公开(公告)号：US20020098135A1

公开(公告)日：2002-07-25

申请号：US10033050

申请日：2001-12-28

Applicant: William Marsh Rice University

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: B01J008/06 ,  B01L007/00

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 single-wall carbon nanotubes (SWNT). In one embodiment, a macroscopic molecular array is provided comprising at least about 106 single-wall carbon 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单壁碳纳米管阵列（SWNT）。 在一个实施方案中，提供宏观分子阵列，其包括大致平行取向的至少约106个单壁碳纳米管，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：US20020084410A1

公开(公告)日：2002-07-04

申请号：US10000746

申请日：2001-11-30

Applicant: William Marsh Rice University

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

IPC: G01B007/34 ,  H01J037/06

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: Macroscopically manipulable nanoscale devices made from nanotube assemblies are disclosed. The article of manufacture comprises a macroscopic mounting element capable of being manipulated or observed in a macroscale environment, and a nanoscale nanotube assembly attached to the mounting element. The article permits macroscale information to be provided to or obtained from a nanoscale environment. A method for making a macroscopically manipulable nanoscale devices comprises the steps of (1) providing a nanotube-containing material; (2) preparing a nanotube assembly device having at least one carbon nanotube for attachment; and (3) attaching said nanotube assembly to a surface of a mounting element.

Abstract translation: 公开了由纳米管组件制成的宏观可操纵的纳米级器件。 该制品包括能够在宏观环境中操纵或观察的宏观安装元件，以及附接到安装元件的纳米级纳米管组件。 该文章允许向纳米级环境提供宏观信息或从纳米级环境中获得宏观信息。 一种用于制造宏观可操纵的纳米级器件的方法包括以下步骤：（1）提供含纳米管的材料; （2）制备具有至少一个用于附着的碳纳米管的纳米管组装装置; 和（3）将所述纳米管组件附接到安装元件的表面。

公开(公告)号：US20040223901A1

公开(公告)日：2004-11-11

申请号：US10730630

申请日：2003-12-08

Applicant: William Marsh Rice University

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

IPC: D01F009/12

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 1000null 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., 1000null C.) in which tubes may continue to grow and coalesce into ropes.

Abstract translation: 本发明公开了在被保留的CO中提供已被预热（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）的过程。 催化剂前体分解温度低于混合区。 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：US20020109087A1

公开(公告)日：2002-08-15

申请号：US10027753

申请日：2001-12-21

Applicant: William Marsh Rice University

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

IPC: G01N023/00

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: Macroscopically manipulable nanoscale devices made from nanotube assemblies are disclosed. The article of manufacture comprises a macroscopic mounting element capable of being manipulated or observed in a macroscale environment, and a nanoscale nanotube assembly attached to the mounting element. The article permits macroscale information to be provided to or obtained from a nanoscale environment. A method for making a macroscopically manipulable nanoscale devices comprises the steps of (1) providing a nanotube-containing material; (2) preparing a nanotube assembly device having at least one carbon nanotube for attachment; and (3) attaching said nanotube assembly to a surface of a mounting element.

Abstract translation: 公开了由纳米管组件制成的宏观可操纵的纳米级器件。 该制品包括能够在宏观环境中操纵或观察的宏观安装元件，以及附接到安装元件的纳米级纳米管组件。 该文章允许向纳米级环境提供宏观信息或从纳米级环境中获得宏观信息。 一种用于制造宏观可操纵的纳米级器件的方法包括以下步骤：（1）提供含纳米管的材料; （2）制备具有至少一个用于附着的碳纳米管的纳米管组装装置; 和（3）将所述纳米管组件附接到安装元件的表面。

公开(公告)号：US20020102196A1

公开(公告)日：2002-08-01

申请号：US10033028

申请日：2001-12-28

Applicant: William Marsh Rice University

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: D01F009/12 ,  B01J008/06 ,  B01L007/00

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 compositions and articles of manufacturing comprising single-wall carbon nanotubes (SWNTs). Tubular single-wall carbon nanotube molecules are useful for making electrical connectors for devices such as integrated circuits or semiconductor chips used in computers because of the high electrical conductivity and small size of the carbon molecule. SWNT molecules are also useful as components of electrical devices where quantum effects dominate at room temperatures, for example, resonant tunneling diodes. The metallic carbon molecules are useful as antennas at optical frequencies, and as probes for scanning probe microscopy such as are used in scanning tunneling microscopes (STM) and atomic force microscopes (AFM). Tubular carbon molecules may also be used in RF shielding applications, e.g., to make microwave absorbing materials.

Abstract translation: 本发明一般涉及包含单壁碳纳米管（SWNT）的组合物和制品。 管状单壁碳纳米管分子由于碳分子的高导电性和小尺寸而用于制造用于计算机中的诸如集成电路或半导体芯片的器件的电连接器。 SWNT分子也可用作其中量子效应在室温下占优势的电气器件的组件，例如谐振隧穿二极管。 金属碳分子可用作光频天线，用作扫描探针显微镜的探针，例如用于扫描隧道显微镜（STM）和原子力显微镜（AFM）。 管状碳分子也可用于RF屏蔽应用中，例如制备微波吸收材料。

公开(公告)号：US20020090331A1

公开(公告)日：2002-07-11

申请号：US10032732

申请日：2001-12-28

Applicant: William Marsh Rice University

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: D01F009/12 ,  B01J008/06 ,  B01L007/00

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 growing carbon fiber from single-wall carbon nanotube (SWNT) molecular arrays. In one embodiment, the present invention involves a macroscopic molecular array of at least about 106 tubular carbon molecules in generally parallel orientation and having substantially similar lengths in the range of from about 50 to about 500 nanometers. The hemispheric fullerene cap is removed from the upper ends of the tubular carbon molecules in the array. The upper ends of the tubular carbon molecules in the array are then contacted with a catalytic metal. A gaseous source of carbon is supplied to the end of the array while localized energy is applied to the end of the array in order to heat the end to a temperature in the range of about 500null C. to about 1300null C. The growing carbon fiber is continuously recovered.

Abstract translation: 本发明一般涉及从单壁碳纳米管（SWNT）分子阵列生长碳纤维的方法。 在一个实施方案中，本发明包括大致平行取向的至少约106个管状碳分子的宏观分子阵列，并且具有在约50至约500纳米范围内的基本相似的长度。 半球状富勒烯帽从阵列中的管状碳分子的上端除去。 然后将阵列中的管状碳分子的上端与催化金属接触。 气体碳源被提供到阵列的末端，同时将局部能量施加到阵列的端部，以将端部加热到约500℃至约1300℃的温度。增长 碳纤维连续回收。

公开(公告)号：US20020088938A1

公开(公告)日：2002-07-11

申请号：US10038204

申请日：2001-12-21

Applicant: William Marsh Rice University

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

IPC: G01N023/00

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: Macroscopically manipulable nanoscale devices made from nanotube assemblies are disclosed. The article of manufacture comprises a macroscopic mounting element capable of being manipulated or observed in a macroscale environment, and a nanoscale nantube assembly attached to the mounting element. The article permits macroscale information to be provided to or obtained from a nanoscale environment. A method for making a macroscopically manipulatable nanoscale devices comprises the steps of (1) providing a nanotubecontaining material; (2) preparing a nanotube assembly device having at least one carbon nanotube for attachment; and (3) attaching said nanotube assembly to a surface of a mounting element.

Abstract translation: 公开了由纳米管组件制成的宏观可操纵的纳米级器件。 该制品包括能够在宏观环境中操纵或观察的宏观安装元件，以及附接到安装元件的纳米级纳米管组件。 该文章允许向纳米级环境提供宏观信息或从纳米级环境中获取宏观信息。 一种用于制造宏观可操纵的纳米级器件的方法包括以下步骤：（1）提供纳米覆盖材料; （2）制备具有至少一个用于附着的碳纳米管的纳米管组装装置; 和（3）将所述纳米管组件附接到安装元件的表面。

公开(公告)号：US20020159943A1

公开(公告)日：2002-10-31

申请号：US10034745

申请日：2001-12-28

Applicant: William Marsh Rice University

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: D01F009/12 ,  H05F003/00

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: A method for purifying a mixture comprising single-wall carbon nanotubes and amorphous carbon contaminate is disclosed The method includes the steps of heating the mixture under oxidizing conditions sufficient to remove the amorphous carbon, followed by recovering a product comprising at least about 80% by weight of single-wall carbon nanotubes. A method for producing tubular carbon molecules of about 5 to 500 nm in length is also disclosed. The method includes the steps of cutting single-wall nanotube containing-material to form a mixture of tubular carbon molecules having lengths in the range of 5-500 nm and isolating a fraction of the molecules having substantially equal lengths. The nanotubes may be used, singularly or in multiples, in power transmission cables, in solar cells, in batteries, as antennas, as molecular electronics, as probes and manipulators, and in composites.

Abstract translation: 公开了一种用于纯化包含单壁碳纳米管和无定形碳污染物的混合物的方法。该方法包括以下步骤：在足以除去无定形碳的氧化条件下加热混合物，然后回收包含至少约80重量％ 的单壁碳纳米管。 还公开了一种生产长度为约5至500nm的管状碳分子的方法。 该方法包括以下步骤：切割含有单壁纳米管的材料以形成长度在5-500nm范围内的管状碳分子的混合物，并分离具有基本相等长度的分子的一部分。 纳米管可以在输电电缆，太阳能电池，电池，天线，分子电子学，探头和操纵器以及复合材料中单独或多次使用。

公开(公告)号：US20020136683A1

公开(公告)日：2002-09-26

申请号：US10032932

申请日：2001-12-28

Applicant: William Marsh Rice University

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: D01F009/12

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 arrays of single-wall carbon nanotubes (SWNT). In one embodiment, the present invention involves forming a macroscopic molecular array of tubular carbon molecules, said method comprising the step of assembling subarrays of up to 106 single-wall carbon nanotubes into a composite array.

Abstract translation: 本发明一般涉及形成单壁碳纳米管阵列（SWNT）。 在一个实施方案中，本发明涉及形成管状碳分子的宏观分子阵列，所述方法包括将多达106个单壁碳纳米管的子阵列组装成复合阵列的步骤。

公开(公告)号：US20020102201A1

公开(公告)日：2002-08-01

申请号：US10036684

申请日：2001-12-21

Applicant: William Marsh Rice University

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

IPC: G21K007/00

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: Macroscopically manipulable nanoscale devices made from nanotube assemblies are disclosed. The article of manufacture comprises a macroscopic mounting element capable of being manipulated or observed in a macroscale environment, and a nanoscale nanotube assembly attached to the mounting element. The article permits macroscale information to be provided to or obtained from a nanoscale environment. A method for making a macroscopically manipulable nanoscale devices comprises the steps of (1) providing a nanotube-containing material. (2) preparing a nanotube assembly device having at least one carbon nanotube for attachment; and (3) attaching said nanotube assembly to a surface of a mounting element.

Abstract translation: 公开了由纳米管组件制成的宏观可操纵的纳米级器件。 该制品包括能够在宏观环境中操纵或观察的宏观安装元件，以及附接到安装元件的纳米级纳米管组件。 该文章允许向纳米级环境提供宏观信息或从纳米级环境中获得宏观信息。 用于制造宏观可操纵的纳米级器件的方法包括以下步骤：（1）提供含纳米管的材料。 （2）制备具有至少一个用于附着的碳纳米管的纳米管组装装置; 和（3）将所述纳米管组件附接到安装元件的表面。