公开(公告)号：US20120128880A1

公开(公告)日：2012-05-24

申请号：US11509810

申请日：2006-08-25

Applicant: Saikat Talapatra ,  Swastik Kar ,  Sunil Pal ,  Robert Vajtai ,  Pulickel Ajayan

Inventor： Saikat Talapatra ,  Swastik Kar ,  Sunil Pal ,  Robert Vajtai ,  Pulickel Ajayan

IPC: C23C16/26 ,  B32B5/16 ,  B05D5/12 ,  B82Y40/00

CPC classification number: H01G11/36 ,  B82Y30/00 ,  B82Y40/00 ,  C01B32/162 ,  C01B2202/06 ,  C01B2202/08 ,  Y02E60/13 ,  Y10S977/843 ,  Y10T428/25

Abstract: A chemical vapor deposition (CVD) method using a vapor phase catalyst of directly growing aligned carbon nanotubes on a metal surfaces. The method allows for fabrication of carbon nanotube containing structures that exhibit a robust carbon nanotube metal junction without a pre-growth application of solid catalytic materials to the metal surface or the use of solder or adhesives in a multi-step fabrication process.

Abstract translation: 使用在金属表面上直接生长取向的碳纳米管的气相催化剂的化学气相沉积（CVD）方法。 该方法允许制造含有碳纳米管的结构，其显示出坚固的碳纳米管金属结，而不需要在金属表面上预固化催化材料，或者在多步骤制造过程中使用焊料或粘合剂。

公开(公告)号：US07673521B2

公开(公告)日：2010-03-09

申请号：US10537944

申请日：2003-12-09

Applicant: Pulickel Ajayan ,  Emer Lahiff ,  Paul Stryjek ,  Chang Y. Ryu ,  Seamus Curran

Inventor： Pulickel Ajayan ,  Emer Lahiff ,  Paul Stryjek ,  Chang Y. Ryu ,  Seamus Curran

IPC: G01L1/20 ,  G01M5/00

CPC classification number: G01M5/0083 ,  B82Y15/00 ,  B82Y30/00 ,  G01L1/005 ,  G01L1/20 ,  G01M5/0033 ,  H01B1/24 ,  H01Q1/28 ,  H01Q1/38 ,  Y10S977/953 ,  Y10S977/956

Abstract: A method of producing polymer/nanotube composites where the density and position of the nanotubes (11) within the composite ca be controlled. Carbon nanotubes (11) are grown from organometallic micropatterns. These periodic nanotube arrays are then incorporated into a polymer matrix (7) by deposing a curable polymer film on the as-grown tubes. This controlled method of producing free-standing nanotube/polymer composite films may be used to form nanosensor (3) which provide information regarding a physical condition of a material (20), such as an airplane chassis or wing, in contact with the nanosensor (3).

Abstract translation: 制备聚合物/纳米管复合材料的方法，其中复合材料内的纳米管（11）的密度和位置可以被控制。 碳纳米管（11）从有机金属微图案生长。 然后通过在生长管上除去可固化聚合物膜，将这些周期性纳米管阵列掺入聚合物基体（7）中。 可以使用这种控制的制造独立的纳米管/聚合物复合膜的方法来形成纳米传感器（3），其提供关于与纳米传感器接触的诸如飞机底盘或机翼的材料（20）的物理状态的信息 3）。

公开(公告)号：US20070218202A1

公开(公告)日：2007-09-20

申请号：US11622610

申请日：2007-01-12

Applicant: Pulickel Ajayan ,  G. Ramanath ,  Bingqing Wei ,  Anyuan Cao ,  Yung Jung

Inventor： Pulickel Ajayan ,  G. Ramanath ,  Bingqing Wei ,  Anyuan Cao ,  Yung Jung

IPC: C23C16/00

CPC classification number: B82Y30/00 ,  B82Y40/00 ,  C01B32/16 ,  C01B2202/08 ,  C04B35/14 ,  C04B35/62802 ,  C04B35/62839 ,  C04B2235/3206 ,  C04B2235/3217 ,  C04B2235/3418 ,  C04B2235/5264 ,  C04B2235/528 ,  C04B2235/5288 ,  C30B29/605 ,  C30B33/00 ,  H01M4/583 ,  Y10T428/139

Abstract: A method of controllably aligning carbon nanotubes to a template structure to fabricate a variety of carbon nanotube containing structures and devices having desired characteristics is provided. The method allows simultaneous, selective growth of both vertically and horizontally controllably aligned nanotubes on the template structure but not on a substrate in a single process step.

Abstract translation: 提供了一种可控地将碳纳米管与模板结构对准以制造各种含碳纳米管的结构和具有期望特性的器件的方法。 该方法允许在单一工艺步骤中在模板结构上的垂直和水平可控排列的纳米管的同时，选择性生长，但不在基板上。

公开(公告)号：US20070213419A1

公开(公告)日：2007-09-13

申请号：US11602495

申请日：2006-11-21

Applicant: Anyuan Cao ,  Pulickel Ajayan

Inventor： Anyuan Cao ,  Pulickel Ajayan

IPC: C08J9/14

CPC classification number: C04B38/00 ,  B82Y30/00 ,  B82Y40/00 ,  C01B32/162 ,  C01B2202/06 ,  C01B2202/08 ,  C01B2202/26 ,  C04B2111/0037 ,  Y10T428/2457 ,  Y10T428/249953 ,  Y10T428/249978 ,  Y10T428/249979 ,  C04B14/026 ,  C04B30/02

Abstract: An open-cell carbon nanotube foam is made of a plurality of separated carbon nanotubes. The foam exhibits a Poisson's ratio substantially equal to zero, a compressibility of at least 85%, a recovery rate of at least 120 mm/min, a compressive strength of at least 12 MPa, a sag factor of at least 4, a fatigue resistance to no more than 15% permanent deformation when subjected to at least 1,000 compressive cycles at a strain of 85%, and/or a resilience of between 25% and 30%. The carbon nanotubes may be multiwalled carbon nanotubes that are aligned parallel to a thickness of a film comprising the foam.

Abstract translation: 开孔碳纳米管泡沫由多个分离的碳纳米管制成。 泡沫体的泊松比基本上等于零，压缩率至少为85％，回收率至少为120mm / min，抗压强度至少为12MPa，松弛系数至少为4，抗疲劳性 当在85％的应变和/或25％至30％的回弹力下经受至少1,000次压缩循环时，永久变形不超过15％。 碳纳米管可以是与包含泡沫的膜的厚度平行排列的多壁碳纳米管。

公开(公告)号：US20070138010A1

公开(公告)日：2007-06-21

申请号：US10537944

申请日：2003-12-09

Applicant: Pulickel AJAYAN

Inventor： Pulickel AJAYAN

IPC: G01N27/26 ,  H01B1/04 ,  H01Q1/36 ,  H01Q1/00 ,  B05D5/12

CPC classification number: G01M5/0083 ,  B82Y15/00 ,  B82Y30/00 ,  G01L1/005 ,  G01L1/20 ,  G01M5/0033 ,  H01B1/24 ,  H01Q1/28 ,  H01Q1/38 ,  Y10S977/953 ,  Y10S977/956

Abstract: A method of producing polymer/nanotube composites where the density and position of the nanotubes (11) within the composite ca be controlled. Carbon nanotubes (11) are grown from organometallic micropatterns. These periodic nanotube arrays are then incorporated into a polymer matrix (7) by deposing a curable polymer film on the as-grown tubes. This controlled method of producing free-standing nanotube/polymer composite films may be used to form nanosensor (3) which provide information regarding a physical condition of a material (20), such as an airplane chassis or wing, in contact with the nanosensor (3).

Abstract translation: 制备聚合物/纳米管复合材料的方法，其中复合材料内的纳米管（11）的密度和位置可以被控制。 碳纳米管（11）从有机金属微图案生长。 然后通过在生长管上除去可固化聚合物膜，将这些周期性纳米管阵列掺入聚合物基质（7）中。 可以使用这种控制的制造独立的纳米管/聚合物复合膜的方法来形成纳米传感器（3），其提供关于与纳米传感器接触的诸如飞机底盘或机翼的材料（20）的物理状态的信息 3）。

公开(公告)号：US20060073089A1

公开(公告)日：2006-04-06

申请号：US11005474

申请日：2004-12-07

Applicant: Pulickel Ajayan ,  Alvaro Carrillo ,  Nirupama Chakrapani ,  Ravindra Kane ,  Bingqing Wei

Inventor： Pulickel Ajayan ,  Alvaro Carrillo ,  Nirupama Chakrapani ,  Ravindra Kane ,  Bingqing Wei

IPC: D01F9/12

CPC classification number: D01F9/127 ,  A61L27/08 ,  A61L27/422 ,  A61L27/56 ,  A61L2400/12 ,  B01D39/2055 ,  B01D67/0072 ,  B01D67/0088 ,  B01D67/0093 ,  B01D71/021 ,  B01D2239/10 ,  B01D2239/1216 ,  B01D2239/1291 ,  B01D2323/24 ,  B01D2325/08 ,  B01D2325/24 ,  B60R13/02 ,  B60R13/08 ,  B82Y30/00 ,  B82Y40/00 ,  C01B32/168 ,  H01M4/583 ,  H01M4/96 ,  Y10S977/742 ,  Y10T428/12424

Abstract: A method of making a carbon nanotube structure includes providing an array of substantially aligned carbon nanotubes, wetting the array with a liquid, and evaporating the liquid to form the carbon nanotube structure having a pattern in the carbon nanotube array. The structure is preferably a carbon nanotube foam.

公开(公告)号：US20060027499A1

公开(公告)日：2006-02-09

申请号：US11193340

申请日：2005-08-01

Applicant: Pulickel Ajayan ,  Saikat Talapatra ,  Robert Vajtai ,  Anchal Srivastava ,  Onkar Srivastava

Inventor： Pulickel Ajayan ,  Saikat Talapatra ,  Robert Vajtai ,  Anchal Srivastava ,  Onkar Srivastava

IPC: D01F9/12 ,  B01D65/02

CPC classification number: B01D71/021 ,  B01D39/2055 ,  B01D61/14 ,  B01D67/0067 ,  B01D67/0093 ,  B01D69/04 ,  B01D2323/08 ,  B01D2323/24 ,  B01D2325/02 ,  B82Y30/00 ,  D01F9/127

Abstract: Monolithic, macroscopic, nanoporous nanotube filters are fabricated having radially aligned carbon nanotube walls. The freestanding filters have diameters and lengths up to several centimeters. A single-step filtering process was demonstrated in two important settings: the elimination of multiple components of heavy hydrocarbons from petroleum, a crucial step in post-distillation of crude oil, and the elimination of bacterial contaminants such as Escherichia coli or the nanometer-sized poliovirus from drinking water. All the filtration processes were repeated several times with completely reproducible results. These nanotube filters can be cleaned repeatedly after each filtration process to regain their full filtering efficiency.

Abstract translation: 制造具有径向排列的碳纳米管壁的单片，宏观，纳米孔纳米管滤波器。 独立式过滤器的直径和长度可达几厘米。 在两个重要的环境中证明了一步过滤过程：从石油中消除重质烃的多重组分，原油后蒸馏中的关键步骤，以及消除细菌污染物如大肠杆菌或纳米级 来自饮用水的脊髓灰质炎病毒 所有的过滤过程重复数次，完全可重复的结果。 在每个过滤过程之后，可以重复清洗这些纳米管过滤器，以恢复其全部过滤效率。

公开(公告)号：US20110169704A1

公开(公告)日：2011-07-14

申请号：US12717454

申请日：2010-03-04

Applicant: Pulickel AJAYAN ,  Emer Lahiff ,  Paul Stryjek ,  Chang Y. Ryu ,  Seamus Curran

Inventor： Pulickel AJAYAN ,  Emer Lahiff ,  Paul Stryjek ,  Chang Y. Ryu ,  Seamus Curran

IPC: H01Q1/28 ,  H01Q21/12

CPC classification number: G01M5/0083 ,  B82Y15/00 ,  B82Y30/00 ,  G01L1/005 ,  G01L1/20 ,  G01M5/0033 ,  H01B1/24 ,  H01Q1/28 ,  H01Q1/38 ,  Y10S977/953 ,  Y10S977/956

Abstract: A method of producing polymer/nanotube composites where the density and position of the nanotubes within the composite can be controlled. Carbon nanotubes are grown from organometallic micropatterns. These periodic nanotube arrays are then incorporated into a polymer matrix by depositing a curable polymer film on the as-grown tubes. This controlled method of producing free-standing nanotube/polymer composite films may be used to form nanosensors which provide information regarding a physical condition of a material, such as an airplane chassis or wing, in contact with the nanosensor.

Abstract translation: 制备聚合物/纳米管复合材料的方法，其中可以控制复合材料内纳米管的密度和位置。 碳纳米管从有机金属微图案生长。 然后将这些周期性纳米管阵列通过在可生长的管上沉积可固化的聚合物膜而结合到聚合物基质中。 可以使用这种控制的制造独立的纳米管/聚合物复合膜的方法来形成纳米传感器，其提供关于与纳米传感器接触的材料（例如飞机底盘或机翼）的物理状态的信息。

公开(公告)号：US07473411B2

公开(公告)日：2009-01-06

申请号：US11005474

申请日：2004-12-07

Applicant: Pulickel Ajayan ,  Alvaro Carrillo ,  Nirupama Chakrapani ,  Ravi S. Kane ,  Bingqing Wei

Inventor： Pulickel Ajayan ,  Alvaro Carrillo ,  Nirupama Chakrapani ,  Ravi S. Kane ,  Bingqing Wei

IPC: D01F9/12

CPC classification number: D01F9/127 ,  A61L27/08 ,  A61L27/422 ,  A61L27/56 ,  A61L2400/12 ,  B01D39/2055 ,  B01D67/0072 ,  B01D67/0088 ,  B01D67/0093 ,  B01D71/021 ,  B01D2239/10 ,  B01D2239/1216 ,  B01D2239/1291 ,  B01D2323/24 ,  B01D2325/08 ,  B01D2325/24 ,  B60R13/02 ,  B60R13/08 ,  B82Y30/00 ,  B82Y40/00 ,  C01B32/168 ,  H01M4/583 ,  H01M4/96 ,  Y10S977/742 ,  Y10T428/12424

Abstract: A method of making a carbon nanotube structure includes providing an array of substantially aligned carbon nanotubes, wetting the array with a liquid, and evaporating the liquid to form the carbon nanotube structure having a pattern in the carbon nanotube array. The structure is preferably a carbon nanotube foam.

Abstract translation: 制造碳纳米管结构的方法包括提供基本排列的碳纳米管阵列，用液体润湿阵列，并蒸发液体以形成在碳纳米管阵列中具有图案的碳纳米管结构。 该结构优选为碳纳米管泡沫。

公开(公告)号：US20060252853A1

公开(公告)日：2006-11-09

申请号：US10535279

申请日：2003-11-18

Applicant: Pulickel Ajayan ,  Chang Ryu ,  Nirupama Chakrapani ,  Gunaranjan Viswanathan ,  Seamus Curran

Inventor： Pulickel Ajayan ,  Chang Ryu ,  Nirupama Chakrapani ,  Gunaranjan Viswanathan ,  Seamus Curran

IPC: D01F9/12 ,  C08K9/00

CPC classification number: B82Y30/00 ,  B82Y40/00 ,  C01B32/174 ,  C01B2202/02 ,  C01B2202/06 ,  D06M13/144 ,  D06M13/51 ,  D06M2101/40 ,  D06M2400/01

Abstract: The invention relates to derivatized, well-dispersed CNTs that have enhanced miscibility with organic agents. Composite materials may be made using such CNTs. The composite materials, in turn, may be used in optical and electronic applications.

Abstract translation: 本发明涉及具有增强的与有机试剂的混溶性的衍生的，良好分散的CNT。 可以使用这样的CNT来制造复合材料。 复合材料又可用于光学和电子应用。