公开(公告)号：US07780939B2

公开(公告)日：2010-08-24

申请号：US11408520

申请日：2006-06-13

Applicant: John L. Margrave ,  Edward T. Mickelson ,  Robert Hauge ,  Peter Boul ,  Chad Huffman ,  Jie Liu ,  Richard E. Smalley ,  Ken Smith ,  Daniel T. Colbert

Inventor： John L. Margrave ,  Edward T. Mickelson ,  Robert Hauge ,  Peter Boul ,  Chad Huffman ,  Jie Liu ,  Richard E. Smalley ,  Ken Smith ,  Daniel T. Colbert

IPC: B82B1/00

CPC classification number: B01J21/18 ,  B01J23/74 ,  B01J23/755 ,  B01J35/006 ,  B01J35/06 ,  B82Y30/00 ,  B82Y40/00 ,  C01B32/174 ,  C01B2202/02 ,  C01B2202/06 ,  D01F11/121 ,  Y10S977/74 ,  Y10S977/748 ,  Y10S977/75 ,  Y10S977/843 ,  Y10S977/848

Abstract: This invention is directed to chemical derivatives of carbon nanotubes wherein the carbon nanotubes have a diameter up to 3 nm. In one embodiment, this invention also provides a method for preparing carbon nanotubes having substituents attached to the side wall of the nanotube by reacting single-wall carbon nanotubes with fluorine gas and recovering fluorine derivatized carbon nanotubes, then reacting fluorine derivatized carbon nanotubes with a nucleophile. Some of the fluorine substituents are replaced by nucleophilic substitution. If desired, the remaining fluorine can be completely or partially eliminated to produce carbon nanotubes having substituents attached to the side wall of the nanotube. The substituents are dependent on the nucleophile, and preferred nucleophiles include alkyl lithium species such as methyl lithium.

Abstract translation: 本发明涉及碳纳米管的化学衍生物，其中碳纳米管具有高达3nm的直径。 在一个实施方案中，本发明还提供了通过使单壁碳纳米管与氟气反应并回收氟衍生的碳纳米管制备具有连接到纳米管侧壁的取代基的碳纳米管的方法，然后使氟衍生的碳纳米管与亲核试剂 。 一些氟取代基被亲核取代取代。 如果需要，可以完全或部分地除去剩余的氟以产生具有连接到纳米管侧壁上的取代基的碳纳米管。 取代基取决于亲核试剂，优选的亲核试剂包括烷基锂物质如甲基锂。

公开(公告)号：US20090169463A1

公开(公告)日：2009-07-02

申请号：US11507964

申请日：2006-08-22

Applicant: Richard E. Smalley ,  Daniel T. Colbert ,  Hongjie Dai ,  Jie Liu ,  Andrew G. Rinzler ,  Jason H. Hafner ,  Kenneth A. Smith ,  Ting Guo ,  Pavel Nikolaev ,  Andreas Thess

Inventor： Richard E. Smalley ,  Daniel T. Colbert ,  Hongjie Dai ,  Jie Liu ,  Andrew G. Rinzler ,  Jason H. Hafner ,  Kenneth A. Smith ,  Ting Guo ,  Pavel Nikolaev ,  Andreas Thess

IPC: C01B31/00

CPC classification number: G11C13/025 ,  B01J19/081 ,  B01J19/087 ,  B01J19/10 ,  B01J19/121 ,  B01J19/126 ,  B01J19/129 ,  B01J21/185 ,  B01J23/74 ,  B01J23/755 ,  B01J23/8913 ,  B01J37/0238 ,  B01J37/349 ,  B01J2219/00078 ,  B01J2219/0892 ,  B82B3/00 ,  C01B32/152 ,  C01B32/162 ,  C01B32/17 ,  C01B2202/02 ,  D01F9/12 ,  D01F9/127 ,  D21H27/00 ,  G11B9/1418 ,  G11B9/1445 ,  G11B9/1472 ,  G11B9/149 ,  G11C13/0014 ,  G11C13/0019 ,  G11C2213/16 ,  G11C2213/71 ,  G11C2213/81 ,  H01G9/2059 ,  H01L31/0352 ,  H01L31/06 ,  H01L31/18 ,  H01M4/133 ,  H01M4/525 ,  H01M4/583 ,  H01M4/587 ,  H01M4/625 ,  H01M10/0525 ,  Y02E10/542 ,  Y02E60/122 ,  Y02P70/521 ,  Y02P70/54 ,  Y10S977/70 ,  Y10S977/742 ,  Y10S977/745 ,  Y10S977/748 ,  Y10S977/75 ,  Y10S977/753 ,  Y10S977/789 ,  Y10S977/842 ,  Y10S977/843 ,  Y10S977/845 ,  Y10S977/847 ,  Y10S977/848 ,  Y10S977/849 ,  Y10S977/882 ,  Y10S977/948 ,  Y10T428/24058 ,  Y10T428/2918 ,  Y10T428/292 ,  Y10T428/30

Abstract: This invention relates generally to forming an array of fullerene nanotubes. In one embodiment, a macroscopic molecular array is provided comprising at least about 106 fullerene nanotubes in generally parallel orientation and having substantially similar lengths in the range of from about 5 to about 500 nanometers.

Abstract translation: 本发明一般涉及形成富勒烯纳米管阵列。 在一个实施方案中，提供了宏观分子阵列，其包括大致平行取向的至少约106个富勒烯纳米管，并且具有在约5至约500纳米范围内的基本相似的长度。

公开(公告)号：US20080210370A1

公开(公告)日：2008-09-04

申请号：US11840033

申请日：2007-08-16

Applicant: Richard E. Smalley ,  Daniel T. Colbert ,  Ken A. Smith ,  Deron A. Walters ,  Michael J. Casavant ,  Chad B. Huffman ,  Boris I. Yakobson ,  Robert H. Hauge ,  Rajesh Kumar Saini ,  Wan-Ting Chiang ,  Xiao Chuan Qin

Inventor： Richard E. Smalley ,  Daniel T. Colbert ,  Ken A. Smith ,  Deron A. Walters ,  Michael J. Casavant ,  Chad B. Huffman ,  Boris I. Yakobson ,  Robert H. Hauge ,  Rajesh Kumar Saini ,  Wan-Ting Chiang ,  Xiao Chuan Qin

IPC: C01B31/02 ,  B32B37/00 ,  B05D3/00 ,  B01J19/00 ,  B03C1/32

CPC classification number: B82Y40/00 ,  B82Y10/00 ,  B82Y30/00 ,  C01B32/168 ,  C01B2202/02 ,  C01B2202/08 ,  H01J2201/30469 ,  Y10S977/75 ,  Y10S977/845 ,  Y10S977/847 ,  Y10T156/10

Abstract: The present invention is directed to the creation of macroscopic materials and objects comprising aligned nanotube segments. The invention entails aligning single-wall carbon nanotube (SWNT) segments that are suspended in a fluid medium and then removing the aligned segments from suspension in a way that macroscopic, ordered assemblies of SWNT are formed. The invention is further directed to controlling the natural proclivity or nanotube segments to self assemble into or ordered structures by modifying the environment of the nanotubes and the history of that environment prior to and during the process. The materials and objects are “macroscopic” in that they are large enough to be seen without the aid of a microscope or of the dimensions of such objects. These macroscopic ordered SWNT materials and objects have the remarkable physical, electrical, and chemical properties that SWNT exhibit on the microscopic scale because they are comprised of nanotubes, each of which is aligned in the same direction and in contact with its nearest neighbors. An ordered assembly of closest SWNT also serves as a template for growth of more and larger ordered assemblies. An ordered assembly further serves as a foundation for post processing treatments that modify the assembly internally to specifically enhance selected material properties such as shear strength, tensile strength, compressive strength, toughness, electrical conductivity, and thermal conductivity.

Abstract translation: 本发明涉及包括对准的纳米管段的宏观材料和物体的产生。 本发明需要将悬浮在流体介质中的单壁碳纳米管（SWNT）段对准，然后以形成SWNT的宏观有序组件的方式从悬浮液中除去对准的段。 本发明进一步涉及通过在工艺之前和期间修改纳米管的环境和该环境的历史来控制天然倾向或纳米管段自组装成或有序的结构。 材料和物体是“宏观的”，因为它们足够大以便在没有显微镜或这些物体的尺寸的情况下被看到。 这些宏观有序的SWNT材料和物体具有卓越的物理，电学和化学性质，SWNT在微观尺度上显示，因为它们由纳米管组成，其中每个纳米管沿相同方向对齐并与其最近的邻近物接触。 最近的SWNT的有序组件也可以作为增加更多和更大订单组件的模板。 订购的组件还用作后处理处理的基础，其在内部改变组件以特异性地增强选定的材料性能，例如剪切强度，抗拉强度，抗压强度，韧性，导电性和导热性。

公开(公告)号：US07419624B1

公开(公告)日：2008-09-02

申请号：US11507974

申请日：2006-08-22

Applicant: Richard E. Smalley ,  Daniel T. Colbert ,  Hongjie Dai ,  Jie Liu ,  Andrew G. Rinzler ,  Jason H. Hafner ,  Ken Smith ,  Ting Guo ,  Pavel Nikolaev ,  Andreas Thess

Inventor： Richard E. Smalley ,  Daniel T. Colbert ,  Hongjie Dai ,  Jie Liu ,  Andrew G. Rinzler ,  Jason H. Hafner ,  Ken Smith ,  Ting Guo ,  Pavel Nikolaev ,  Andreas Thess

IPC: B82B1/00

CPC classification number: G11C13/025 ,  B01J19/081 ,  B01J19/087 ,  B01J19/10 ,  B01J19/121 ,  B01J19/126 ,  B01J19/129 ,  B01J21/185 ,  B01J23/74 ,  B01J23/755 ,  B01J23/8913 ,  B01J37/0238 ,  B01J37/349 ,  B01J2219/00078 ,  B01J2219/0892 ,  B82B3/00 ,  C01B32/152 ,  C01B32/162 ,  C01B32/17 ,  C01B2202/02 ,  D01F9/12 ,  D01F9/127 ,  D21H27/00 ,  G11B9/1418 ,  G11B9/1445 ,  G11B9/1472 ,  G11B9/149 ,  G11C13/0014 ,  G11C13/0019 ,  G11C2213/16 ,  G11C2213/71 ,  G11C2213/81 ,  H01G9/2059 ,  H01L31/0352 ,  H01L31/06 ,  H01L31/18 ,  H01M4/133 ,  H01M4/525 ,  H01M4/583 ,  H01M4/587 ,  H01M4/625 ,  H01M10/0525 ,  Y02E10/542 ,  Y02E60/122 ,  Y02P70/521 ,  Y02P70/54 ,  Y10S977/70 ,  Y10S977/742 ,  Y10S977/745 ,  Y10S977/748 ,  Y10S977/75 ,  Y10S977/753 ,  Y10S977/789 ,  Y10S977/842 ,  Y10S977/843 ,  Y10S977/845 ,  Y10S977/847 ,  Y10S977/848 ,  Y10S977/849 ,  Y10S977/882 ,  Y10S977/948 ,  Y10T428/24058 ,  Y10T428/2918 ,  Y10T428/292 ,  Y10T428/30

Abstract: This invention relates generally to a method for producing composites of fullerene nanotubes and compositions thereof. In one embodiment, the present invention involves a method of producing a composite material that includes a matrix and a fullerene nanotube material embedded within said matrix. In another embodiment, a method of producing a composite material containing fullerene nanotube material is disclosed. This method includes the steps of preparing an assembly of a fibrous material; adding the fullerene nanotube material to the fibrous material; and adding a matrix material precursor to the fullerene nanotube material and the fibrous material.

Abstract translation: 本发明一般涉及富勒烯纳米管复合材料的制造方法及其组合物。 在一个实施方案中，本发明涉及一种生产复合材料的方法，所述复合材料包括嵌入所述基质内的基质和富勒烯纳米管材料。 在另一个实施方案中，公开了一种制备含有富勒烯纳米管材料的复合材料的方法。 该方法包括准备纤维材料组件的步骤; 将富勒烯纳米管材料添加到纤维材料中; 并向所述富勒烯纳米管材料和所述纤维材料添加基质材料前体。

公开(公告)号：US07338915B1

公开(公告)日：2008-03-04

申请号：US09722950

申请日：2000-11-27

Applicant: Richard E. Smalley ,  Daniel T. Colbert ,  Ting Guo ,  Andrew G. Rinzler ,  Pavel Nikolaev ,  Andreas Thess

Inventor： Richard E. Smalley ,  Daniel T. Colbert ,  Ting Guo ,  Andrew G. Rinzler ,  Pavel Nikolaev ,  Andreas Thess

IPC: C01B31/00

CPC classification number: B82Y30/00 ,  B82Y15/00 ,  B82Y40/00 ,  C01B32/162 ,  C01B2202/02 ,  C01B2202/22 ,  C01B2202/36 ,  Y02P20/134 ,  Y10S428/903 ,  Y10S977/742 ,  Y10S977/743 ,  Y10S977/75 ,  Y10S977/751 ,  Y10S977/842 ,  Y10S977/844 ,  Y10S977/938 ,  Y10T428/2913 ,  Y10T442/50 ,  Y10T442/624

Abstract: This invention provides a method of making single-wall carbon nanotubes by laser vaporizing a mixture of carbon and one or more Group VIII transition metals. Single-wall carbon nanotubes preferentially form in the vapor and the one or more Group VIII transition metals catalyzed growth of the single-wall carbon nanotubes. In one embodiment of the invention, one or more single-wall carbon nanotubes are fixed in a high temperature zone so that the one or more Group VIII transition metals catalyze further growth of the single-wall carbon nanotube that is maintained in the high temperature zone. In another embodiment, two separate laser pulses are utilized with the second pulse timed to be absorbed by the vapor created by the first pulse.

Abstract translation: 本发明提供了一种通过激发汽化碳和一种或多种第八族过渡金属的混合物来制备单壁碳纳米管的方法。 单壁碳纳米管优先在蒸气中形成，并且一个或多个VIII族过渡金属催化单壁碳纳米管的生长。 在本发明的一个实施方案中，一个或多个单壁碳纳米管固定在高温区域中，使得一种或多种第VIII族过渡金属催化保持在高温区域中的单壁碳纳米管的进一步生长 。 在另一个实施例中，利用两个单独的激光脉冲，第二脉冲定时被第一脉冲产生的蒸气吸收。

公开(公告)号：US07204970B2

公开(公告)日：2007-04-17

申请号：US10730630

申请日：2003-12-08

Applicant: Richard E. Smalley ,  Ken A. Smith ,  Daniel T. Colbert ,  Pavel Nikolaev ,  Michael J. Bronikowski ,  Robert K. Bradley ,  Frank Rohmund

Inventor： Richard E. Smalley ,  Ken A. Smith ,  Daniel T. Colbert ,  Pavel Nikolaev ,  Michael J. Bronikowski ,  Robert K. Bradley ,  Frank Rohmund

IPC: C01B11/02

CPC classification number: B01J4/002 ,  B01J3/04 ,  B01J3/042 ,  B01J19/121 ,  B01J19/26 ,  B01J2219/0875 ,  B82Y30/00 ,  B82Y40/00 ,  C01B32/162 ,  C01B2202/02 ,  C01B2202/36 ,  D01F9/1278 ,  Y10S977/75 ,  Y10S977/751 ,  Y10S977/843 ,  Y10S977/845 ,  Y10S977/951 ,  Y10T428/30

Abstract: The present invention discloses the process of supplying high pressure (e.g., 30 atmospheres) CO that has been preheated (e.g., to about 1000° C.) and a catalyst precursor gas (e.g., Fe(CO)5) in CO that is kept below the catalyst precursor decomposition temperature to a mixing zone. In this mixing zone, the catalyst precursor is rapidly heated to a temperature that results in (1) precursor decomposition, (2) formation of active catalyst metal atom clusters of the appropriate size, and (3) favorable growth of SWNTs on the catalyst clusters. Preferably a catalyst cluster nucleation agency is employed to enable rapid reaction of the catalyst precursor gas to form many small, active catalyst particles instead of a few large, inactive ones. Such nucleation agencies can include auxiliary metal precursors that cluster more rapidly than the primary catalyst, or through provision of additional energy inputs (e.g., from a pulsed or CW laser) directed precisely at the region where cluster formation is desired. Under these conditions SWNTs nucleate and grow according to the Boudouard reaction. The SWNTs thus formed may be recovered directly or passed through a growth and annealing zone maintained at an elevated temperature (e.g., 1000° C.) in which tubes may continue to grow and coalesce into ropes.

Abstract translation: 本发明公开了提供已被预热（例如，约1000℃）的高压（例如30个大气压）的CO和催化剂前体气体（例如Fe（CO）5） >）在CO中，其保持低于催化剂前体分解温度至混合区。 在该混合区中，将催化剂前体快速加热到导致（1）前体分解的温度，（2）形成适当尺寸的活性催化剂金属原子簇，和（3）在催化剂簇上的SWNT的有利生长 。 优选使用催化剂簇成核剂来使催化剂前体气体快速反应以形成许多小的活性催化剂颗粒，而不是几个大的非活性催化剂颗粒。 这样的成核机构可以包括比主要催化剂更快地聚集的辅助金属前体，或者通过提供精确地指向需要簇形成的区域的额外的能量输入（例如来自脉冲或CW激光）。 在这些条件下，SWNT根据Boudouard反应成核并生长。 如此形成的SWNT可以直接回收或通过保持在高温（例如1000℃）的生长和退火区域，其中管可以继续生长并聚结成绳索。

公开(公告)号：US07108841B2

公开(公告)日：2006-09-19

申请号：US10033092

申请日：2001-12-28

Applicant: Richard E. Smalley ,  Daniel T. Colbert ,  Hongjie Dai ,  Jie Liu ,  Andrew G. Rinzler ,  Jason H. Hafner ,  Ken Smith ,  Ting Guo ,  Pavel Nikolaev ,  Andreas Thess

Inventor： Richard E. Smalley ,  Daniel T. Colbert ,  Hongjie Dai ,  Jie Liu ,  Andrew G. Rinzler ,  Jason H. Hafner ,  Ken Smith ,  Ting Guo ,  Pavel Nikolaev ,  Andreas Thess

IPC: D01F9/12

CPC classification number: G11C13/025 ,  B01J19/081 ,  B01J19/087 ,  B01J19/10 ,  B01J19/121 ,  B01J19/126 ,  B01J19/129 ,  B01J21/185 ,  B01J23/74 ,  B01J23/755 ,  B01J23/8913 ,  B01J37/0238 ,  B01J37/349 ,  B01J2219/00078 ,  B01J2219/0892 ,  B82B3/00 ,  C01B32/152 ,  C01B32/162 ,  C01B32/17 ,  C01B2202/02 ,  D01F9/12 ,  D01F9/127 ,  D21H27/00 ,  G11B9/1418 ,  G11B9/1445 ,  G11B9/1472 ,  G11B9/149 ,  G11C13/0014 ,  G11C13/0019 ,  G11C2213/16 ,  G11C2213/71 ,  G11C2213/81 ,  H01G9/2059 ,  H01L31/0352 ,  H01L31/06 ,  H01L31/18 ,  H01M4/133 ,  H01M4/525 ,  H01M4/583 ,  H01M4/587 ,  H01M4/625 ,  H01M10/0525 ,  Y02E10/542 ,  Y02E60/122 ,  Y02P70/521 ,  Y02P70/54 ,  Y10S977/70 ,  Y10S977/742 ,  Y10S977/745 ,  Y10S977/748 ,  Y10S977/75 ,  Y10S977/753 ,  Y10S977/789 ,  Y10S977/842 ,  Y10S977/843 ,  Y10S977/845 ,  Y10S977/847 ,  Y10S977/848 ,  Y10S977/849 ,  Y10S977/882 ,  Y10S977/948 ,  Y10T428/24058 ,  Y10T428/2918 ,  Y10T428/292 ,  Y10T428/30

Abstract: This invention relates generally to forming a patterned array of single-wall carbon nanotubes (SWNT). In one embodiment, a nanoscale array of microwells is provided on a substrate; a metal catalyst is deposited in each microwells; and a stream of hydrocarbon or CO feedstock gas is directed at the substrate under conditions that effect growth of single-wall carbon nanotubes from each microwell.

Abstract translation: 本发明一般涉及形成单壁碳纳米管（SWNT）的图案化阵列。 在一个实施例中，在衬底上提供纳米尺寸的微孔阵列; 在每个微孔中沉积金属催化剂; 并且在从每个微孔产生单壁碳纳米管的生长的条件下，烃或CO原料气流被引导到基底。

公开(公告)号：US07067098B2

公开(公告)日：2006-06-27

申请号：US10038204

申请日：2001-12-21

Applicant: Daniel T. Colbert ,  Hongjie Dai ,  Jason H. Hafner ,  Andrew G. Rinzler ,  Richard E. Smalley

Inventor： Daniel T. Colbert ,  Hongjie Dai ,  Jason H. Hafner ,  Andrew G. Rinzler ,  Richard E. Smalley

IPC: D01F9/12

CPC classification number: G01Q70/12 ,  C01B32/152 ,  C01B32/162 ,  C01B32/174 ,  C01B2202/02 ,  C01B2202/06 ,  C01B2202/08 ,  C01B2202/24 ,  C01B2202/34 ,  G01Q70/16 ,  G11B9/1409 ,  G11B11/007 ,  G11C13/025 ,  G11C2213/81 ,  H01J2201/30469 ,  Y10S977/70 ,  Y10S977/75 ,  Y10S977/789 ,  Y10S977/843 ,  Y10S977/845 ,  Y10T428/249977 ,  Y10T428/2918

Abstract: This invention relates generally to forming an array of single-wall carbon nanotubes (SWNT) and compositions thereof. In one embodiment, a homogeneous population of SWNT molecules is used to produce a substantially two-dimensional array made up of single-walled nanotubes aggregated in substantially parallel orientation to form a monolayer extending in directions substantially perpendicular to the orientation of the individual nanotubes. Using SWNT molecules of the same type and structure provides a homogeneous array. By using different SWNT molecules, either a random or ordered heterogeneous structure can be produced by employing successive reactions after removal of previously masked areas of a substrate. Tn one embodiment, SWNT molecules may be linked to a substrate through a linker moiety such as —S—, —S—(CH2)n,-NH-, SiO3(CH2)3NH- or the like.

Abstract translation: 本发明一般涉及形成单壁碳纳米管阵列（SWNT）及其组合物。 在一个实施方案中，使用SWNT分子的均匀群体来产生由基本上平行取向聚集的单壁纳米管构成的基本上二维的阵列，以形成沿着与各个纳米管的取向基本垂直的方向延伸的单层。 使用相同类型和结构的SWNT分子提供均匀的阵列。 通过使用不同的SWNT分子，可以通过在去除衬底的先前掩蔽区域之后采用连续的反应来产生随机或有序的异质结构。 在一个实施方案中，SWNT分子可以通过接头部分例如-S - ， - S-（CH 2）n - ， - NH - ，SiO 3（NH 2）3 NH-等。

公开(公告)号：US07008563B2

公开(公告)日：2006-03-07

申请号：US09935994

申请日：2001-08-23

Applicant: Richard E. Smalley ,  Daniel T. Colbert ,  Ken A. Smith ,  Michael O'Connell

Inventor： Richard E. Smalley ,  Daniel T. Colbert ,  Ken A. Smith ,  Michael O'Connell

IPC: H01B1/24 ,  C01B3/04 ,  C01B31/00

CPC classification number: C08K9/08 ,  B82Y10/00 ,  B82Y30/00 ,  D01F11/14 ,  H01C17/0652 ,  H01L51/0048 ,  H01L51/0052 ,  H01Q17/002 ,  H05K1/0373 ,  H05K1/162 ,  Y02E60/364 ,  Y10S977/745 ,  Y10S977/746 ,  Y10S977/748 ,  Y10S977/75 ,  Y10S977/783 ,  Y10T428/2935 ,  Y10T428/2991 ,  Y10T428/2998

Abstract: The present invention relates to new compositions of matter and articles of manufacture comprising SWNTs as nanometer scale conducting rods dispersed in an electrically-insulating matrix. These compositions of matter have novel and useful electrical, mechanical, and chemical properties including applications in antennas, electromagnetic and electro-optic devices, and high-toughness materials. Other compositions of matter and articles of manufacture are disclosed, including polymer-coated and polymer wrapped single-wall nanotubes (SWNTs), small ropes of polymer-coated and polymer-wrapped SWNTs and materials comprising same. This composition provides one embodiment of the SWNT conducting-rod composite mentioned above, and also enables creation of high-concentration suspensions of SWNTs and compatibilization of SWNTs with polymeric matrices in composite materials. This solubilization and compatibilization, in turn, enables chemical manipulation of SWNT and production of composite fibers, films, and solids comprising SWNTs.

公开(公告)号：US06979709B2

公开(公告)日：2005-12-27

申请号：US10033076

申请日：2001-12-28

Applicant: Richard E. Smalley ,  Daniel T. Colbert ,  Hongjie Dai ,  Jie Liu ,  Andrew G. Rinzler ,  Jason H. Hafner ,  Kenneth A. Smith ,  Ting Guo ,  Pavel Nikolaev ,  Andreas Thess

Inventor： Richard E. Smalley ,  Daniel T. Colbert ,  Hongjie Dai ,  Jie Liu ,  Andrew G. Rinzler ,  Jason H. Hafner ,  Kenneth A. Smith ,  Ting Guo ,  Pavel Nikolaev ,  Andreas Thess

IPC: B01J8/06 ,  B01J19/08 ,  B01J19/10 ,  B01J19/12 ,  B01L7/00 ,  B82B3/00 ,  C01B31/02 ,  D01F9/12 ,  D01F9/127 ,  G01Q70/06 ,  G01Q70/12 ,  G11B9/00 ,  G11C13/02 ,  H01G9/20 ,  H01L31/0352 ,  H01L31/06 ,  H01L31/18 ,  H01M4/133 ,  H01M4/52 ,  H01M4/525 ,  H01M4/58 ,  H01M4/583 ,  H01M4/587 ,  H01M4/62 ,  H01M10/0525 ,  H01M10/36

CPC classification number: G11C13/025 ,  B01J19/081 ,  B01J19/087 ,  B01J19/10 ,  B01J19/121 ,  B01J19/126 ,  B01J19/129 ,  B01J21/185 ,  B01J23/74 ,  B01J23/755 ,  B01J23/8913 ,  B01J37/0238 ,  B01J37/349 ,  B01J2219/00078 ,  B01J2219/0892 ,  B82B3/00 ,  C01B32/152 ,  C01B32/162 ,  C01B32/17 ,  C01B2202/02 ,  D01F9/12 ,  D01F9/127 ,  D21H27/00 ,  G11B9/1418 ,  G11B9/1445 ,  G11B9/1472 ,  G11B9/149 ,  G11C13/0014 ,  G11C13/0019 ,  G11C2213/16 ,  G11C2213/71 ,  G11C2213/81 ,  H01G9/2059 ,  H01L31/0352 ,  H01L31/06 ,  H01L31/18 ,  H01M4/133 ,  H01M4/525 ,  H01M4/583 ,  H01M4/587 ,  H01M4/625 ,  H01M10/0525 ,  Y02E10/542 ,  Y02E60/122 ,  Y02P70/521 ,  Y02P70/54 ,  Y10S977/70 ,  Y10S977/742 ,  Y10S977/745 ,  Y10S977/748 ,  Y10S977/75 ,  Y10S977/753 ,  Y10S977/789 ,  Y10S977/842 ,  Y10S977/843 ,  Y10S977/845 ,  Y10S977/847 ,  Y10S977/848 ,  Y10S977/849 ,  Y10S977/882 ,  Y10S977/948 ,  Y10T428/24058 ,  Y10T428/2918 ,  Y10T428/292 ,  Y10T428/30

Abstract: This invention relates generally to carbon fiber produced from single-wall carbon nanotube (SWNT) molecular arrays. In one embodiment, the present invention involves a macroscopic carbon fiber comprising at least 106 signal-wall carbon nanotubes in generally parallel orientation.

Abstract translation: 本发明一般涉及由单壁碳纳米管（SWNT）分子阵列产生的碳纤维。 在一个实施方案中，本发明涉及包含大致平行取向的至少10 6个信号壁碳纳米管的宏观碳纤维。