Abstract: A plurality of nanowires is grown on a first substrate in a first direction perpendicular to the first substrate. An insulation layer covering the nanowires is formed on the first substrate to define a nanowire block including the nanowires and the insulation layer. The nanowire block is moved so that each of the nanowires is arranged in a second direction parallel to the first substrate. The insulation layer is partially removed to partially expose the nanowires. A gate line covering the exposed nanowires is formed. Impurities are implanted into portions of the nanowires adjacent to the gate line.

Abstract: A carbon nanotube (CNT) attraction material is deposited on a substrate in the gap region between two electrodes on the substrate. An electric potential is applied to the two electrodes. The CNT attraction material is wetted with a solution defined by a carrier liquid having carbon nanotubes (CNTs) suspended therein. A portion of the CNTs align with the electric field and adhere to the CNT attraction material. The carrier liquid and any CNTs not adhered to the CNT attraction material are then removed.

Abstract: A method for making a liquid crystal display screen includes the steps of: providing a base comprising a surface; manufacturing a substrate, wherein manufacturing a substrate comprises: placing a carbon nanotube layer on the surface of the base, the carbon nanotube layer comprising a plurality of carbon nanotubes substantially aligned along a same direction; applying a fixing layer on a surface of the carbon nanotube layer, thereby obtaining a first substrate; and supplying a liquid crystal layer, wherein the carbon nanotubes of a first substrate are arranged perpendicular to that of a second substrate.

Abstract: A method for forming graphene includes introducing a substrate and a carbon-containing reactant source into a chamber, and radiating a laser beam onto the substrate to decompose the carbon-containing reactant source and form graphene over the substrate using carbon atoms generated by decomposition of the carbon-containing reactant source. A carbon-containing gas (methane) decomposes upon radiation of a laser beam. The carbon-containing gas has a decomposition rate on the order of femtoseconds and the laser beam has a pulse on the order of nanoseconds or more. The graphene is grown in a single layer along the surface of the substrate. Then, the graphene is selectively patterned using a laser beam to form a desired pattern.

Abstract: A method for manufacturing a carbon nanotube film, comprises providing a carbon nanotube array and a drawing tool, positioning the drawing tool close to the carbon nanotube array and selecting some carbon nanotubes of the carbon nanotube array, and drawing the selected carbon nanotubes away from the carbon nanotube array along a drawing direction at a drawing angle, thereby forming the carbon nanotube film. The drawing angle is an angle of inclination between the drawing direction and the growth direction. The drawing angle is less than or equal to 80 degrees.

Abstract: Methods for dissolving carbon materials such as, for example, graphite, graphite oxide, oxidized graphene nanoribbons and reduced graphene nanoribbons in a solvent containing at least one superacid are described herein. Both isotropic and liquid crystalline solutions can be produced, depending on the concentration of the carbon material The superacid solutions can be formed into articles such as, for example, fibers and films, mixed with other materials such as, for example, polymers, or used for functionalization of the carbon material. The superacid results in exfoliation of the carbon material to produce individual particles of the carbon material. In some embodiments, graphite or graphite oxide is dissolved in a solvent containing at least one superacid to form graphene or graphene oxide, which can be subsequently isolated. In some embodiments, liquid crystalline solutions of oxidized graphene nanoribbons in water are also described.

Abstract: A method for making a thermionic electron emission device. The method includes the following steps. First, an insulating substrate is provided. Second, a number of lattices are formed on the insulating substrate. Third, a first electrode and a second electrode are fabricated in each lattice on the insulating substrate. Fourth, a carbon nanotube film structure is provided and at least part of the carbon nanotube film is suspended structure above the insulating substrate. Sixth, excess carbon nanotube film structure is cut away to obtain a number of thermionic electron emitters. The thermionic electron emitters are spaced from each other and located between the first electrode and the second electrode in each lattice.

Abstract: A method of manufacturing a memory device having a carbon nanotube can be provided by forming a lower electrode on a substrate and forming an insulating interlayer on the lower electrode. An upper electrode including a diode can be formed on the insulating interlayer, where the upper electrode can have a first void exposing a sidewall of the diode and a portion of the insulating interlayer. A portion of the insulating interlayer can be partially removed to form an insulating interlayer pattern having a second void that exposes a portion of the lower electrode, where the second void can be connected with the first void. A carbon nanotube wiring can be formed from the lower electrode through the second and first voids, where the carbon nanotube wiring may be capable of being electrically connected with the diode of the upper electrode by a voltage applied to the lower electrode.

Abstract: An apparatus for manufacturing a large-area carbon nanotube film includes a reactor chamber, a helical-shaped substrate, and a supporter. The reactor chamber includes an inlet and an outlet. The inlet and the outlet are aligned on an axis of the reactor chamber. The helical-shaped substrate and the supporter are located wholly inside the reactor chamber. The supporter is moveable along the axis of the reactor chamber, and the helical-shaped substrate is supported by the supporter.

Abstract: Methods of preparing conductive thermoset precursors containing carbon nanotubes is provided. Also provided is a method of preparing conductive thermosets containing carbon nanotubes. The carbon nanotubes may in individual form or in the form of aggregates having a macromorpology resembling the shape of a cotton candy, bird nest, combed yarn or open net. Preferred multiwalled carbon nanotubes have diameters no greater than 1 micron and preferred single walled carbon nanotubes have diameters less than 5 nm. Carbon nanotubes may be adequately dispersed in a thermoset precursor by using a extrusion process generally reserved for thermoplastics. The thermoset precursor may be a precursor for epoxy, phenolic, polyimide, urethane, polyester, vinyl ester or silicone. A preferred thermoset precursor is a bisphenol A derivative.

Abstract: A polymer-carbon nanotube composite film is provided for use as a sensor for detecting chemical vapors. The composite film is formed by coating perpendicularly-aligned carbon nanotubes with a polymer selected from poly(vinyl acetate), poly(isoprene), or blends thereof. The sensor may be formed by attaching at least two electrodes to the polymer-carbon nanotube composite film. The sensor may be used in any applications where the sensor is capable of detecting a change in conductivity in the composite.

Abstract: A process of forming a semiconductive carbon nanotube structure includes imposing energy on a mixture that contains metallic carbon nanotubes and semiconductive carbon nanotubes under conditions to cause the metallic carbon nanotubes to be digested or to decompose so that they may be separated away from the semiconductive carbon nanotubes.

Abstract: Porous wall hollow glass microspheres are provided as a template for formation of nanostructures such as carbon nanotubes, In addition, the carbon nanotubes in combination with the porous wall hollow glass microsphere provides an additional reaction template with respect to carbon nanotubes.

Abstract: Carbon nanotubes, a method for preparing the same and an element using the same are provided. The method for preparing carbon nanotubes includes synthesizing carbon nanotubes from carbon source using an arc-discharge method in the presence of catalysts and promoter, wherein the promoter contains an element capable of reducing the surface energy of carbon nanotubes. Carbon nanotubes with high purity and narrow diameter distribution can thus be prepared.

Abstract: A method for making a macro-scale carbon nanotube tube structure includes the following steps. A linear structure and a carbon nanotube structure are provided. The carbon nanotube structure includes at least one carbon nanotube film or at least one carbon nanotube wire. The carbon nanotube structure is wrapped around the linear structure to form a carbon nanotube composite structure. The linear structure is removed from the carbon nanotube composite structure, thereby forming the macro-scale carbon nanotube tube structure.

Abstract: A method of making a hard latex from a latex comprising an aqueous dispersion of a polymer, the method comprising the step of exposing the latex to infrared radiation.

Abstract: An apparatus for making a carbon nanotube composite structure includes a supply unit, a wrapping unit, and a collecting unit. The supply unit is configured to supply a linear structure. The wrapping unit includes a drive mechanism, a hollow rotating shaft, and a face plate. The drive mechanism is mounted on a first end of the hollow rotating shaft to drive the hollow rotating shaft. The face plate is fixed on a second end of the hollow rotating shaft and loads a carbon nanotube array with a growing substrate. The carbon nanotube array forms a carbon nanotube structure. The wrapping unit winds the carbon nanotube structure around the linear structure. The collecting unit pulls the linear structure and collects the carbon nanotube composite wire structure.

Abstract: The present disclosure provides a carbon nanotube wire structure. The carbon nanotube wire structure includes a flexible core and a carbon nanotube layer. The carbon nanotube layer wraps around the flexible core. The flexible core is a linear structure. The carbon nanotube layer includes a number of carbon nanotubes oriented around the flexible core in a helix manner. The present disclosure also provides a method for making the carbon nanotube wire structure.

Abstract: A method for making a carbon nanotube composite wire structure comprises the following steps. A supply unit, a collecting unit, and a wrapping unit are provided. The wrapping unit comprises a hollow rotating shaft, and a face plate mounted on the hollow rotating shaft. A linear structure is provided by the supply unit. The linear structure passes through the hollow rotating shaft and is fixed on a collecting unit. A carbon nanotube structure is drawn from a carbon nanotube array. The carbon nanotube array is loaded on the face plate. One end of the carbon nanotube structure is adhered to the linear structure. The face plate is rotated, and the linear structure is pulled along a fixed direction.

Abstract: A method and apparatus for determining statistical characteristics of nano-particles includes distributing the nano-particles over a surface and then determining properties of the nano-particles by automatic measurement of multiple particles or by a measurement that determines properties of multiple particles at one time, without manipulating individual nano-particles.

Abstract: A method for transferring a nano material formed on a first substrate through deposition techniques to a second substrate, includes: (A) contacting the second substrate with a free end of the nano material on the first substrate; (B) heating the first substrate so that heat is conducted substantially from the first substrate through the nano material to the second substrate to soften a contact portion of a surface of the second substrate that is in contact with the free end of the nano material; (C) after step (B), cooling the second substrate so as to permit hardening of the contact portion of the surface of the second substrate and solid bonding of the nano material to the second substrate; and (D) after step (C), removing the first substrate from the nano material.

Abstract: The invention provides methods functionalizing a planar surface of a graphene layer, a graphite surface, or microelectronic structure. The graphene layer, graphite surface, or planar microelectronic structure surface is exposed to at least one vapor including at least one functionalization species that non-covalently bonds to the graphene layer, a graphite surface, or planar microelectronic surface while providing a functionalization layer of chemically functional groups, to produce a functionalized graphene layer, graphite surface, or planar microelectronic surface.

Abstract: Using SWNT-CA as scaffolds to fabricate stiff, highly conductive polymer (PDMS) composites. The SWNT-CA is immersing in a polymer resin to produce a SWNT-CA infiltrated with a polymer resin. The SWNT-CA infiltrated with a polymer resin is cured to produce the stiff and electrically conductive composite of carbon nanotube aerogel and polymer.

Abstract: A graphene-based saturable absorber device suitable for use in a ring-cavity fiber laser or a linear-cavity fiber laser is disclosed. The saturable absorber device includes an optical element and a graphene-based saturable absorber material supported by the optical element and comprising at least one of graphene, a graphene derivative and functionalized graphene. An examplary optical element is an optical fiber having an end facet that supports the saturable absorber material. Various forms of the graphene-based saturable absorber materials and methods of forming same are also disclosed.

Abstract: Carbon nanotube template arrays may be edited to form connections between proximate nanotubes and/or to delete undesired nanotubes or nanotube junctions.

Abstract: A mechanically robust, binder-free, inexpensive target for laser synthesis of carbon nanotubes and a method for making same, comprising the steps of mixing prismatic edge natural flake graphite with a metal powder catalyst and pressing the graphite and metal powder mixture into a mold having a desired target shape.

Abstract: A method for the production of various morphologies of solid carbon product by reducing carbon oxides with a reducing agent in the presence of a catalyst. The carbon oxides are typically either carbon monoxide or carbon dioxide. The reducing agent is typically either a hydrocarbon gas or hydrogen. The desired morphology of the solid carbon product may be controlled by the specific catalysts, reaction conditions and optional additives used in the reduction reaction. The resulting solid carbon products have many commercial applications.

Abstract: Provided are a conductive polymer-carbon nanotube composite including a carbon nanotube and a conductive polymer filled therein, and a method of manufacturing the same. The conductive polymer-carbon nanotube composite where a conductive polymer is filled in a carbon nanotube is manufactured by introducing a monomer of the conductive polymer into the carbon nanotube using a supercritical fluid technique and polymerizing the monomer. The conductive polymer-carbon nanotube composite is a novel nano-structure material which can overcome limitations that conventional materials may have, and thus can be applied to various applications such as sensors, electrode materials, nanoelectronic materials, etc.

Abstract: A method of making a transparent conductive film includes providing a carbon nanotube array and a substrate. At least one carbon nanotube film is extracted from the carbon nanotube array, and stacked on the substrate to form a carbon nanotube film structure. The carbon nanotube film structure is irradiated by a laser beam along a predetermined path to obtain a predetermined pattern. The predetermined pattern is separated from the other portions of the carbon nanotube film, thereby forming the transparent conductive film from the predetermined pattern of the carbon nanotube film.

Abstract: Low-aspect ratio nanostructures, such as nanocups, nanorings, and arrays of nanocups and nanorings, methods of fabrication of nanostructures, and methods of using nanostructures are disclosed.

Abstract: A method of controlling the number of layers of graphene layers includes forming graphene on a first surface of a first substrate, and forming a second substrate on a second surface of the first substrate; and irradiating the graphene with light to cause constructive Fresnel interference, wherein a multilayer structure or non-uniform graphene structure formed on the a surface of the graphene is removed by the constructive Fresnel interference.

Abstract: A method comprising patterning a substrate to form exposed regions of the substrate sized to deter entangled growth of carbon nanotubes thereon and growing vertically aligned nanotubes on the exposed regions of the substrate.

Abstract: We disclose a process to produce carbon nanotubes from microalgae. Microalgae is been utilized for biodiesel production. The algal membrane resulted from oil extraction of microalgae is used here to produce carbon nanotubes. The process utilized for the conversion is composed of two steps, in the first step the algal membrane is converted to carbon black through a pyrolysis process in inert atmosphere, in the second step the resulted carbon black is converted to carbon nanotubes by mixing the carbon black with a fluid with known self ignition condition and subjecting the mix to said self ignition condition.

Abstract: The exemplary embodiments of the present invention provide a method and system for aligning graphite nanofibers in a thermal interface material to enhance the thermal interface material performance. The method includes preparing the graphite nanofibers in a herringbone configuration, and dispersing the graphite nanofibers in the herringbone configuration into the thermal interface material. The method further includes applying a magnetic field of sufficient intensity to align the graphite nanofibers in the thermal interface material. The system includes the graphite nanofibers configured in a herringbone configuration and a means for dispersing the graphite nanofibers in the herringbone configuration into the thermal interface material. The system further includes a means for applying a magnetic field of sufficient intensity to align the graphite nanofibers in the thermal interface material.

Abstract: A thin film transistor includes a source electrode, a drain electrode, a semiconducting layer, and a gate electrode. The drain electrode is spaced from the source electrode. The semiconducting layer is connected to the source electrode and the drain electrode. The gate electrode is insulated from the source electrode, the drain electrode, and the semiconducting layer by an insulating layer. The semiconducting layer includes at least two stacked carbon nanotube films. Each carbon nanotube film includes an amount of carbon nanotubes. At least a part of the carbon nanotubes of each carbon nanotube film are aligned along a direction from the source electrode to the drain electrode.

Abstract: A shiny is manufactured using a low-molecular-weight organic acid as a dispersant and a nonaqueous organic solvent as a solvent, whereby a coated electrode for a power storage device in which an active material which has been made into microparticles each having a particle diameter of 100 nm or less is uniformly dispersed can be manufactured. By the use of the coated electrode manufactured in this manner, a power storage device with high charge/discharge characteristics can be manufactured. In other words, a power storage device with high capacity density can be realized because the amount of impurities is small and the power density is high due to the sufficient dispersion of the active material in the active material layer.

Abstract: Cohesive assemblies comprising carbon are prepared by obtaining carbon in the form of powder, particles, flakes, or loose agglomerates, dispersing the carbon in a liquid halogen by mechanical mixing and/or sonication, and substantially removing the liquid halogen, typically by evaporation, whereby the cohesive assembly of carbon is formed. The method is especially suitable for preparing free-standing, monolithic assemblies of carbon nanotubes in the form of films, wafers, or discs, having high carbon packing density and low electrical resistivity. The assemblies have various potential applications, such as electrodes in batteries or supercapacitors or as electromagnetic interference shielding materials.

Abstract: A carbon nanohorn (CNH) is oxidized to make an opening in the side of the CNH. A substance to be included, e.g., a metal, is introduced through the opening. The inclusion substance is moved to a tip part of the carbon nanohorn through heat treatment in vacuum or an inert gas. The CNH is further heat treated in an atmosphere containing oxygen in a low concentration to remove the carbon layer in the tip through catalysis of the inclusion substance. This exposes the inclusion substance. If the inclusion substance is a metal which is not moved to a tip part by the heat treatment in vacuum or an inert gas, the carbon part surrounding the fine catalyst particle is specifically burned by a heat treatment in an low oxygen concentration atmosphere, while utilizing the catalysis. Thus, the fine catalyst particle is fixed to the tip part of the CNH.

Abstract: Disclosed herein is a mass production system and method of synthesized carbon nanotubes. The system is configured to completely open the reaction chamber to an outside during synthesis of the carbon nanotubes in the reaction chamber while allowing a specific gas to occupy a predetermined region within the reaction chamber, thereby blocking introduction of external air into the reaction chamber which is opened to external air.

Abstract: In some aspects, a method of fabricating a memory cell is provided that includes fabricating a steering element above a substrate, and fabricating a reversible-resistance switching element coupled to the steering element by selectively fabricating carbon nano-tube (“CNT”) material above the substrate, wherein the CNT material comprises a single CNT. Numerous other aspects are provided.

Abstract: The present invention is generally directed to, in one embodiment, a composite nanofiber having a plurality of nanoparticles retained on the surface of the nanofiber, and a process for forming such composite nanofibers.

Abstract: A system that receives nanomaterials, forms nanofibrous materials therefrom, and collects these nanofibrous materials for subsequent applications. The system include a housing coupled to a synthesis chamber within which nanotubes are produced. A spindle may extend from within the housing, across the inlet, and into the chamber for collecting nanotubes and twisting them into a yarn. A body portion may be positioned at an intake end of the spindle. The body portion may include a pathway for imparting a twisting force onto the flow of nanotubes and guide them into the spindle for collection and twisting into the nanofibrous yarn. Methods and apparatuses for forming nanofibrous are also disclosed.

Abstract: A method for making a carbon nanotube structure is introduced. The method includes the following steps. A carbon nanotube precursor including a number of carbon nanotubes is provided. The carbon nanotube precursor is placed in a chamber with low oxygen environment. The carbon nanotube precursor is heated in the chamber.

Abstract: Disclosed are methods of exfoliating graphite using one or more ionic liquids. Also disclosed is the exfoliated graphite and/or graphene provided by a disclosed method. Further disclosed are composites comprising exfoliated graphite and/or graphene and methods of making the composites.

Abstract: A substrate of the present invention for producing aligned carbon nanotube aggregates on a surface thereof is a substrate for producing aligned carbon nanotube aggregates on a surface thereof, the substrate for producing aligned carbon nanotube aggregates including: a metal base substrate; and carburizing prevention layers formed on both front and back surfaces of the metal base substrate, respectively.

Abstract: Process for dispersing nanoparticles, such as carbon nanotubes, in a medium-viscosity fluid by passing the fluid and nanoparticles through one or more multiscrew extruders having one or more kneading zones

Abstract: A method and an apparatus for manufacturing a graphene transfer film are provided. The method of manufacturing the graphene transfer film includes: forming graphene on a graphene growth film comprising a carbonization catalyst; disposing a carrier film and the graphene growth film so that the carrier film and the graphene growth film, on which the graphene is formed, face each other; applying air pressure to at least one of the graphene growth film and the carrier film so that the graphene and the carrier film are attached to each other; and removing at least a part of the graphene growth film.

Abstract: Graphene production using a continuous or pulsed laser beam focused on a substrate of graphite oxide in a significantly inert environment is disclosed. Laser-induced graphene features are characterized by a 2D-band in the Raman spectra. When the photons of the laser at a various frequencies and power levels beam impinge a graphite oxide foil for various amounts of time, a strip, divet, trench, or hole, having graphene at the bottom or sides is produced. The concentration of the graphite oxide and the laser beam may be adjusted so that the depth of the trench created is a certain depth less than the thickness of the foil. Additionally, in some embodiments, the evaporation of the water during the Hummers method is adjusted so that there remains interlaminar water in the graphite oxide foil. The presently disclosed subject matter may also be used in patterning using rastering or substrate motion.

Abstract: A carbon nanotube manufacturing method wherein a catalyst is heated in a reaction chamber while the reaction chamber is filled with argon gas containing hydrogen. When a predetermined temperature is reached in the reaction chamber, the reaction chamber is evacuated. Then a raw material gas as a carbon source is charged and sealed in the reaction chamber whereupon the synthesis of carbon nanotube begins. Subsequently, when a condition in which the synthesis of carbon nanotubes has proceeded to a predetermined level is detected, gases in the reaction chamber are exhausted. Then, the raw material gas is changed and sealed in the reaction tube again. Thereafter, the charging (synthesizing) operation and the exhausting operation are repeated until the carbon nanotube with a desired film thickness are synthesized. A carbon nanotube manufacturing apparatus is also disclosed.

Abstract: In a Chemical Vapour Deposition (CVD) process for forming carbon nanomaterials, a supply of acetylene gas is filtered by a filter to remove a volatile hydrocarbon gas before the acetylene gas is provided to a mass flow controller. The mass flow controller can mix the filtered acetylene gas with a supply of the volatile hydrocarbon gas so that a gas mixture has a selected proportion of the volatile hydrocarbon gas. The filter performs the filtering by passing the acetylene gas over active carbon.