公开(公告)号：US08362295B2

公开(公告)日：2013-01-29

申请号：US12812169

申请日：2009-01-08

Applicant: James M. Tour ,  Howard K. Schmidt ,  Condell D. Doyle ,  Dmitry V. Kosynkin ,  Jay R. Lomeda

Inventor： James M. Tour ,  Howard K. Schmidt ,  Condell D. Doyle ,  Dmitry V. Kosynkin ,  Jay R. Lomeda

IPC: C07C63/00 ,  C07C25/24 ,  C07C205/45 ,  C07C43/235 ,  C07C17/281 ,  C01B31/00

CPC classification number: C09K8/032 ,  B82Y30/00 ,  B82Y40/00 ,  C01B32/192 ,  C01B32/194 ,  C01B32/23 ,  C01B2204/04 ,  C01B2204/28 ,  C09K8/035 ,  C09K8/62 ,  Y10S977/734 ,  Y10S977/737 ,  Y10S977/738

Abstract: Drilling fluids comprising graphenes and nanoplatelet additives and methods for production thereof are disclosed. Graphene includes graphite oxide, graphene oxide, chemically-converted graphene, and functionalized chemically-converted graphene. Derivatized graphenes and methods for production thereof are disclosed. The derivatized graphenes are prepared from a chemically-converted graphene through derivatization with a plurality of functional groups. Derivatization can be accomplished, for example, by reaction of a chemically-converted graphene with a diazonium species. Methods for preparation of graphite oxide are also disclosed.

Abstract translation: 公开了包含石墨烯和纳米血小板添加剂的钻井液及其生产方法。 石墨烯包括氧化石墨，氧化石墨烯，化学转化的石墨烯和官能化的化学转化的石墨烯。 公开了衍生化的石墨烯及其生产方法。 衍生的石墨烯通过具有多个官能团的衍生化由化学转化的石墨烯制备。 衍生化可以通过例如化学转化的石墨烯与重氮物质的反应来实现。 还公开了制备氧化石墨的方法。

公开(公告)号：US20120107597A1

公开(公告)日：2012-05-03

申请号：US12297115

申请日：2007-04-23

Applicant: Myung Jong Kim ,  Nolan Walker Nicholas ,  W. Carter Kittrell ,  Howard K. Schmidt

Inventor： Myung Jong Kim ,  Nolan Walker Nicholas ,  W. Carter Kittrell ,  Howard K. Schmidt

IPC: B32B5/16 ,  B29C45/14 ,  H01B1/04 ,  B82Y30/00

CPC classification number: C01B31/0206 ,  B82Y10/00 ,  B82Y30/00 ,  B82Y40/00 ,  C01B32/15 ,  H01L51/0048 ,  Y10T428/249924

Abstract: According to some embodiments, the present invention provides a system and method for supporting a carbon nanotube array that involve an entangled carbon nanotube mat integral with the array, where the mat is embedded in an embedding material. The embedding material may be depositable on a carbon nanotube. A depositable material may be metallic or nonmetallic. The embedding material may be an adhesive material. The adhesive material may optionally be mixed with a metal powder. The embedding material may be supported by a substrate or self-supportive. The embedding material may be conductive or nonconductive. The system and method provide superior mechanical and, when applicable, electrical, contact between the carbon nanotubes in the array and the embedding material. The optional use of a conductive material for the embedding material provides a mechanism useful for integration of carbon nanotube arrays into electronic devices.

Abstract translation: 根据一些实施方案，本发明提供了一种用于支撑碳纳米管阵列的系统和方法，所述碳纳米管阵列涉及与所述阵列整合的缠结碳纳米管垫，其中所述垫嵌入嵌入材料中。 嵌入材料可以沉积在碳纳米管上。 可存放材料可以是金属或非金属的。 嵌入材料可以是粘合剂材料。 粘合剂材料可以任选地与金属粉末混合。 嵌入材料可以由衬底支撑或自支撑。 嵌入材料可以是导电的或非导电的。 该系统和方法在阵列中的碳纳米管和嵌入材料之间提供优异的机械性能，并且在适用时提供电气接触。 可选地使用用于嵌入材料的导电材料提供了用于将碳纳米管阵列集成到电子器件中的机制。

公开(公告)号：US20100284898A1

公开(公告)日：2010-11-11

申请号：US12299634

申请日：2007-05-07

Applicant: Kirk J. Ziegler ,  Urs Rauwald ,  Robert H. Hauge ,  Howard K. Schmidt ,  Irene Morin Marek ,  Zhenning Gu ,  W. Carter Kittrell

Inventor： Kirk J. Ziegler ,  Urs Rauwald ,  Robert H. Hauge ,  Howard K. Schmidt ,  Irene Morin Marek ,  Zhenning Gu ,  W. Carter Kittrell

IPC: D01F9/12

CPC classification number: C01B32/176 ,  C01B32/174 ,  C01B2202/02 ,  C01B2202/28 ,  C01B2202/34

Abstract: According to some embodiments, the present invention provides a method for attaining short carbon nanotubes utilizing electron beam irradiation, for example, of a carbon nanotube sample. The sample may be pretreated, for example by oxonation. The pretreatment may introduce defects to the sidewalls of the nanotubes. The method is shown to produces nanotubes with a distribution of lengths, with the majority of lengths shorter than 100 tun. Further, the median length of the nanotubes is between about 20 nm and about 100 nm.

Abstract translation: 根据一些实施方案，本发明提供了利用电子束照射来获得例如碳纳米管样品的短碳纳米管的方法。 样品可以进行预处理，例如通过氧化。 预处理可能在纳米管的侧壁上引入缺陷。 该方法显示产生具有长度分布的纳米管，其大部分长度短于100μm。 此外，纳米管的中值长度在约20nm和约100nm之间。

公开(公告)号：US20100140591A1

公开(公告)日：2010-06-10

申请号：US11910522

申请日：2007-02-02

Applicant: Nolan Walker Nicholas ,  W Carter Kittrell ,  Myung Jong Kim ,  Howard K. Schmidt

Inventor： Nolan Walker Nicholas ,  W Carter Kittrell ,  Myung Jong Kim ,  Howard K. Schmidt

IPC: H01L51/10 ,  H01L51/40

CPC classification number: H01L51/057 ,  B82Y10/00 ,  H01L51/0048

Abstract: A method for forming nanotube electrical devices, arrays of nanotube electrical devices, and device structures and arrays of device structures formed by the methods. Various methods of the present invention allow creation of semiconducting and/or conducting devices from readily grown SWNT carpets rather than requiring the preparation of a patterned growth channel and takes advantage of the self-controlling nature of these carpet heights to ensure a known and controlled channel length for reliable electronic properties as compared to the prior methods.

Abstract translation: 用于形成纳米管电子器件的方法，纳米管电子器件的阵列，以及通过该方法形成的器件结构和器件结构的阵列。 本发明的各种方法允许从容易生长的SWNT地毯制造半导体和/或导电装置，而不需要制备图案化的生长通道，并利用这些毯子高度的自我控制性质来确保已知和受控的通道 与现有方法相比可靠的电子性能。

公开(公告)号：US20090283405A1

公开(公告)日：2009-11-19

申请号：US12281444

申请日：2007-03-02

Applicant: Howard K. Schmidt ,  Haiqing Peng ,  Manuel Joao Mendes ,  Matteo Pasquali

Inventor： Howard K. Schmidt ,  Haiqing Peng ,  Manuel Joao Mendes ,  Matteo Pasquali

IPC: C02F1/469

CPC classification number: B03C5/005 ,  B03C5/026 ,  B82Y30/00 ,  B82Y40/00 ,  C01B32/172 ,  C01B2202/02 ,  C01B2202/22 ,  Y10S977/742 ,  Y10S977/751

Abstract: According to some embodiments, a method for separating a first fraction of a single wall carbon nanotubes and a second fraction of single wall carbon nanotubes includes, but is not limited to: flowing a solution comprising the nanotubes into a dielectrophoresis chamber; applying a DC voltage, in combination with an AC voltage, to the dielectrophoresis chamber; and collecting a first eluent from the dielectrophoresis chamber, wherein the first eluent comprises the first fraction and is depleted of the second fraction, wherein the first and second fractions differ by at least one of conductivity, diameter, length, and combinations thereof.

Abstract translation: 根据一些实施方案，用于分离单壁碳纳米管和第二部分单壁碳纳米管的第一部分的方法包括但不限于：将包含纳米管的溶液流动到介电电泳室中; 将DC电压与AC电压组合施加到介电电泳室; 以及从所述介电电泳腔室收集第一洗脱液，其中所述第一洗脱液包含所述第一馏分并且耗尽所述第二馏分，其中所述第一和第二馏分通过传导率，直径，长度及其组合中的至少一个而不同。

公开(公告)号：US5354584A

公开(公告)日：1994-10-11

申请号：US59245

申请日：1993-05-07

Applicant: Howard K. Schmidt

Inventor： Howard K. Schmidt

IPC: C23C14/48 ,  C23C16/27 ,  C23C16/44 ,  B05D3/06 ,  C23C16/00

CPC classification number: C23C16/278 ,  C23C14/48 ,  C23C16/27 ,  C23C16/271 ,  C23C16/44

Abstract: A material growing by deposition is exposed to a low energy beam of ionized dopant. The ion beam energy is sufficient to implant the dopant in the growing surface of the material. This doping method will work well for any dopant that is substantially immobile in the material at the temperature necessary for deposition growth.

Abstract translation: 通过沉积生长的材料暴露于电离掺杂剂的低能量束。 离子束能量足以将掺杂剂注入材料的生长表面。 该掺杂方法对于在沉积生长所需的温度下在材料中基本上不可移动的任何掺杂剂都将很好地工作。

公开(公告)号：US09067791B2

公开(公告)日：2015-06-30

申请号：US12297115

申请日：2007-04-23

Applicant: Myung Jong Kim ,  Nolan Walker Nicholas ,  W. Carter Kittrell ,  Howard K. Schmidt

Inventor： Myung Jong Kim ,  Nolan Walker Nicholas ,  W. Carter Kittrell ,  Howard K. Schmidt

IPC: B32B5/16 ,  B29C45/14 ,  H01B1/04 ,  B82Y30/00 ,  C01B31/02 ,  B82Y10/00 ,  B82Y40/00 ,  H01L51/00

CPC classification number: C01B31/0206 ,  B82Y10/00 ,  B82Y30/00 ,  B82Y40/00 ,  C01B32/15 ,  H01L51/0048 ,  Y10T428/249924

Abstract: According to some embodiments, the present invention provides a system and method for supporting a carbon nanotube array that involve an entangled carbon nanotube mat integral with the array, where the mat is embedded in an embedding material. The embedding material may be depositable on a carbon nanotube. A depositable material may be metallic or nonmetallic. The embedding material may be an adhesive material. The adhesive material may optionally be mixed with a metal powder. The embedding material may be supported by a substrate or self-supportive. The embedding material may be conductive or nonconductive. The system and method provide superior mechanical and, when applicable, electrical, contact between the carbon nanotubes in the array and the embedding material. The optional use of a conductive material for the embedding material provides a mechanism useful for integration of carbon nanotube arrays into electronic devices.

Abstract translation: 根据一些实施方案，本发明提供了一种用于支撑碳纳米管阵列的系统和方法，所述碳纳米管阵列涉及与所述阵列整合的缠结碳纳米管垫，其中所述垫嵌入嵌入材料中。 嵌入材料可以沉积在碳纳米管上。 可存放材料可以是金属或非金属的。 嵌入材料可以是粘合剂材料。 粘合剂材料可以任选地与金属粉末混合。 嵌入材料可以由衬底支撑或自支撑。 嵌入材料可以是导电的或非导电的。 该系统和方法在阵列中的碳纳米管和嵌入材料之间提供优异的机械性能，并且在适用时提供电气接触。 可选地使用用于嵌入材料的导电材料提供了用于将碳纳米管阵列集成到电子器件中的机制。

公开(公告)号：US08763387B2

公开(公告)日：2014-07-01

申请号：US12853066

申请日：2010-08-09

Applicant: Howard K. Schmidt

Inventor： Howard K. Schmidt

IPC: E21B43/26

CPC classification number: F03B13/06 ,  F02C6/16 ,  F03D9/17 ,  F03D9/255 ,  F03D9/28 ,  Y02E10/22 ,  Y02E10/46 ,  Y02E10/72 ,  Y02E60/15 ,  Y02E60/17 ,  Y02P90/50

Abstract: Energy is stored by injecting fluid into a hydraulic fracture in the earth and producing the fluid hack while recovering power. The method is particularly adapted to storage of large amounts of energy such as in grid-scale electric energy systems. The hydraulic fracture may be formed and treated with resin so as to limit fluid loss and to increase propagation pressure.

Abstract translation: 能量通过将流体注入地球的水力裂缝并在回收功率的同时产生流体侵入而被储存。 该方法特别适用于存储大量的能量，例如电网规模的电能系统。 可以用树脂形成和处理水力破裂，以限制流体损失并增加传播压力。

公开(公告)号：US08394664B2

公开(公告)日：2013-03-12

申请号：US11910522

申请日：2007-02-02

Applicant: Nolan Walker Nicholas ,  W. Carter Kittrell ,  Myung Jong Kim ,  Howard K. Schmidt

Inventor： Nolan Walker Nicholas ,  W. Carter Kittrell ,  Myung Jong Kim ,  Howard K. Schmidt

IPC: H01L51/10 ,  H01L51/40

CPC classification number: H01L51/057 ,  B82Y10/00 ,  H01L51/0048

Abstract: A method for forming nanotube electrical devices, arrays of nanotube electrical devices, and device structures and arrays of device structures formed by the methods. Various methods of the present invention allow creation of semiconducting and/or conducting devices from readily grown SWNT carpets rather than requiring the preparation of a patterned growth channel and takes advantage of the self-controlling nature of these carpet heights to ensure a known and controlled channel length for reliable electronic properties as compared to the prior methods.

Abstract translation: 用于形成纳米管电子器件的方法，纳米管电子器件的阵列，以及通过该方法形成的器件结构和器件结构的阵列。 本发明的各种方法允许从容易生长的SWNT地毯制造半导体和/或导电装置，而不需要制备图案化的生长通道，并利用这些毯子高度的自我控制性质来确保已知和受控的通道 与现有方法相比可靠的电子性能。

公开(公告)号：US20100283008A1

公开(公告)日：2010-11-11

申请号：US12679864

申请日：2008-09-24

Applicant: Juan G. Duque ,  Matteo Pasquali ,  Howard K. Schmidt ,  Laurent Cogent ,  A. Nicholas G. Parra-Vasquez

Inventor： Juan G. Duque ,  Matteo Pasquali ,  Howard K. Schmidt ,  Laurent Cogent ,  A. Nicholas G. Parra-Vasquez

IPC: C09K11/02 ,  B01J13/06

CPC classification number: B82Y30/00 ,  A61B18/28 ,  A61N5/062 ,  B82Y40/00 ,  C01B32/174 ,  C01B2202/02 ,  C01B2202/04 ,  C01B2202/06 ,  C01B2202/28 ,  C01P2004/04 ,  C01P2004/13 ,  C09C1/44

Abstract: Compositions comprising at least one type of carbon nanotube, at least one surfactant, and at least one polymer are disclosed. The compositions provide stable fluorescence over a wide range of pH in various embodiments. In some embodiments, the compositions are biocompatible. Methods for preparing the compositions from at least one pre-formed polymer are disclosed. Methods for preparing the compositions from at least one monomer are disclosed. Heating methods utilizing the compositions are disclosed.

Abstract translation: 公开了包含至少一种类型的碳纳米管，至少一种表面活性剂和至少一种聚合物的组合物。 在各种实施方案中，组合物在宽范围的pH下提供稳定的荧光。 在一些实施方案中，组合物是生物相容的。 公开了从至少一种预成型聚合物制备组合物的方法。 公开了从至少一种单体制备组合物的方法。 公开了利用组合物的加热方法。