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    • 3. 发明申请
    • METHODS FOR CONTROLLING DENSITY, POROSITY, AND/OR GAP SIZE WITHIN NANOTUBE FABRIC LAYERS AND FILMS
    • 用于控制纳米纤维层和薄膜中密度,孔隙度和/或尺寸的方法
    • US20130052449A1
    • 2013-02-28
    • US13578691
    • 2011-02-14
    • Rahul SenJ. Thomas KocabFeng Gu
    • Rahul SenJ. Thomas KocabFeng Gu
    • H01B1/04B32B5/16B82Y30/00B82Y40/00
    • B82Y30/00C01B32/158C01B2202/02C01B2202/06C01B2202/22C01B2202/34C01B2202/36G11C13/025Y10S977/751Y10S977/752Y10T428/249921
    • A method for controlling density, porosity and/or gap size within a nanotube fabric layer is disclosed. In one aspect, this can be accomplished by controlling the degree of rafting in a nanotube fabric. In one aspect, the method includes adjusting the concentration of individual nanotube elements dispersed in a nanotube application solution. A high concentration of individual nanotube elements will tend to promote rafting in a nanotube fabric layer formed using such a nanotube application solution, whereas a lower concentration will tend to discourage rafting. In another aspect, the method includes adjusting the concentration of ionic particles dispersed in a nanotube application solution. A low concentration of ionic particles will tend to promote rafting in a nanotube fabric layer formed using such a nanotube application solution, whereas a higher concentration will tend to discourage rafting. In other aspects, both concentration parameters are adjusted.
    • 公开了一种用于控制纳米管织物层内的密度,孔隙率和/或间隙尺寸的方法。 在一个方面,这可以通过控制纳米管织物中漂流的程度来实现。 一方面,该方法包括调节分散在纳米管应用溶液中的单个纳米管元件的浓度。 单个纳米管元件的高浓度倾向于促进在使用这种纳米管施用溶液形成的纳米管织物层中的漂流,而较低浓度将倾向于阻止漂流。 另一方面,该方法包括调节分散在纳米管应用溶液中的离子颗粒的浓度。 低浓度的离子颗粒倾向于促进在使用这种纳米管施用溶液形成的纳米管织物层中的漂流,而较高的浓度将倾向于阻止漂流。 在其他方面,调整浓度参数。
    • 9. 发明授权
    • Electromagnetic and thermal sensors using carbon nanotubes and methods of making same
    • 使用碳纳米管的电磁和热传感器及其制造方法
    • US08110883B2
    • 2012-02-07
    • US12046855
    • 2008-03-12
    • Jonathan W. WardElwood James EgertonRahul SenBrent M. Segal
    • Jonathan W. WardElwood James EgertonRahul SenBrent M. Segal
    • H01L31/00
    • G01T1/16G01J5/02G01J5/023G01J5/046G01J5/08G01J5/0846G01J5/0853G01J5/20G01J5/24
    • Electromagnetic radiation detecting and sensing systems using carbon nanotube fabrics and methods of making the same are provided. In certain embodiments of the invention, an electromagnetic radiation detector includes a substrate, a nanotube fabric disposed on the substrate, the nanotube fabric comprising a non-woven network of nanotubes, and first and second conductive terminals, each in electrical communication with the nanotube fabric, the first and second conductive terminals disposed in space relation to one another. Nanotube fabrics may be tuned to be sensitive to a predetermined range of electromagnetic radiation such that exposure to the electromagnetic radiation induces a change in impedance between the first and second conductive terminals. The detectors include microbolometers, themistors and resistive thermal sensors, each constructed with nanotube fabric. Nanotube fabric detector arrays may be formed for broad-range electromagnetic radiation detecting. Methods for making nanotube fabric detectors, arrays, microbolometers, thermistors and resistive thermal sensors are each described.
    • 提供了使用碳纳米管织物的电磁辐射检测和感测系统及其制造方法。 在本发明的某些实施例中,电磁辐射检测器包括衬底,布置在衬底上的纳米管织物,纳米管织物包括纳米管的无纺网络,以及第一和第二导电端子,每个与纳米管织物电连通 ,所述第一和第二导电端子彼此空间关系地设置。 纳米管织物可以被调谐为对预定范围的电磁辐射敏感,使得暴露于电磁辐射会引起第一和第二导电端子之间的阻抗变化。 检测器包括微伏表,电阻器和电阻式热传感器,每个由纳米管织物构成。 纳米管织物检测器阵列可以形成用于宽范围电磁辐射检测。 每个都描述制造纳米管织物检测器,阵列,微量热敏电阻,热敏电阻和电阻热传感器的方法。