CPC分类号： H01L51/057 ,  B82Y10/00 ,  G11C13/025 ,  H01L29/0665 ,  H01L29/0673 ,  H01L29/0676 ,  H01L29/125 ,  H01L29/66409 ,  H01L29/772 ,  H01L51/0048 ,  Y10S977/734

摘要： Carbon nanotube field effect transistors, arrays of carbon nanotube field effect transistors, device structures, and arrays of device structures. A stacked device structure includes a gate electrode layer and catalyst pads each coupled electrically with a source/drain contact. The gate electrode layer is divided into multiple gate electrodes and at least one semiconducting carbon nanotube is synthesized by a chemical vapor deposition process on each of the catalyst pads. The gate electrode has a sidewall covered by a gate dielectric and at least one semiconducting carbon nanotube adjacent to the sidewall of the gate electrode. Source/drain contacts are electrically coupled with opposite ends of the semiconducting carbon nanotube to complete the device structure. Multiple device structures may be configured either as a memory circuit or as a logic circuit.

摘要翻译： 碳纳米管场效应晶体管，碳纳米管场效应晶体管阵列，器件结构和器件结构阵列。 叠层器件结构包括栅极电极层和各个与源极/漏极接触电连接的催化剂焊盘。 栅电极层被分成多个栅极电极，并且通过化学气相沉积工艺在每个催化剂焊盘上合成至少一个半导体碳纳米管。 栅电极具有被栅极电介质覆盖的侧壁和与栅电极的侧壁相邻的至少一个半导体碳纳米管。 源极/漏极触点与半导体碳纳米管的相对端电耦合以完成器件结构。 多个器件结构可以被配置为存储器电路或逻辑电路。

公开(公告)号：US07691720B2

公开(公告)日：2010-04-06

申请号：US11926661

申请日：2007-10-29

申请人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

发明人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

IPC分类号： H01L21/76

CPC分类号： H01L51/057 ,  B82Y10/00 ,  H01L51/0048 ,  Y10S977/70 ,  Y10S977/734 ,  Y10S977/742

摘要： Vertical device structures incorporating at least one nanotube and methods for fabricating such device structures by chemical vapor deposition. Each nanotube is grown by chemical vapor deposition catalyzed by a catalyst pad and encased in a coating of a dielectric material. Vertical field effect transistors may be fashioned by forming a gate electrode about the encased nanotubes such that the encased nanotubes extend vertically through the thickness of the gate electrode. Capacitors may be fashioned in which the encased nanotubes and the corresponding catalyst pad bearing the encased nanotubes forms one capacitor plate.

摘要翻译： 结合至少一个纳米管的垂直器件结构和通过化学气相沉积制造这种器件结构的方法。 每个纳米管通过由催化剂垫催化的化学气相沉积生长并且包裹在电介质材料的涂层中。 可以通过围绕封装的纳米管形成栅电极来形成垂直场效应晶体管，使得封装的纳米管垂直延伸穿过栅电极的厚度。 可以形成电容器，其中包裹的纳米管和带有封装的纳米管的相应的催化剂垫片形成一个电容器板。

公开(公告)号：US07851064B2

公开(公告)日：2010-12-14

申请号：US12031493

申请日：2008-02-14

申请人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

发明人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

IPC分类号： B32B9/00

CPC分类号： B82Y30/00 ,  B82Y10/00 ,  B82Y40/00 ,  C01B32/162 ,  C01B2202/06 ,  C01B2202/22 ,  C01B2202/34 ,  H01J1/3044 ,  H01J2201/30469 ,  Y10S977/742 ,  Y10S977/84 ,  Y10S977/842 ,  Y10S977/843 ,  Y10T428/30

摘要： Methods for synthesizing carbon nanotubes and structures formed thereby, includes forming carbon nanotubes on a plurality of synthesis sites supported by a first substrate, interrupting nanotube synthesis, mounting a free end of each carbon nanotube to a second substrate, and removing the first substrate. Each carbon nanotube is capped by one of the synthesis sites, to which growth reactants have ready access.

摘要翻译： 合成碳纳米管和由此形成的结构的方法包括在由第一衬底支撑的多个合成位置上形成碳纳米管，中断纳米管合成，将每个碳纳米管的自由端安装到第二衬底上，以及去除第一衬底。 每个碳纳米管被其中一个合成位点封盖，生长反应物可以随时进入。

公开(公告)号：US07038299B2

公开(公告)日：2006-05-02

申请号：US10732951

申请日：2003-12-11

申请人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

发明人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

IPC分类号： H01L29/12 ,  H01L29/06 ,  H01L21/205 ,  H01L21/64

CPC分类号： H01L51/0512 ,  B82Y10/00 ,  B82Y30/00 ,  B82Y40/00 ,  C01B32/162 ,  C01B2202/22 ,  C01B2202/34 ,  C30B25/02 ,  C30B29/02 ,  C30B29/605 ,  H01L51/0048 ,  Y10S977/854

摘要： Methods for selecting semiconducting carbon nanotubes from a random collection of conducting and semiconducting carbon nanotubes synthesized on multiple synthesis sites carried by a substrate and structures formed thereby. After an initial growth stage, synthesis sites bearing conducting carbon nanotubes are altered to discontinue synthesis at these specific synthesis sites and, thereby, halt lengthening of the conducting carbon nanotubes. Synthesis sites bearing semiconducting carbon nanotubes are unaffected by the alteration so that semiconducting carbon nanotubes may be lengthened to a greater length than the conducting carbon nanotubes.

摘要翻译： 从由衬底承载的多个合成位点上合成的导电和半导体碳纳米管的随机集合以及由此形成的结构选择半导体碳纳米管的方法。 在初始生长阶段之后，改变承载导电碳纳米管的合成位点，以在这些特定合成位点停止合成​​，从而停止导电碳纳米管的延长。 具有半导体碳纳米管的合成位点不受改变的影响，使得半导体碳纳米管可以被延长到比导电碳纳米管更长的长度。

公开(公告)号：US07264415B2

公开(公告)日：2007-09-04

申请号：US10798908

申请日：2004-03-11

申请人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

发明人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

IPC分类号： G03F1/00 ,  G03C5/00

CPC分类号： G03F1/30

摘要： Methods for fabricating alternating phase shift masks or reticles used in semiconductor optical lithography systems. The methods generally include forming a layer of phase shift mask material on a handle substrate and patterning the layer to define recessed phase shift windows. The patterned layer is transferred from the handle wafer to a mask blank. The depth of the phase shift windows is determined by the thickness of the layer of phase shift mask material and is independent of the patterning process. In particular, the depth of the phase shift windows is not dependent upon the etch rate uniformity of an etch process across a surface of a mask blank.

摘要翻译： 用于制造用于半导体光刻系统中的交替相移掩模或掩模版的方法。 所述方法通常包括在手柄基板上形成一层相移掩模材料，并且图案化该层以限定凹陷的相移窗口。 图案层从手柄晶片转移到掩模板。 相移窗口的深度由相移掩模材料层的厚度确定，并且与图案化工艺无关。 特别地，相移窗口的深度不依赖于通过掩模板的表面的蚀刻工艺的蚀刻速率均匀性。

公开(公告)号：US07951660B2

公开(公告)日：2011-05-31

申请号：US10703355

申请日：2003-11-07

申请人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Larry Alan Nesbit

发明人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Larry Alan Nesbit

IPC分类号： H01L21/336

CPC分类号： H01L29/66772 ,  H01L21/2807 ,  H01L29/4908

摘要： A method for fabricating a metal-oxide-semiconductor device structure. The method includes introducing a dopant species concurrently into a semiconductor active layer that overlies an insulating layer and a gate electrode overlying the semiconductor active layer by ion implantation. The thickness of the semiconductor active layer, the thickness of the gate electrode, and the kinetic energy of the dopant species are chosen such that the projected range of the dopant species in the semiconductor active layer and insulating layer lies within the insulating layer and a projected range of the dopant species in the gate electrode lies within the gate electrode. As a result, the semiconductor active layer and the gate electrode may be doped simultaneously during a single ion implantation and without the necessity of an additional implant mask.

摘要翻译： 一种制造金属氧化物半导体器件结构的方法。 该方法包括通过离子注入将掺杂剂物质同时引入覆盖在半导体有源层上的绝缘层和栅电极的半导体有源层中。 选择半导体有源层的厚度，栅电极的厚度和掺杂剂物质的动能，使得半导体有源层和绝缘层中的掺杂剂物质的投影范围位于绝缘层内，并且投影 栅电极中的掺杂物种类的范围位于栅电极内。 结果，半导体有源层和栅电极可以在单个离子注入期间同时掺杂，而不需要另外的注入掩模。

公开(公告)号：US07994575B2

公开(公告)日：2011-08-09

申请号：US11175582

申请日：2005-07-06

申请人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Larry Alan Nesbit

发明人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Larry Alan Nesbit

IPC分类号： H01L21/336

CPC分类号： H01L29/66772 ,  H01L21/2807 ,  H01L29/4908

摘要： A method for fabricating a metal-oxide-semiconductor device structure. The method includes introducing a dopant species concurrently into a semiconductor active layer that overlies an insulating layer and a gate electrode overlying the semiconductor active layer by ion implantation. The thickness of the semiconductor active layer, the thickness of the gate electrode, and the kinetic energy of the dopant species are chosen such that the projected range of the dopant species in the semiconductor active layer and insulating layer lies within the insulating layer and a projected range of the dopant species in the gate electrode lies within the gate electrode. As a result, the semiconductor active layer and the gate electrode may be doped simultaneously during a single ion implantation and without the necessity of an additional implant mask.

摘要翻译： 一种制造金属氧化物半导体器件结构的方法。 该方法包括通过离子注入将掺杂剂物质同时引入覆盖在半导体有源层上的绝缘层和栅电极的半导体有源层中。 选择半导体有源层的厚度，栅电极的厚度和掺杂剂物质的动能，使得半导体有源层和绝缘层中的掺杂剂物质的投影范围位于绝缘层内，并且投影 栅电极中的掺杂物种类的范围位于栅电极内。 结果，半导体有源层和栅电极可以在单个离子注入期间同时掺杂，而不需要另外的注入掩模。

公开(公告)号：US07273794B2

公开(公告)日：2007-09-25

申请号：US10732953

申请日：2003-12-11

申请人： Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

发明人： Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

IPC分类号： H01L21/76

CPC分类号： H01L27/1203 ,  H01L21/76283 ,  H01L21/84

摘要： To isolate two active regions formed on a silicon-on-insulator (SOI) substrate, a shallow trench isolation region is filled with liquid phase deposited silicon dioxide (LPD-SiO2) while avoiding covering the active areas with the oxide. By selectively depositing the oxide in this manner, the polishing needed to planarize the wafer is significantly reduced as compared to a chemical-vapor deposited oxide layer that covers the entire wafer surface. Additionally, the LPD-SiO2 does not include the growth seams that CVD silicon dioxide does. Accordingly, the etch rate of the LPD-SiO2 is uniform across its entire expanse thereby preventing cavities and other etching irregularities present in prior art shallow trench isolation regions in which the etch rate of growth seams exceeds that of the other oxide areas.

摘要翻译： 为了隔离形成在绝缘体上硅（SOI）衬底上的两个有源区，浅沟槽隔离区填充有液相沉积二氧化硅（LPD-SiO 2），同时避免覆盖有源区 与氧化物。 通过以这种方式选择性地沉积氧化物，与覆盖整个晶片表面的化学气相沉积氧化物层相比，平坦化晶片所需的抛光显着降低。 此外，LPD-SiO 2不包括CVD二氧化硅的生长接缝。 因此，LPD-SiO 2的蚀刻速率在其整个宽度上是均匀的，从而防止存在于现有技术的浅沟槽隔离区域中的空穴和其它蚀刻不规则性，其中生长接缝的蚀刻速率超过 其他氧化物区域。

公开(公告)号：US07525156B2

公开(公告)日：2009-04-28

申请号：US11760477

申请日：2007-06-08

申请人： Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

发明人： Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell ,  Larry Alan Nesbit

IPC分类号： H01L23/58

CPC分类号： H01L27/1203 ,  H01L21/76283 ,  H01L21/84

摘要： To isolate two active regions formed on a silicon-on-insulator (SOI) substrate, a shallow trench isolation region is filled with liquid phase deposited silicon dioxide (LPD-SiO2) while avoiding covering the active areas with the oxide. By selectively depositing the oxide in this manner, the polishing needed to planarize the wafer is significantly reduced as compared to a chemical-vapor deposited oxide layer that covers the entire wafer surface. Additionally, the LPD-SiO2 does not include the growth seams that CVD silicon dioxide does. Accordingly, the etch rate of the LPD-SiO2 is uniform across its entire expanse thereby preventing cavities and other etching irregularities present in prior art shallow trench isolation regions in which the etch rate of growth seams exceeds that of the other oxide areas.

摘要翻译： 为了隔离形成在绝缘体上硅（SOI）衬底上的两个有源区，浅沟槽隔离区填充有液相沉积二氧化硅（LPD-SiO 2），同时避免用氧化物覆盖有源区。 通过以这种方式选择性地沉积氧化物，与覆盖整个晶片表面的化学气相沉积氧化物层相比，平坦化晶片所需的抛光显着降低。 另外，LPD-SiO2不包括CVD二氧化硅的生长接缝。 因此，LPD-SiO 2的蚀刻速率在其整个宽度上是均匀的，从而防止存在于现有技术的浅沟槽隔离区域中的空腔和其它蚀刻不规则性，其中生长接缝的蚀刻速率超过其它氧化物区域的蚀刻速率。

公开(公告)号：US20100273298A1

公开(公告)日：2010-10-28

申请号：US12830510

申请日：2010-07-06

申请人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell

发明人： Toshiharu Furukawa ,  Mark Charles Hakey ,  Steven John Holmes ,  David Vaclav Horak ,  Charles William Koburger, III ,  Peter H. Mitchell

IPC分类号： H01L21/98

CPC分类号： H01L21/7685 ,  B82Y10/00 ,  H01L21/32051 ,  H01L21/76838 ,  H01L21/76876 ,  H01L21/76877 ,  H01L23/53276 ,  H01L51/0048 ,  H01L51/0052 ,  H01L2221/1094 ,  H01L2924/0002 ,  Y10S977/742 ,  Y10S977/762 ,  Y10S977/778 ,  Y10S977/842 ,  H01L2924/00

摘要： A conductive layer in an integrated circuit is formed as a sandwich having multiple sublayers, including at least one sublayer of oriented carbon nanotubes. The conductive layer sandwich preferably contains two sublayers of carbon nanotubes, in which the carbon nanotube orientation in one sublayer is substantially perpendicular to that of the other layer. The conductive layer sandwich preferably contains one or more additional sublayers of a conductive material, such as a metal. In one embodiment, oriented carbon nanotubes are created by forming a series of elongated parallel catalyst strips on a horizontal surface, and growing carbon nanotubes from the catalyst in the presence of a directional flow of reactant gases.

摘要翻译： 集成电路中的导电层形成为具有多个子层的夹层，包括至少一个定向碳纳米管子层。 导电层夹层优选包含两个碳纳米管子层，其中一个子层中的碳纳米管取向基本上垂直于另一层的碳纳米管取向。 导电层夹层优选地包含一种或多种另外的导电材料的子层，例如金属。 在一个实施方案中，定向碳纳米管通过在水平表面上形成一系列细长的平行催化剂条而形成，并且在有反应气体的定向流的存在下从催化剂生长碳纳米管。